Patent Publication Number: US-6336755-B1

Title: Image forming apparatus

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to an image forming apparatus, which can apply processing solution or post-processing solution appropriately on an image recording material such as a photosensitive material so as to form an image. 
     2. Description of the Related Art 
     Conventionally, when a color film or a color printed original is copied to an image recording material, for example, a photosensitive material such as a silver halide photographic photosensitive material, each of processings including exposing, developing, bleach-fixing, rinsing and drying are sequentially performed. 
     When the developing, bleach-fixing and rinsing are performed, the developing solution, bleaching solution and rinsing water are applied on the photosensitive material by “dipping” the photosensitive material sequentially into each of the developing solution, bleaching solution and rinsing water, which are processing solutions stored in a developing tank, a bleach-fixing tank and a rinsing tank, respectively. 
     When the dipping method is carried out in this manner, i.e., the processing solution is applied by immersing the photosensitive material into the tank filled with the processing solution, the processing solution is applied on the entire two surfaces of the photosensitive material. Since the processing solution is applied to a reverse surface of the photosensitive material, which surface does not have a photographic structuring layer formed thereon, the processing solution is used wastefully and inefficiently. Accordingly, a large amount of the processing solution is needed. Further, when the image forming apparatus is structured to dip the photosensitive material into the processing solution stored in the tank, spent processing solution, which has been used to process the photosensitive material and in which chemical changes have been thereby caused, is mixed in the processing solution stored in the next processing tank. Further, the area that the processing solution is in contact with the air is large. Thus, primary components of the processing solution deteriorate, hardening of the processing solution is advanced, and the use-life of the processing solution is shortened. As a result, the amount of spent waste solution is correspondingly increased. Accordingly, there is a problem because a large amount of the spent waste solution of the processing solution must be disposed. 
     SUMMARY OF THE INVENTION 
     In view of the aforementioned circumstances, execution of each processing by applying a small amount of processing solution or post-processing solution is made possible. Further, it is an object of the present invention to provide an image forming apparatus that can reduce the amount of waste solution to be processed. 
     A first aspect of the present invention is an image forming apparatus comprising: processing solution applying means for applying alkaline processing solution including hydrogen peroxide, which alkaline processing solution is substantially devoid of developing agents, to substantially only a photographic structuring layer side of an exposed silver halide photographic photosensitive material, the silver halide photographic photosensitive material having a support and at least one photographic structuring layer formed on the support, which photographic structuring layer comprises a dye-forming coupler and a reducing agent. 
     A second aspect of the present invention is an image forming apparatus comprising: processing solution applying means for applying alkaline processing solution, which is substantially devoid of developing agents, to substantially only a photographic structuring layer side of an exposed silver halide photographic photosensitive material, the silver halide photographic photosensitive material having a support and at least one photographic structuring layer formed on the support, which photographic structuring layer comprises a dye-forming coupler and a reducing agent. 
     A third aspect of the present invention is an image forming apparatus comprising: processing solution applying means for applying solution including hydrogen peroxide to substantially only a photographic structuring layer side of an exposed silver halide photographic photosensitive material, the silver halide photographic photosensitive material having a support and at least one photographic structuring layer formed on the support, which photographic structuring layer comprises a dye-forming coupler and a reducing agent. 
     Being structured in the above-described manner, the processing solution applying means performs development-intensification processing by applying the processing solution only on the photographic structuring layer side of the silver halide photographic photo sensitive material. 
     As a result, a required small amount of the processing solution is applied, and the applied processing solution is used up and disposed of each time. Accordingly, waste solution which has been used many times and has deteriorated is not generated. Thus, disposal of waste solution is not necessary. 
     Further, as waste solution is not generated as described above, the amount of the processing solution can be reduced correspondingly, with the result that a large amount of the processing solution is not needed. Therefore, this apparatus is easily maintained and can perform stable developing processing. 
     Further, the entire image forming apparatus can be structured compactly. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a front view showing a schematic structure of an entire image forming apparatus according to a first embodiment of the present invention. 
     FIG. 2 is a schematic perspective view showing a flow of processing steps of the image forming apparatus according to the first embodiment of the present invention. 
     FIG. 3 is an enlarged view in rear elevation, partly in section, showing a structural example of processing solution applying means, by picking out the processing solution applying means portion of the image forming apparatus according to the first embodiment of the present invention and viewing the portion from the rear side in FIG.  1 . 
     FIG. 4 is an enlarged perspective view showing a jetting tank portion of the processing solution applying means of the image forming apparatus according to the first embodiment of the present invention. 
     FIG. 5 is a bottom view showing a state in which a photosensitive material is conveyed under the jetting tank of the image forming apparatus according to the first embodiment of the present invention. 
     FIG. 6 is a sectional view of the jetting tank of the image forming apparatus according to the first embodiment of the present invention, wherein the jetting tank is cut along the VI—VI line in FIG.  5 . 
     FIG. 7 is a sectional view showing a state in which water is jetted from the jetting tank of the image forming apparatus according to the first embodiment of the present invention, in a cross-section corresponding to FIG.  6 . 
     FIG. 8 is a side view illustrating a schematic structure of the processing solution applying means in a felt pen form, which can be structured as the processing solution applying means of the image forming apparatus according to the first embodiment of the present invention. 
     FIG. 9 is a sectional view illustrating a schematic structure of the processing solution applying means in a geyser form, which can be structured as the processing solution applying means of the image forming apparatus according to the first embodiment of the present invention. 
     FIG. 10 is a side view illustrating a schematic structure of the processing solution applying means in a porous roller form, which can be structured as the processing solution applying means of the image forming apparatus according to the first embodiment of the present invention. 
     FIG. 11 is a side view illustrating a schematic structure of the processing solution applying means in a spray form, which can be structured as the processing solution applying means of the image forming apparatus according to the first embodiment of the present invention. 
     FIG. 12 is a front view showing a schematic structure of the entire image forming apparatus according to second and third embodiments of the present invention. 
     FIG. 13 is a front view showing a schematic structure of the entire image forming apparatus according to a fourth embodiment of the present invention. 
     FIG. 14 is a front view showing a schematic structure of the entire image forming apparatus according to a fifth embodiment of the present invention. 
     FIG. 15 is a front view showing a schematic structure of the entire image forming apparatus according to a sixth embodiment of the present invention. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     FIG. 1 shows a schematic total structure of an image forming apparatus according to a first embodiment of the present invention, wherein the apparatus includes processing solution applying means. 
     In the image forming apparatus shown in FIG. 1, a paper feeding section  12  is disposed at the lower-right side in the apparatus body  10 . Further, a conveying path  14  is provided inside the apparatus body  10  so as to wind continuously from the paper feeding section  12  to an outlet  16  at the intermediate portion of the right side of the body shown in FIG.  1 . 
     Inside the apparatus body  10 , an exposing section  18  for exposing an image on a photosensitive material  40  fed from the paper feeding section  12 , a development-intensification processing section  20 , a cleaning section  24 , a stabilizing section  25 , a drying section  26 , and the outlet  16  for discharging the image recording material  40  on which an image has been formed, are sequentially disposed along the conveying path  14  from the paper feeding section  12  side. Each of these sections is operated automatically by a controlling section (not shown). 
     Further, inside the apparatus body  10 , a tank for processing solution, a tank for cleaning water and a tank for waste solution (which tanks are not shown) are also disposed. 
     The paper feeding section  12  of the image forming apparatus contains the photosensitive material  40  as a band-shaped image recording material which is wound in a roll configuration, and feeds a leading end portion of the photosensitive material  40  onto the conveying path  14 , which leading end portion is pulled out from an outer peripheral end portion of the roll. 
     At several positions along the conveying path  14 , feeding rollers  36  are disposed. The feeding rollers  36  feed the photosensitive material  40  from the paper feeding section  12  to the outlet  16  on the conveying path  14 , by nipping the photosensitive material  40  between each pair of the rotating rollers. 
     The photosensitive material  40  which has been fed from the paper feeding section  12  is cut into a predetermined size by a cutter  38 , which is disposed near the paper feeding section  12 , and is then conveyed to the exposing section  18 . 
     At the exposing section  18 , color image signals which are input with a scanner (not shown) or the like are subjected to image processing, and then a latent image is formed by exposing the photosensitive material  40 , which is at a predetermined position on the conveying path  14 , by a laser light source of a semiconductor laser unit, in accordance with processed image data. The photosensitive material  40 , on which the latent image has been formed in this manner, is conveyed to the development-intensification processing section  20  by the feeding rollers  36 . 
     The development-intensification processing section  20  has the processing solution applying means, conveying means and heat controlling means. In the present first embodiment, for example, as shown in FIGS. 3-7, the processing solution applying means is structured with an applying device  310  which applies the processing solution only on a photosensitive material emulsion surface  40 A which is one side of the photosensitive material  40 . At a portion of the applying device  310 , a jetting tank  312  is disposed. 
     As shown in FIG. 3, at the lower-left side of the jetting tank  312 , a processing solution bottle  332  for storing the processing solution to be supplied to the jetting tank  312  is disposed. At an upper portion of the processing solution bottle  332 , a filter  334  for filtering the processing solution is disposed. A solution conveying pipe  342 , which is provided with a pump  336  at an intermediate portion thereof, connects the processing solution bottle  332  and the filter  334 . 
     Further, at the right side of the jetting tank  312  shown in FIG. 3, a sub-tank  338  for storing the processing solution conveyed from the processing solution bottle  332  is disposed. A solution conveying pipe  344  extends from the filter  334  to the sub-tank  338 . 
     Accordingly, when the pump  336  operates, the processing solution is conveyed from the processing solution bottle  332  toward the filter  334 , and the processing solution filtered by passing through the filter  334  is conveyed to the sub-tank  338 , where the processing solution is temporarily stored. 
     A solution conveying pipe  346  is disposed between the sub-tank  338  and the jetting tank  312  so as to connect the two. The processing solution conveyed with the pump  336  from the processing solution bottle  332  through the filter  334 , the sub-tank  338 , the solution conveying pipe  346  and the like eventually fills the jetting tank  312 . 
     A circulating pipe  348 , one end of which is connected to the processing solution bottle  332 , is connected to the sub-tank  338  in an extended state by protruding inside the sub-tank  338 . The excess processing solution which has been stored in the sub-tank  338  is returned to the processing solution bottle  332  via the circulating pipe  348 . 
     As shown in FIGS. 4-7, at a portion which is one section among wall surfaces of the jetting tank  312  and faces the conveying path  14  of the photosensitive material  40 , a nozzle plate  322  formed by bending a thin, elastically deformable, rectangular plate is set. 
     As shown in FIGS. 5 and 6, on the nozzle plate  322 , a plurality of nozzle holes  324  (for example, each of which may have a diameter of several tens of μm) for jetting the processing solution which fills the jetting tank  312  are arranged linearly along the direction intersecting the conveying direction A of the photosensitive material  40 , and are disposed across the entire transverse direction of the photosensitive material  40  at regular intervals. Thus the processing solution in the jetting tank  312  can be expelled from each of these nozzle holes  324  toward the photosensitive material  40 . 
     On the other hand, as shown in FIGS. 3 and 4, an exhaust duct  330  extends from an upper portion of the jetting tank  312 , and enables the inside and outside of the jetting tank  312  to communicate. Further, a valve (not shown) for opening and closing the exhaust duct  330  is set at an intermediate portion of the exhaust duct  330 . Due to opening and closing movements of the valve , the inside of the jetting tank  312  can be made to communicate with or be closed off from the outside air. 
     As shown in FIG. 6, end side portions of the nozzle plate  322 , which orthogonally intersect the longitudinal direction of the plurality of which are the nozzle holes  324 , which are arranged linearly, are adhered with an adhesive or the like and are fixed to a pair of lever plates  320 , respectively. The nozzle plate  322  and the pair of the lever plates  320  are thereby connected. The pair of the lever plates  320  are fixed to a pair of side walls  312 A via a pair of small-width supporting portions  312 B, respectively, wherein each of the supporting portions  312 B is formed at a lower portion of the respective side wall  312 A of the jetting tank  312 . 
     On the other hand, a pair of top walls  312 C, which form a top surface of the jetting tank  312  by abutting each other, partially protrude to the outside of the jetting tank  312 . At the respective lower side of the protruding top walls  312 C, a plurality of piezoelectric elements  326  (in the present first embodiment, each side has three piezoelectric elements) serving as an actuator, are adhered and disposed to bottom surfaces of the piezoelectric elements  326 , and outer end sides of the lever plates  320  are adhered, respectively, so that the piezoelectric elements  326  and the lever plates  320  are connected. 
     Each of the lever plates  320 , the side walls  312 A, the supporting portions  312 B and the top walls  312 C forms a portion of an integrally formed frame  314 . As shown in FIG. 6, due to a pair of the frames  314  being put together and screwed down with bolts (not shown), the pair of the lever plates  320 , the pair of the side walls  312 A, the pair of the top walls  312 C and the pair of the supporting portions  312 B are disposed so that respective members of the pairs face each other, and together for m an outer frame of the jetting tank  312 . 
     As shown in FIGS. 4 and 5, at each of portions defined by right and left ends of the nozzle plate  322  , which are end portions of the nozzle plate  322  located in the longitudinal direction of the nozzle holes  324 , and by end portions of the pair of the frames  314 , a thin sealing plate  328  is disposed so as to adhere to the respective frame  314 . 
     Further, at inner sides of the sealing plates  328 , an elastic adhesive, for example, that of a silicone rubber type, fills the openings between the sealing plates  328  and the right and left ends of the nozzle plate  322  and the openings between the sealing plates  328  and the end portions of the pair of the frames  314 , in order to prevent the processing solution from leaking therefrom. Accordingly, the openings of the jetting tank  312  is sealed by the elastic adhesive without inhibiting the movement of the right and left ends of the nozzle plate  322 . It is also possible to seal right and left ends of the jetting tank  312  using only the elastic adhesive, without using the thin sealing plates  328 . 
     Due to the above, when the piezoelectric elements  326  are energized by the power source, the piezoelectric elements  32   6  lengthen and rotate the lever plates  320  a bout the supporting portions  312 B, as shown in FIG.  7 . Together with this rotation, the piezoelectric elements  326  simultaneously deform and displace the nozzle plate  322  so that a middle portion of the nozzle plate  322  rises along the direction of arrow B. Together with the deformation of the nozzle plate  322 , pressure of the processing solution in the jetting tank  312  simultaneously increases, such that a small amount of the processing solution L is jetted linearly from the nozzle holes  324 . 
     As shown in FIG. 1, at a position that faces the jetting tank  312  at the side of the conveying path  14  opposite thereto, the holding means is provided in order to prevent the nozzle holes  324  from clogging, wherein the clogging is caused by evaporation of the water content of the processing solution and by deposition of components thereof at the nozzle holes  324  portion of the jetting tank  312 . This occurs when the jetting tank  312  is not being used and the nozzle holes  324  do not perform an operation of atomizing the processing solution after the atomizing operation. 
     The holding means comprises a pan member  352  which has a substantially U-shaped cross-section and which can be operated to move in the direction of arrow C in FIG.  1 . When the jetting tank  312  performs the operation of atomizing the processing solution, the pan member  352  is located at a position vertically downward from the conveying path  14  and just below the nozzle holes  324 , and is used to catch the droplets of the processing solution which have been jetted from the nozzle holes  324  and have not been deposited on the photosensitive material  40 . 
     For times when the jetting tank  312  is not being used, the pan member  352  is moved in the vertically upward direction and the nozzle holes  324  portion of the jetting tank  312  is immersed in the solution stored to a predetermined level in a recessed portion of the pan member  352  so as to prevent the nozzle holes  324  portion from drying and clogging. Further, the recessed portion of the pan member  352  may be filled with the cleaning solution to perform cleaning of the nozzle holes  324  as needed. 
     The previously described processing solution applying means may have structures other than the above-described structure such as those shown in FIGS. 8-11. The means shown in FIG. 8 is structured in a so-called felt form, wherein the processing solution for processing the photosensitive material  40  is applied only on the photosensitive material emulsion surface  40 A which is one side of the photosensitive material  40 , by sliding a felt applying member  42  soaked with the processing solution. 
     In the processing solution applying means in the felt form, the processing solution is supplied by processing solution supplying means (not shown) from a tank for the processing solution to the felt applying member  42  formed with a blade-shaped felt material which is an elastic body having a water absorbing property. Further, the amount of the processing solution to be supplied is controlled by processing solution supply controlling means  44 . 
     The processing solution applying means shown in FIG. 9 is structured in a so-called geyser form. In processing solution applying the means, viscous processing solution is extruded from a slit member  48  and is smeared only on the photosensitive material emulsion surface  40 A which is one side of the photosensitive material  40 . 
     The processing solution applying means shown in FIG. 10 is structured in a so-called porous roller form. In the means, the processing solution is applied by rolling a porous roller  50  only on the photosensitive material emulsion surface  40 A which is one side of the photosensitive material  40  after the processing solution is supplied to and soaks the porous roller  50 . 
     The processing solution applying means shown in FIG. 11 is structured in a so-called spray form. In the processing solution applying means, the processing solution is sprayed and applied with a spraying device  51  only on the photosensitive material emulsion surface  40 A which is a bottom surface of the photosensitive material  40 . 
     In the development-intensification processing section  20  structured as previously described, at the upstream side of the conveying means, a first developing intensifier is applied on the photosensitive material emulsion surface  40 A of the conveyed photosensitive material  40  by the processing solution applying means. The photosensitive material  40 , on which the first developing intensifier has been applied in this manner, is heated by the heat controlling means, and is then conveyed by the conveying means while being kept at a predetermined temperature. During the conveyance, a chemical reaction is caused and the development-intensification processing is completed, and then the photosensitive material  40  is conveyed to the cleaning section  24 , which is next. 
     The development-intensification processing section  20  is not limited to the previously described structure, and may have other various structures. 
     As shown in FIG. 1, a heat-control section  354  is provided at a position that is on the conveying path  14  of the photosensitive material  40  and is at the downstream side in the direction the photosensitive material  40  is conveyed from the jetting tank  312 . The heat-control section  354  has a belt conveyer  356  ( 360 ,  362 ) as conveying means which is disposed along and just below the conveying path  14 , and a case portion  358  as the heat controlling means which covers the belt conveyer  356  so as to envelop it. 
     In the belt conveyer  356 , an endless belt  362  for conveyance is wound between a pair of rollers  360  so that it can convey the photosensitive material  40  disposed on the endless belt  362  in the direction of arrow A. The belt conveyer  356  may be structured in a so-called gel-belt form, in which a sticky condition imparted to an outer surface of the endless belt  362 , and the photosensitive material  40  is thereby conveyed in the state of being adhered to the endless belt  362  so as not to be blown off. 
     In the case portion  358 , an inlet opening  366  for introducing the photosensitive material  40 , which opens correspondingly to an inlet at the upstream side of the belt conveyer  356  on the conveying path  14 , and an outlet opening  368  for discharging the photosensitive material  40 , which opens correspondingly to an outlet at the downstream side thereof, are provided. 
     In the case portion  358 , the air is kept at a predetermined temperature by a heater (not shown). Therefore, the inside of the case portion  358  is adjusted so that the emulsion surface  40 A portion of the photosensitive material  40 , having the first developing intensifier applied thereon, is kept at a predetermined temperature, and chemical change proceeds at a predetermined speed, when the photosensitive material  40  passes through the case portion  358 . 
     At a position which is on the conveying path  14  and near the outlet opening  368 , conveying rollers  364  are disposed. The pair of the conveying rollers  364  squeeze off the spent excess first developing intensifier which is deposited on the photosensitive material  40 , and conveys the photosensitive material  40  by rotating while nipping the photosensitive material  40  therebetween. 
     The photosensitive material  40 , which has been processed at the above-described development-intensification processing section  20 , is conveyed to the cleaning section  24  on the conveying path  14 . The cleaning section  24  is means for post-processing which is a step for ensuring preservation properties of the image formed on the photographic material  40 . 
     As shown in the total schematic structural view of the image forming apparatus in FIG. 1, the cleaning section  24  cleans the emulsion surface  40 A of the photosensitive material  40  by splashing a necessary amount of the cleaning water only on the emulsion surface  40 A with a shower device  52 . The shower device  52  is a non-contacting type applying means. By using the shower device  52  in this manner, the cleaning water can be splashed on the emulsion surface  40 A in a non-contact state such that a portion of the shower device  52  does not touch the emulsion surface  40 A. It is desirable to dispose wetting prevention means which prevents a surface opposite to the emulsion surface  40 A of the photosensitive material  40  from being wet with the cleaning water during the splashing. 
     At a position which is below the shower device  52  and which is at the side of the conveying path  14  opposite thereto, a pan  54  for the cleaning water is provided. The pan  54  is disposed under the conveying path from the shower device  52  with respect to squeezing rollers  56 , which are disposed at the downstream side of the conveying path  14  from the shower device  52 , and catches spilt cleaning water. 
     The pair of the squeezing rollers  56  squeeze off the cleaning water on the emulsion surface  40 A by rotating while nipping the photosensitive material  40  therebetween. The split cleaning water caught by the pan  54  is reclaimed to be reused, or disposed of, as waste solution. The photosensitive material  40 , from which the cleaning water has been squeezed by the squeezing rollers  56 , is conveyed to the stabilizing section  25 . The stabilizing section  25  is disposed at a position downstream the conveying path  14 . 
     At the stabilizing section  25 , stabilizing processing is performed by splashing a first stabilizing solution on the emulsion surface  40 A of the photosensitive material  40  with a shower device  58 . The shower device  58  is a non-contacting type applying means. Further, at the stabilizing section  25 , the first stabilizing solution on the photosensitive material  40  is squeezed off by squeezing rollers  60 , and the spilt first stabilizing solution is caught by a pan  62 . The shower device  58 , the squeezing rollers  60  and the pan  62  are structured in the same manner as the shower device  52 , the squeezing rollers  56  and the pan  54  of the previously described cleaning section  24 , respectively. 
     The photosensitive material  40 , for which the stabilizing processing has been completed at the stabilizing section  25 , is conveyed to the drying section  26 , which is downstream the conveying path  14 . The drying section  26  is structured as a drying system by heat rollers and hot air blowing. That is, in order to dry the emulsion surface  40 A, the portion on the conveying path  14  which corresponds to the drying section  26  is covered with a cover member  64 , and hot air is blown on the emulsion surface  40 A of the photosensitive material  40  inside the cover member  64 . Further, heat rollers  66  heated to a predetermined temperature are rotated while contacting the photosensitive material  40  to dry the emulsion surface  40 A, while performing a conveying operation. 
     The photosensitive material  40 , which has been dried at the drying section  26  in this manner and on which the image has been formed, is conveyed as a finished product from the outlet  16  onto a tray portion  10 A, which is mounted so as to protrude from a side portion of the apparatus body  10 . The photosensitive material  40  is eventually stacked on the tray portion  10 A. 
     Next, the photosensitive material  40  used in the image forming apparatus of the first embodiment, and each of the processing solutions will be described. 
     The photosensitive material  40  used in this image forming apparatus is the photosensitive material  40  containing a color developing agent and the like, and a construction thereof will be described hereinafter. 
     (Photosensitive material) 
     (1) Silver halide color photographic photosensitive material, which has at least one photographic structuring layer on a support, and includes in any of the photographic structuring layers at least one dye-forming coupler and at least one reducing agent for coloring represented by the following general formulas (I) and/or (II).                    
     In the above formulas, R 1 -R 4  each independently represent a hydrogen atom or a substituent. A 1  and A 2  each represent a hydroxyl group or a substituted amino group. X represents a polyvalent connecting group selected from —CO—, —SO—, —SO 2  and —PO&lt;. Y 1K  and Z 1K  represent a nitrogen atom or a group represented by —CR 5 ═(R 5  is a hydrogen atom or a substituent). k represents an integer which is 0 or more. P represents a proton dissociative group or a group which can be a cation, and has a function of forming dye with a process in which an oxidant produced by redox reaction between the present compound and the exposed silver halide couples with a coupler, and thereafter electron-transfer from P triggers cutting of N—X bonding and elimination of the substituent bonded to the coupling portion of the coupler. Y represents a bivalent connecting group. Z represents a nucleophilic group which can attack X when the present compound is oxidized. n is 1 or 2 when X is —PO&lt;, and is 1 when X is another group. R 1  and R 2 , R 3  and R 4 , and two or more atoms or substituents selected arbitrarily from Y 1K , Z 1K , and P, may each be independently linked with each other to form a ring. 
     (2) Silver halide color photographic photosensitive material, which has at least one photographic structuring layer on a support, and includes in any of the photographic structuring layers at least one dye-forming coupler and at least one reducing agent for coloring represented by the following general formula (III). 
     
       
         R 11 —NHNH—X 0 —R 12   General formula (III) 
       
     
     In the above formula, R 11  is an aryl group or a hetero ring group which may have a substituent, and R 12  is an alkyl group, an alkenyl group, an alkynyl group, an aryl group or a hetero ring group which may have a substituent. X 0  is —SO 2 —, —CO—, —COCO—, —CO—O—, —CONH(R 13 )—,—COCO—O—, —COCO—N(R 13 )— or —SO 2 —NH(R 13 )—, wherein R 13  is a hydrogen atom or a group described with regards to R 12 . 
     (3) Photosensitive material as described above in (2) in which the compound represented by the general formula (III) is represented by the following general formulas (IV) or (V).                    
     In the above formulas, Z 1  represents an acyl group, a carbamoyl group, an alkoxycarbonyl group or an aryloxycarbonyl group, Z 2  represents a carbamoyl group, an alkoxycarbonyl group or an aryloxycarbonyl group, and X 1 , X 2 , X 3 , X 4  and X 5  each represent a hydrogen atom or a substituent. However, the sum of Hammett&#39;s substituent constant σp of X 1 , X 3  and X 5  and Hammett&#39;s substituent constant σm of X 2  and X 4  is within a range from 0.08 to 3.80. R 3a  represents a hetero ring group. 
     (4) Photosensitive material as described above in (3) in which the compounds represented by the general formulas (IV) and (V) are represented by the following general formulas (VI) and (VII), respectively.                    
     In the above formulas, R 1a  and R 2a  each represent a hydrogen atom or a substituent, and X 1 , X 2 , X 3 , X 4  and X 5  each represent a hydrogen atom or a substituent. However, the sum of Hammett&#39;s substituent constant σp of X 1 , X 3  and X 5  and Hammett&#39;s substituent constant σm of X 2  and X 4  is within a range from 0.80 to 3.80. R 3a  represents a hetero ring group. 
     (5) Photosensitive material as described above in (4) in which the compounds represented by the general formulas (VI) and (VII) are represented by the following general formulas (VIII) and (IX), respectively.                    
     In the above formulas, R 4a  and R 5a  each represent a hydrogen atom or a substituent, either R 4a  or R 5a  is a hydrogen atom, and X 6 , X 7 , X 8 , X 9  and X 10  each represent a hydrogen atom, a cyano group, a sulfonyl group, a sulfinyl group, a sulfamoyl group, a carbamoyl group, an alkoxycarbonyl group, an aryloxycarbonyl group, an acyl group, a trifluoromethyl group, a halogen atom, an acyloxy group, an acylthio group or a hetero ring group. However, the sum of Hammett&#39;s substituent constant σp of X 6 , X 8  and X 10  and Hammett&#39;s substituent constant σm of X 7  and X 9  is within a range from 1.20 to 3.80. 
     Q 1  represents a non-metallic atom group which is necessary to form a hetero ring of 5-8 member ring including nitrogen together with C. 
     In the photosensitive material according to the present embodiment, it is desirable that the total amount of silver of the silver halide contained in all applied layers is 0.03-0.3 g/m 2 . 
     The reducing agent for coloring is preferably used in an amount of 0.01-10 mmol/m 2  per coloring layer in order to obtain sufficient density of the formed color. A more preferable amount for use thereof is of 0.05-5 mmol/m 2 , and an especially preferable amount for use is of 0.1-1 mmol/m 2 . If the amount is within this range, sufficient density of the formed color can be obtained. 
     Further, the amount of the coupler in coloring layers in which the reducing agent for coloring is used, is preferably 0.05-20 times as large as the amount of the reducing agent for coloring on the basis of mol conversion, more preferably 0.1-10 times, and especially preferably 0.2-5 times. If the amount is within this range, sufficient density of the formed color can be obtained. 
     
       
         
           
               
               
               
               
             
               
                   
                   
               
             
            
               
                   
                 First developing intensifier 
                   
                   
               
               
                   
                 water 
                 800 
                 ml 
               
               
                   
                 sodium 5-sulfosalicylate 
                 50 
                 g 
               
               
                   
                 benzotriazole 
                 0.02 
                 g 
               
               
                   
                 KCl 
                 2.5 
                 g 
               
               
                   
                 hydroxyethylidene-1,1-diphosphonic acid 
                 4 
                 ml 
               
               
                   
                 (30% aqueous solution) 
               
               
                   
                 hydrogen peroxide (30% aqueous solution) 
                 30 
                 ml 
               
               
                   
                 Further, water was added to the above such that 
               
               
                   
                 the total amount of the solution was 1 liter 
               
               
                   
                 pH 
                 11.5 
               
               
                   
                 First stabilizing solution 
               
               
                   
                 potassium carbonate 
                 15 
                 g 
               
               
                   
                 sodium 2-mercaptobenzimidazole-5-sulfonate 
                 1 
                 g 
               
               
                   
                 hydroxyethylidene-1,1-diphosphonic acid 
                 1 
                 ml 
               
               
                   
                 (30% aqueous solution) 
               
               
                   
                 5-chloro-2-methyl-4-isothiazoline-3-one 
                 0.02 
                 g 
               
               
                   
                 Further, water was added to the above such that 
               
               
                   
                 the total amount of the solution was 1 liter 
               
               
                   
                 pH 
                 9.5 
               
               
                   
                   
               
            
           
         
       
     
     Next, the operation and the method of using the image forming apparatus structured in the above-described manner will be explained with reference to FIGS. 1 and 2. Initially, image signals for an original document with an image are input by using the scanner or the like, and are subjected to the image processing, so as to prepare the exposing section  18  for operation. 
     Subsequently, when a command for forming the image of the original document on the photosensitive material  40  is input to the controlling section (not shown) of the apparatus body  10 , the paper feeding section  12  is operated by the command of the controlling section, and the band-shaped photosensitive material  40  is fed onto the conveying path  14 . The photosensitive material  40 , which has been fed a predetermined length onto the conveying path  14  in this manner, is cut into a predetermined size by the cutter  38 , and is then conveyed to the exposing section  18 . 
     At the exposing section  18 , the emulsion surface  40 A which is one side of the photosensitive material  40  is exposed in accordance with an image-processed data to form a latent image which corresponds to the image on the original document, and then the photosensitive material  40  is conveyed to the development-intensification processing section  20 . At the development-intensification processing section  20 , the first developing intensifier is applied on the emulsion surface  40 A of the photosensitive material  40  by the applying device  310  serving as the processing solution applying means, and the photosensitive material  40  is subjected to the developing processing for 20 seconds during which the photosensitive material  40  is conveyed 280 mm on the conveying path  14  at a predetermined temperature (40° C.). Thereafter, the excess first developing intensifier thereon is squeezed off by the rollers  364 , and then the photosensitive material  40  is conveyed to the cleaning section  24 . 
     At the cleaning section  24 , the cleaning water is splashed on the emulsion surface  40 A of the photosensitive material  40  by the shower device  52 , the photosensitive material  40  is rinsed for 5 seconds to remove alkaline components during which the photosensitive material  40  is conveyed 140 mm on the conveying path  14 , and the residual cleaning water deposited on the photosensitive material  40  is squeezed off by the squeezing rollers  56 . Next, the photosensitive material  40  is conveyed to the stabilizing section  25 . At the stabilizing section  25 , the first stabilizing solution is splashed on the emulsion surface  40 A of the photosensitive material  40  by the shower device  58 , the photosensitive material  40  is subjected to the stabilizing processing (silver-removing processing) for 5 seconds during which the photosensitive material  40  is conveyed 70 mm on the conveying path  14 , and the first stabilizing solution deposited on the photosensitive material  40  is squeezed off by the squeezing rollers  60 . Next, the photosensitive material  40  is conveyed to the drying section  26 . 
     At the drying section  26 , primarily the emulsion surface  40 A of the photosensitive material  40  wetted with the processing solution is dried for 10 seconds during which the photosensitive material  40  is conveyed 140 mm on the conveying path  14 , and then the photosensitive material  40  is conveyed from the outlet  16  onto the tray  10 A as a finished product on which the image has been formed. As a result, a series of controlling operations for the image forming processing is completed. 
     FIRST EXAMPLE 
     A first example, in which the image forming apparatus in the present first embodiment is structured such that the stabilizing section  25  is disposed at a position along the conveying path  14  that is upstream with respect to the cleaning section  24 , will be described next. 
     Inside the apparatus body  10 , the following are disposed in sequence from the paper feeding section  12  side: the exposing section  18  for exposing the photosensitive material  40 , which is the image recording material conveyed from the paper feeding section  12 , to form an image; next, the development-intensification processing section  20 ; thereafter, the stabilizing section  25 ; followed by the cleaning section  24 , the drying section  26 , and the outlet  16 . The outlet  16  is for discharging the image recording material on which the image has been formed. 
     In the present first example the mechanical structure of the stabilizing section  25  and the cleaning section  24  are equivalent to each other. The first stabilizing solution is jetted with the shower device  52  to effect stabilizing processing of the emulsion surface  40 A, which is one side of the photosensitive material  40 . Next, the cleaning water is jetted with the shower device  58  to effect cleaning processing of the emulsion surface  40 A. 
     The photosensitive material  40  and processing solutions such as the first developing intensifier and the first stabilizing solution used in the image forming apparatus of the present first example are the equivalents of those in the above-described first embodiment. 
     Further, according to the structure of the present first example, after the stabilizing processing is effected for the emulsion surface  40 A, the cleaning processing is effected therefor. Accordingly, after these steps, there is no residual first stabilizing solution on the emulsion surface  40 A. Thus, subsequent processing of the emulsion surface  40 A to remove alkaline components can be made unnecessary. 
     SECOND EXAMPLE 
     A second example will be described next. In the second example, image processings will be effected using processing solution and post-processing solution that differ from those described above, in the image forming apparatus in the present first embodiment having the structure shown in FIG.  1 . 
     In the image forming apparatus according to this second example, the processing solution and the post-processing solution having compositions as indicated below. 
     
       
         
           
               
             
               
                   
               
               
                 Second developing intensifier (Solution by mixing equal amounts 
               
               
                 of second alkaline processing solution and second solution 
               
               
                 including hydrogen peroxide) 
               
               
                   
               
             
            
               
                   
               
            
           
           
               
               
               
            
               
                 Second alkaline processing solution (Activator solution) 
                   
                   
               
               
                 water 
                 700 
                 ml 
               
               
                 potassium hydroxide 
                 44 
                 g 
               
               
                 potassium chloride 
                 1.25 
                 g 
               
               
                 benzotriazole 
                 0.01 
                 g 
               
               
                 hydroxyethylidene-1,1-diphosphonic acid 
                 4 
                 ml 
               
               
                 (30% aqueous solution) 
               
               
                 compound represented by Cpd-2 below 
                 5 
                 g 
               
               
                 surfactant 
                 0.2 
                 g 
               
               
                 (compound represented by W-1 below) 
               
               
                 Further, water was added to the above such that the total 
               
               
                 amount of the solution was 1 liter 
               
               
                 Second solution including hydrogen peroxide 
               
               
                 water 
                 800 
                 ml 
               
               
                 hydrogen peroxide (30% aqueous solution) 
                 30 
                 ml 
               
               
                 hydroxyethylidene-1,1-diphosphonic acid 
                 4 
                 ml 
               
               
                 (30% aqueous solution) 
               
               
                 compound represented by Cpd-2 below 
                 5 
                 g 
               
               
                 Further, water was added to the above such that the total 
               
               
                 amount of the solution was 1 liter 
               
               
                 pH 
                 5.5 
               
               
                 Second stabilizing solution (post-processing solution which 
               
               
                 is an acidic solution) 
               
               
                 citric acid (anhydride) 
                 30 
                 g 
               
               
                 agent which forms a complex compound with silver 
                 36 
                 g 
               
               
                 (compound represented by Cpd-1 below) 
               
               
                 surfactant (compound represented by W-1 below) 
                 0.2 
                 g 
               
               
                 Further, water was added to the above such that the total 
               
               
                 amount of the solution was 1 liter 
               
               
                 pH 
                 2 
               
            
           
           
               
            
               
                 Cpd-1 
               
               
                 
                   
                     
                     
                         
                         
                     
                   
                 
               
               
                   
               
               
                 Cpd-2 
               
               
                 
                   
                     
                     
                         
                         
                     
                   
                 
               
               
                   
               
               
                 W-1 
               
               
                 
                   
                     
                     
                         
                         
                     
                   
                 
               
               
                   
               
            
           
         
       
     
     Operation and method of use of the image forming apparatus relating to the second example structured as described above will be described next, with reference to FIGS. 1 and 2. First, image signals of an original document are input by using the scanner of the like, and are subjected to the image processing, so as to prepare the exposing section  18  for operation. 
     Subsequently, when a command for forming the image of the original document on the photosensitive material  40  is input to the controlling section (not shown) of the apparatus body  10 , the paper feeding section  12  is operated by the command of the controlling section, and the band-shaped photosensitive material  40  is fed onto the conveying path  14 . The photosensitive material  40 , which has been fed a predetermined length onto the conveying path in this matter, is cut into a predetermined size by the cutter  38 , and is then conveyed to the exposing section  18 . 
     At the exposing section  18 , the emulsion surface  40 A which is one side of the photosensitive material  40 , is exposed in accordance with an image processed-data to form a latent image which corresponds to the image on the original document. The photosensitive material  40  is then conveyed to the development-intensification processing section  20 . At the development intensification processing section  20 , the second developing intensifier (a processing solution produced by mixing equal amounts of the second alkaline processing solution and the second solution including hydrogen peroxide) at a predetermined temperature (approximately of from 35 to 45° C.) is applied onto the emulsion surface  40 A of the photosensitive material  40 . The second developing intensifier is applied with the applying device  310  serving as the processing solution applying means. The photosensitive material  40  is then subjected to the developing processing for  18  seconds, during which the photosensitive material  40  is conveyed on the conveying path  14 , which is on a heat panel. The heat panel is means for adjusting heating temperature of the development-intensification processing section  20  and adjusts the temperature to approximately 40° C. Thereafter, the excess second developing intensifier is squeezed off by the rollers  364 , and the photosensitive material  40  is conveyed to the cleaning section  24 . 
     Next, at the cleaning section  24 , which serves as the post-processing means for ensuring preservation properties of the image formed on the photosensitive material  40 , cleaning water is splashed on the emulsion surface  40 A of the photosensitive material  40  with the shower device  52 . The photosensitive material  40  is rinsed while being conveyed on the conveying path  14  so as to remove alkaline components from the emulsion surface  40 A. The residual cleaning water is squeezed off by the squeezing rollers  56 . Next, the photosensitive material  40  is conveyed to the stabilizing section  25 . 
     At the stabilizing section  25 , the second stabilizing solution is splashed onto the emulsion surface  40 A of the photosensitive material  40 . The second stabilizing solution is splashed with the shower device  58  (another non-contacting type processing solution applying means using the jetting tank  312  of the applying device  310  or the like may be used instead of the shower device  58 ). The photosensitive material  40  is subjected to the stabilizing processing while being conveyed on the conveying path  14 . In the stabilizing processing, residual silver on the emulsion surface  40 A of the photosensitive material  40  forms a complex compound with the second stabilizing solution. Thereafter, the second stabilizing solution deposited on the photosensitive material  40  is squeezed off by the squeezing rollers  60 , and the photosensitive material  40  is conveyed to the drying section  26 . 
     At the drying section  26 , the emulsion surface  40 A of the photosensitive material  40  wetted with the processing solution is dried while the photosensitive material  40  is conveyed on the conveying path  14 . The photosensitive material  40  is then conveyed from the outlet  16  onto the tray  10 A as a finished product on which the image has been formed. As a result, a series of controlling operations for the image forming processing is completed. 
     The processing in each of the above-described operation processes is performed only for the emulsion surface  40 A which is one side of the photosensitive material  40 . Accordingly, compared with the case in which both the emulsion surface  40 A of the photosensitive material  40  and the surface opposite to the emulsion surface  40 A are wetted in the same manner, such as in a conventional so-called dipping method or the like, the amount of the processing solution to be applied can be reduced and the deterioration of the entire processing solution can be decreased. This is because each processing solution needs to be applied and the cleaning and stabilizing processings need to be performed only on the emulsion surface  40 A which is one side of the photosensitive material  40 . Further, compared with the case in which the entirety of the two surfaces of the photosensitive material  40  are dried in the same manner, the time for drying can be shortened and thus the time for processing can be shortened considerably, because the emulsion surface  40 A side of the photosensitive material  40  is primarily required to be dried. 
     Plural series of routes, in which the previously described processing operations such as exposing, developing, bleach-fixing, cleaning, drying and the like are performed, may be provided in the image forming apparatus. 
     In the structure of the present first embodiment, the conventional so-called dipping method is not used in the image forming apparatus. Accordingly, a large-sized processing solution tank for dipping the photosensitive material is not needed. In addition, a conveying path that winds considerably in the vertical direction, i.e., a conveying path that extends from outside and above the processing solution in the processing solution tank into the processing solution and then extends to outside and above the processing solution again, does not need to be set. 
     As a result, a flat conveying path for the photosensitive material can be set, which does not wind considerably in the vertical direction. Further, in the structure of the present first embodiment, the processing solution is used up, and waste solution does not remain. Therefore, a large-sized waste solution tank is not needed. Thus, the processing solution tank for dipping, the large conveying path winding in the vertical direction, and the waste solution tank are not needed. Accordingly, the entire image forming apparatus can be structured simply and compactly. 
     In cases using processing solution which deteriorates severely when used, such as the processing solution mixture containing hydrogen peroxide, if the dipping method is used, all of the processing solution in the tank deteriorates rapidly merely by immersing the photosensitive material in the processing solution in the tank. As a result, the amount of the waste solution increases. However, in a case using a processing solution mixed with hydrogen peroxide so that each necessary amount thereof is applied on the photosensitive material by the processing solution applying means whereby each small amount thereof is used up, the deterioration of the processing solution does not spread to the entire processing solution during this processing. Therefore, the entire processing solution can be used effectively to the last. 
     Further, since the processing solution mixed with hydrogen peroxide is used as a developing intensifier, processing of the waste solution thereof does not harm the environment, as hydrogen peroxide separates into water and oxygen in the form of gas with time. 
     Next, a second embodiment of the image forming apparatus of the present invention will be described with reference to FIG.  12 . 
     In the development-intensification processing section of the image forming apparatus according to the second embodiment, the first alkaline processing solution and the first solution including hydrogen peroxide, each of which is a processing solution, are applied on the photosensitive material by separate processing solution applying means. In the second embodiment, the cleaning section is disposed at a portion where the conveying path of the photosensitive material is set in a substantially vertical direction. Further, the stabilizing section and the drying section are disposed at a portion where the conveying path is set so that the emulsion surface of the photosensitive material moving on the conveying path is faced in a substantially vertically downward direction. 
     In the image forming apparatus shown in FIG. 12, the development-intensification processing section  20  disposed inside the apparatus body  10  comprises two processing solution applying means, i.e., applying devices  310 , which are disposed side by side, and each of which is similar to the applying device illustrated in the previously described FIGS. 3-7. 
     A jetting tank  312 A of the applying device  310  is disposed at a position more upstream the conveying path  14  than a jetting tank  312 B, and applies the first alkaline processing solution only on the emulsion surface  40 A, which is one side of the photosensitive material  40 . 
     The jetting tank  312 B of the applying device  310  is disposed at a position more downstream the conveying path  14  than the jetting tank  312 A, and applies the first solution including hydrogen peroxide on the emulsion surface  40 A immediately after the first alkaline processing solution has been applied thereon. On the emulsion surface  40 A of the photosensitive material  40 , the applied first solution including hydrogen peroxide is mixed with the first alkaline processing solution which has been applied thereon. 
     Further, each of the jetting tanks  312 A and  312 B of the applying devices  310  jets the respective processing solution from the nozzle holes  324  (shown in FIG. 4) which do not touch the emulsion surface  40 A of the photosensitive material  40 . This can prevent the first solution including hydrogen peroxide from deteriorating. The cause of such deterioration is that the chemical substance on the emulsion surface  40 A flows in reverse into the nozzle holes  324  and mixes in the first solution including hydrogen peroxide stored in the jetting tank  312 B of the applying device  310 , and then chemical changes and the like are caused. 
     Therefore, the first solution including hydrogen peroxide, which is stored in the jetting tank  312 B of the applying device  310  so as not to deteriorate, can be used up without wasting. 
     As shown in FIG. 12, at a position that faces the two sets of the jetting tanks  312 A and  312 B disposed side by side and is at the side of the conveying path  14  opposite thereto, the holding means is provided. The holding means is provided in order to prevent the nozzle holes  324  from clogging caused by evaporation of the water content of the processing solution and by deposition of components thereof at the respective nozzle holes  324  portion of the jetting tanks  312 A and  312 B, when the jetting tanks are not being used. Another reason for providing the holding means is in order to clean the nozzle holes  324  portions as needed by immersing the portions in the cleaning solution. 
     The holding means comprises the pan member  352  which has a substantially U-shaped cross-section and which can be operated to move in the direction of arrow C in FIG.  12 . The pan member  352  is large enough to accommodate both of the two nozzle plate  322  portions (shown in FIGS. 4-7) of the two sets of the jetting tanks  312 A and  312 B disposed side by side, respectively. 
     When each of the jetting tanks  312 A and  312 B performs the operation of atomizing the processing solution, the pan member  352  is located at a position that is vertically downward from the conveying path  14  and is just below both of the nozzle holes  324  portions. In this case, the pan member  352  is used to catch the droplets of the processing solution which have been jetted from the nozzle holes  324  and have not been deposited on the photosensitive material  40 . 
     For times when neither of the two sets of the jetting tanks  312 A and  312 B is being used, the pan member  352  is moved in the vertically upward direction and the respective nozzle holes  324  portion of each of the jetting tanks  312  is immersed in the solution stored to a predetermined level in the recessed portion of the pan member  352  so as to prevent the nozzle holes  324  portions from drying and causing clogging. Further, the recessed portion of the pan member  352  may be filled with the cleaning solution to perform cleaning of the nozzle holes  324  as needed. 
     On the emulsion surface  40 A of the photosensitive material  40 , the first alkaline processing solution and the first solution including hydrogen peroxide are separately deposited in a short time so as to be layered on each other by the jetting tanks  312 A and  312 B of the two sets of the applying devices  310  in the above-described manner. The photosensitive material  40  is then conveyed along the heat-control section  354  which is at a position along the conveying path  14  that is downstream with respect to the jetting tanks  312 A and  312 B of the applying devices  310  on the conveying path  14 . During the conveyance, chemical changes are caused and the development-intensification processing is performed. 
     As shown in FIG. 12, the cleaning section  24  serving as the means for post-processing which is a step for ensuring preservation properties of the image formed on the photographic material  40 , is disposed next to the development-intensification processing section  20  on the conveying path  14 . The cleaning section  24  is disposed at a portion of the conveying path  14  at which the photosensitive material  40  is conveyed so as to extend in a substantially vertical direction. First conveying rollers  78  are provided immediately before a curving portion of the conveying path  14 . At a vertical portion of the conveying path  14  which is at a position downstream with respect to the first conveying rollers  78 , second, third, and fourth conveying rollers  80 ,  82  and  84  as three sets of conveying-and-squeezing rollers are disposed at equal intervals. 
     Further, a shower device  86  is disposed between the first and second conveying rollers  78  and  80 , between the second and third conveying rollers  80  and  82 , and between the third and fourth conveying rollers  82  and  84 , respectively. Each of the shower devices  86  sprays the cleaning water only on the emulsion surface  40 A to clean the emulsion surface  40 A portion. 
     Part of the cleaning water, which has been sprayed on the emulsion surface  40 A extending in the substantially vertical direction by each of the shower devices  86  in this manner, flows downward due to its own weight, and the flowed cleaning water is squeezed by the first, second or third conveying rollers  78 ,  80  or  82 . The cleaning water deposited on the emulsion surface  40 A is squeezed by the fourth conveying rollers  84 . Then, the squeezed cleaning water flows into a pan  88 , which is disposed vertically below the first, second, third and fourth conveying rollers  78 ,  80 ,  82  and  84 . The cleaning water is thus recovered in the pan  88 . 
     When the cleaning water is sprayed on the emulsion surface of the photosensitive material  40  extending in the vertical direction, the sprayed cleaning water tends to flow in the vertically downward direction of the emulsion surface  40 A. This can prevent the cleaning water from flowing toward the side surface opposite to the emulsion surface  40 A of the photosensitive material  40 . Thus, the operation of cleaning can be performed to clean only the emulsion surface  40 A of the photosensitive material  40 , keeping the opposite surface dry. 
     As shown in FIG. 12, the stabilizing section  25  is disposed at a position downstream with respect to the cleaning section  24  on the conveying path  14 . The stabilizing section  25  is disposed at a portion of the conveying path at which the photosensitive material  40  is conveyed in a substantially horizontal direction in a state in which the emulsion surface  40 A thereof faces the vertically downward direction. 
     In other words, as shown in FIG. 12, the portion extending from the development-intensification processing section  20  through the cleaning section  24  and the stabilizing section  25  to the drying section  26  of the conveying path  14  is set in a U-shape. The stabilizing section  25  is disposed at a portion of the conveying path  14 , which portion is set at the upper side in the substantially horizontal direction. 
     At the stabilizing section  25 , which serves as a means for post-processing which is a step for ensuring preservation properties of the image formed on the photosensitive material  40 , a roller bead  90  for applying the first stabilizing solution on the emulsion surface  40 A is disposed. The roller bead  90  comprises a roller  94  immersed halfway into the first stabilizing solution in a stabilizing solution tank  92 . A suitable amount of the first stabilizing solution is applied on the emulsion surface  40 A, by rotating the roller  94  on the emulsion surface  40 A, which corresponds to the down-faced side of the photosensitive material  40  conveyed on the conveying path  14 . 
     If the first stabilizing solution is applied on the down-faced emulsion surface  40 A of the photosensitive material  40  by the roller bead  90  in this manner, the first stabilizing solution deposited on the emulsion surface  40 A does not resist gravity to move onto the upper side surface of the photosensitive material  40  and thus does not wet the upper side surface. In this way, the first stabilizing solution can be applied only on the emulsion surface  40 A. 
     At a portion adjacent to the roller bead  90  in the downstream direction on the conveying path  14 , a pair of rollers  96  are disposed, which rotate on the photosensitive material  40  while nipping the photosensitive material  40  therebetween so as to squeeze off the processing solution. Above the rollers  96 , a cleaning section  97  is provided. The cleaning section  97  is for cleaning the rollers  96  by causing cleaning solution to drip down from external peripheral surfaces thereof. Further, a pan  98  is disposed vertically below the rollers  96 . The pan  98  catches spent cleaning solution dripping from the rollers  96  and recovers the dripped cleaning solution. 
     At the portion extending from the rollers  96  to the outlet  16  on the conveying path  14 , the drying section  26  is provided. 
     In the image forming apparatus of the second embodiment, the structure, operation and effect other than those described above are the same as those of the previously described first embodiment. Accordingly, the same members are given the same reference numerals, and detailed descriptions thereof are omitted. 
     Next, the photosensitive material  40  used in the image forming apparatus of the second embodiment each of the processing solutions will be described. 
     The photosensitive material  40  used in the image forming apparatus is the same as that used in the previously described first embodiment. 
     Each of the processing solutions used in the image forming apparatus is described below. 
     
       
         
           
               
               
               
             
               
                   
               
             
            
               
                 (First alkaline processing solution) 
                   
                   
               
               
                 water 
                 800 
                 ml 
               
               
                 soduim 5-sulfosalicylate 
                 50 
                 g 
               
               
                 KCl 
                 2.5 
                 g 
               
               
                 benzotriazole 
                 0.02 
                 g 
               
               
                 hydroxyethylidene-1,1-diphosphonic acid 
                 4 
                 ml 
               
               
                 (30% aqueous solution) 
               
               
                 surfactant 
                 5 
                 g 
               
               
                 (compound represented by the following Stil-1) 
               
               
                 Further, water was added to the above such that the total 
               
               
                 amount of the solution was 1 liter 
               
               
                 pH 
                 13 
               
            
           
           
               
            
               
                 Stil-1 
               
               
                 
                   
                     
                     
                         
                         
                     
                   
                 
               
               
                   
               
            
           
           
               
               
               
            
               
                 (First solution uncluding hydrogen peroxide) 
                   
                   
               
               
                 water 
                 800 
                 ml 
               
               
                 hydrogen peroxide (30% aqueous solution) 
                 30 
                 ml 
               
               
                 surfactant (Stil-1) 
                 5 
                 g 
               
               
                 Further, water was added to the above such that the total 
               
               
                 amount of the solution was 1 liter 
               
               
                 pH 
                 5.8 
               
               
                 (First stabilizing solution) 
               
               
                 potassium carbonate 
                 15 
                 g 
               
               
                 soduim 2-mercaptobenzimidazole-5-sulfonate 
                 1 
                 g 
               
               
                 hydroxyethylidene-1,1-diphosphonic acid 
                 1 
                 ml 
               
               
                 (30% aqueous solution) 
               
               
                 5-chloro-2-methyl-4-isothiazoline-3-one 
                 0.02 
                 g 
               
               
                 Further, water was added to the above such that the total 
               
               
                 amount of the solution was 1 liter 
               
               
                 pH 
                 7.0 
               
               
                   
               
            
           
         
       
     
     Next, the operation and the method of using the image forming apparatus, wherein the apparatus is structured in the above-described manner and is of the second embodiment, will be explained with reference to FIG.  12 . Initially, image signals for an original document with an image are input by using the scanner or the like, and are subjected to the image processing, so as to prepare the exposing section  18  for operation. 
     Subsequently, when a command for forming the image of the original document on the photosensitive material  40  is input to the controlling section (not shown) of the apparatus body  10 , the paper feeding section  12  is operated by the command of the controlling section, and the band-shaped photosensitive material  40  is fed onto the conveying path  14 . The photosensitive material  40 , which has been fed a predetermined length onto the conveying path  14  in this manner, is cut into a predetermined size by the cutter  38 , and is then conveyed to the exposing section  18 . 
     At the exposing section  18 , the emulsion surface  40 A which is one side of the photosensitive material  40  is exposed in accordance with an image-processed data to form a latent image which corresponds to the image on the original document, and then the photosensitive material  40  is conveyed to the development-intensification processing section  20 . At the development-intensification processing section  20 , the first alkaline processing solution is applied on the emulsion surface  40 A of the photosensitive material  40  by the jetting tank  312 A of the applying device  310  serving as the processing solution applying means, under conditions in which the quantity for application is 40 cc/m 2 , the width of the nozzle is 5.5 cm, and the length for application is 12 cm. 
     Further, immediately after applying the first alkaline processing solution, the first solution including hydrogen peroxide is applied on the emulsion surface  40 A of the photosensitive material  40  by the jetting tank  312 B so as to be layered onto the first alkaline processing solution, under conditions in which the quantity for application is 40 cc/m 2 , the width of the nozzle is 5.5 cm, and the length for application is 12 cm. 
     The photosensitive material  40  is subjected to the processing for  30  seconds during which the photosensitive material  40  is conveyed on the conveying path  14  at a predetermined temperature (40° C.). Thereafter, the excess processing solution thereon is squeezed off by the rollers  364 , and then the photosensitive material  40  is conveyed to the cleaning section  24 . 
     At the cleaning section  24 , which is the means for post-processing which is a step for ensuring preservation properties of the image formed on the photosensitive material  40 , the cleaning water (30° C.) is splashed on the emulsion surface  40 A of the photosensitive material  40  by the shower devices  86 , the photosensitive material  40  is rinsed for 90 seconds, and the residual cleaning water deposited on the photosensitive material  40  is squeezed off by the squeezing rollers  84 . Next, the photosensitive material  40  is conveyed to the stabilizing section  25 . 
     At the stabilizing section  25 , which is the means for post-processing which is a step for ensuring preservation properties of the image formed on the photosensitive material  40 , the first stabilizing solution (40° C.) is applied on the emulsion surface  40 A of the photosensitive material  40  by the roller bead  90 , and the photosensitive material  40  is subjected to the stabilizing processing for 45 seconds. Next, the photosensitive material  40  is conveyed to the drying section  26 . 
     At the drying section  26 , primarily the emulsion surface  40 A of the photosensitive material  40  wetted with the processing solution is dried for 10 seconds during which the photosensitive material  40  is conveyed 140 mm on the conveying path  14 , and then the photosensitive material  40  is conveyed from the outlet  16  onto the tray as a finished product on which the image has been formed. As a result, a series of controlling operations for the image forming processing is completed. 
     The processing in each of the above-described operation processes is performed only for the emulsion surface  40 A. Accordingly, compared with the case in which both the emulsion surface  40 A of the photosensitive material  40  and the surface opposite to the emulsion surface  40 A are wetted in the same manner, such as in a conventional so-called dipping method or the like, the amount of the processing solution to be applied can be reduced and the deterioration of the entire processing solution can be decreased. This is because each processing solution needs to be applied and the cleaning and stabilizing processings need to be performed only on the emulsion surface  40 A which is one side of the photosensitive material  40 . Further, compared with the case in which the entirety of the two surfaces of the photosensitive material  40  are dried in the same manner, the time for drying can be shortened and thus the time for processing can be shortened considerably, because the emulsion surface  40 A side of the photosensitive material  40  is primarily required to be dried. 
     Plural series of routes, in which the previously described processing operations such as exposing, developing, cleaning, drying and the like are performed, may be provided in the image forming apparatus. 
     In the structure of the present second embodiment, the conventional so-called dipping method is not used in the image forming apparatus. Accordingly, a large-sized processing solution tank for dipping the photosensitive material is not needed. 
     Further, in the structure of the second embodiment, the processing solution is used up, and waste solution does not remain. Accordingly, a large-sized waste solution tank is not needed. Thus, the entire image forming apparatus can be structured simply and compactly. 
     Next, a third embodiment of the image forming apparatus of the present invention will be explained, with reference to FIG.  12 . 
     In the development-intensification processing section of the image forming apparatus according to the present third embodiment, the second alkaline processing solution and the second solution including hydrogen peroxide in the above-described second example of the first embodiment, are each applied onto the photosensitive material with separate processing solution applying means. 
     In the image forming apparatus shown in FIG. 12, the development-intensification processing section  20  disposed inside the apparatus body  10  comprises two processing solution applying means, i.e., the applying devices  310 , which are disposed side by side, each of which is similar to the applying device illustrated in the previously described FIGS. 3-7. 
     The jetting tank  312 A of the applying device  310  is disposed at a position more upstream the conveying path  14  than the jetting tank  312 B, and applies the second alkaline processing solution only on the emulsion surface  40 A, which is one side of the photosensitive material  40 . 
     The jetting tank  312 B of the applying device  310  applies the second solution including hydrogen peroxide on the emulsion surface  40 A immediately after the first alkaline processing solution has been applied thereon. Accordingly, on the emulsion surface  40 A of the photosensitive material  40 , the applied second solution including hydrogen peroxide is mixed with the second alkaline processing solution which has been applied thereon. 
     The jetting tanks  312 A and  312 B are non-contacting type applying means. Each of the jetting tanks  312 A and  312 B of the applying devices  310  jets the respective processing solution from the nozzle holes  324  (shown in FIG. 4) which do not touch the emulsion surface  40 A of the photosensitive material  40 . This can prevent the second solution including hydrogen peroxide from deteriorating. The cause of such deterioration is that the chemical substance on the emulsion surface  40 A flows in reverse into the nozzle holes  324  and mixes in the second solution including hydrogen peroxide stored in the jetting tank  312 B of the applying device  310 , and then chemical changes and the like are caused. 
     Therefore, the second solution including hydrogen peroxide, which is stored in the jetting tank  312 B of the applying device  310  so as not to deteriorate, can be used up without wasting. 
     On the emulsion surface  40 A of the photosensitive material  40 , the second alkaline processing solution and the second solution including hydrogen peroxide are separately deposited in a short time so as to be layered on each other by the jetting tanks  312 A and  312 B of the two applying devices  310  in the above-described manner. The photosensitive material  40  is then conveyed along the heat-control section  354  which is at a position along the conveying path  14  that is downstream with respect to the jetting tanks  312 A and  312 B of the applying devices  310  on the conveying path  14 . During the conveyance, chemical changes are caused and the development-intensification processing is performed. 
     As shown in FIG. 12, the cleaning section  24  serving as the means for post-processing which is a step for ensuring preservation properties of the image formed on the photographic material  40 , is disposed next to the development-intensification processing section  20  on the conveying path  14 . The cleaning section  24  is disposed at a portion of the conveying path  14  at which the photosensitive material  40  is conveyed so as to extend in a substantially vertical direction. First conveying rollers  78  are provided immediately before a curving portion of the conveying path  14 . At a vertical portion of the conveying path  14  which is at a position downstream with respect to the first conveying rollers  78 , second, third, and fourth conveying rollers  80 ,  82  and  84  as three sets of conveying-and-squeezing rollers are disposed at equal intervals. 
     Further, shower devices  86  are disposed between the first and second conveying rollers  78  and  80 , between the second and third conveying rollers  80  and  82 , and between the third and fourth conveying rollers  82  and  84 , respectively. Each of the shower devices  86  sprays the cleaning water only on the emulsion surface  40 A to clean the emulsion surface  40 A portion. 
     When the cleaning water is sprayed on the emulsion surface of the photosensitive material  40  extending in the vertical direction, the sprayed cleaning water tends to flow in the vertically downward direction of the emulsion surface  40 A. This can prevent the cleaning water from flowing toward the side surface opposite to the emulsion surface  40 A of the photosensitive material  40 . Thus, the operation of cleaning can be performed to clean only the emulsion surface  40 A of the photosensitive material  40 , keeping the opposite surface dry. 
     As shown in FIG. 12, the stabilizing section  25  is disposed at a position downstream with respect to the cleaning section  24  on the conveying path  14 . The stabilizing section  25  is disposed at a portion of the conveying path at which the photosensitive material  40  is conveyed in a substantially horizontal direction in a state in which the emulsion surface  40 A thereof faces the vertically downward direction. 
     At the stabilizing section  25 , the roller bead  90  for applying the second stabilizing solution on the emulsion surface  40 A is disposed. The roller bead  90  comprises the roller  94  immersed halfway into the second stabilizing solution in the stabilizing solution tank  92 . A suitable amount of the second stabilizing solution is applied on the emulsion surface  40 A, by rotating the roller  94  on the emulsion surface  40 A, which corresponds to the down-faced side of the photosensitive material  40  conveyed on the conveying path  14 . 
     If the second stabilizing solution is applied on the down-faced emulsion surface  40 A of the photosensitive material  40  by the roller bead  90  in this manner, the second stabilizing solution deposited on the emulsion surface  40 A does not resist gravity to move onto the upper side surface of the photosensitive material  40  and thus does not wet the upper side surface. In this way, the second stabilizing solution can be applied only on the emulsion surface  40 A. Further, instead of the roller bead  90 , another non-contacting processing solution applying means using the jetting tank  312  of the applying device  320  or the like may be used. 
     At a portion adjacent to the roller bead  90  in the downstream direction on the conveying path  14 , the pair of rollers  96  are disposed, which rotate on the photosensitive material  40  while nipping the photosensitive material  40  therebetween so as to squeeze off the post-processing solution. Above the rollers  96 , the cleaning section  97  is provided. The cleaning section  97  is for cleaning the rollers  96  by causing the cleaning solution to drip down from external peripheral surfaces thereof. Further, the pan  98  is disposed vertically below the rollers  96 . The pan  98  catches spent cleaning solution dripping from the rollers  96  and recovers the dripped cleaning solution. 
     At the portion extending from the rollers  96  to the outlet  16  on the conveying path  14 , the drying section  26  is provided. 
     In the image forming apparatus of the third embodiment, the structure, operation and effect other than those described above are the same as those of the previously described second embodiment. Accordingly, the same members are given the same reference numerals, and detailed descriptions thereof are omitted. 
     Next, a fourth embodiment of the image forming apparatus of the present invention will be described with reference to FIG.  13 . 
     In the development-intensification processing section  20  of the image forming apparatus according to the present fourth embodiment, the first alkaline processing solution and the first solution including hydrogen peroxide, each of which is in the above-described second embodiment, are each applied onto the photosensitive material with separate processing solution applying means. In addition, the fourth embodiment is structured by disposing on the conveying path for the photosensitive material the development-intensification processing section  20 , followed by the stabilizing section  25  and the cleaning section  24 . The stabilizing section  25  serves as the means for post-processing which is a step for ensuring preservation properties of the image formed on the photosensitive material  40 . 
     In the image forming apparatus shown in FIG. 13, the development-intensification processing section  20  disposed inside the apparatus body  10  comprises two processing solution applying means, i.e., the applying devices  310 , which are disposed side by side, each of which is similar to the applying device illustrated in the previously described FIGS. 3-7. 
     The jetting tank  312 A of the applying device  310  is disposed at a position more upstream the conveying path  14  than the jetting tank  312 B, and applies the first alkaline processing solution only on the emulsion surface  40 A, which is one side of the photosensitive material  40 . 
     The jetting tank  312 B of the applying device  310  applies the first solution including hydrogen peroxide on the emulsion surface  40 A immediately after the first alkaline processing solution has been applied thereon. Accordingly, on the emulsion surface  40 A of the photosensitive material  40 , the applied first solution including hydrogen peroxide is mixed with the first alkaline processing solution which has been applied thereon. Each of the jetting tanks  312 A and  312 B of the applying devices  310  jets the respective processing solution from the nozzle holes  324  (shown in FIG. 4) which do not touch the emulsion surface  40 A of the photosensitive material  40 . This can prevent the first solution including hydrogen peroxide from deteriorating. The cause of such deterioration is that the chemical substance on the emulsion surface  40 A flows in reverse into the nozzle holes  324  and mixes in the first solution including hydrogen peroxide stored in the jetting tank  312 B of the applying device  310 , and then chemical changes and the like are caused. 
     Therefore, the first solution including hydrogen peroxide, which is stored in the jetting tank  312 B of the applying device  310  so as not to deteriorate, can be used up without wasting. 
     On the emulsion surface  40 A of the photosensitive material  40 , the first alkaline processing solution and the first solution including hydrogen peroxide are separately deposited in a short time so as to be layered on each other by the jetting tanks  312 A and  312 B of the two applying devices  310  in the above-described manner. The photosensitive material  40  is then conveyed along the heat-control section  354  which is at a position along the conveying path  14  that is downstream with respect to the jetting tanks  312 A and  312 B of the applying devices  310  on the conveying path  14 . During the conveyance, chemical changes are caused and the development-intensification processing is performed. 
     As shown in FIG. 13, the stabilizing section  25  serving as the means for post-processing which is a step for ensuring preservation properties of the image formed on the photographic material  40 , is disposed next to the development-intensification processing section  20  on the conveying path  14 . The stabilizing section  25  is disposed at a portion of the conveying path  14  at which the photosensitive material  40  is conveyed so as to extend in a substantially horizontal direction while the emulsion surface  40 A faces downward in the vertical direction. 
     As shown in FIG. 13, the conveying path  14  is set in a u-shaped form, from the development-intensification processing section  20 , the stabilizing section  25  and to the cleaning section  24 . The stabilizing section  25  is disposed at a portion at the beginning of the conveying path  14  at the upper side (of FIG.  13 ), which is set in the substantially horizontal direction. 
     At the stabilizing section  25 , the roller bead  90  for applying the first stabilizing solution on the emulsion surface  40 A is disposed. The roller bead  90  comprises the roller  94  immersed halfway into the first stabilizing solution in the stabilizing solution tank  92 . A suitable amount of the first stabilizing solution is applied on the emulsion surface  40 A, by rotating the roller  94  on the emulsion surface  40 A, which corresponds to the down-faced side of the photosensitive material  40  conveyed on the conveying path  14 . 
     If the first stabilizing solution is applied on the down-faced emulsion surface  40 A of the photosensitive material  40  by the roller bead  90  in this manner, the first stabilizing solution deposited on the emulsion surface  40 A does not resist gravity to move onto the upper side surface of the photosensitive material  40  and thus does not wet the upper side surface. In this way, the first stabilizing solution can be applied only on the emulsion surface  40 A. 
     The cleaning section  24  is disposed after the stabilizing section  25  at the conveying path  14 . As illustrated in FIG. 13, the cleaning section  24  is disposed at a portion at which the photosensitive material  40  on the conveying path  14  is conveyed so as to extend in the substantially horizontal direction, with the emulsion surface  40 A thereof facing downward in the vertical direction. The cleaning section  24  is another portion of the means for post-processing, which is a step for ensuring preservation properties of an image formed on the photosensitive material  40 . 
     Accordingly, the second conveying rollers  80  are disposed at a portion at which the conveying path  14  conveys the photosensitive material in a substantially horizontal direction, downstream from the first conveying rollers  78 , which are near the stabilizing section  25 . A predetermined distance is left between the second conveying rollers  80  and the first conveying rollers  78 . 
     Further, the shower device  86  as non-contacting type applying means is disposed between the first and second conveying rollers  78  and  80 . The shower device  86  sprays the cleaning water only on the emulsion surface  40 A, which is one side of the photosensitive material  40  conveyed in the horizontal direction. The shower device  86  thereby cleans the emulsion surface  40 A portion. A pan  88  collects the spent cleaning solution. 
     When the cleaning water is sprayed on the emulsion surface of the photosensitive material  40  facing downward in the vertical direction, the cleaning water deposited on the emulsion surface  40 A does not resist gravity to move onto the upper side surface of the photosensitive material  40  and thus does not wet the upper side surface. Thus, the operation of cleaning can be performed to clean only the emulsion surface  40 A of the photosensitive material  40 , keeping the opposite surface dry. 
     In the image forming apparatus of the fourth embodiment, the structure, operation and effect other than those described above are the same as those of the previously described second embodiment. Accordingly, the same members are given the same reference numerals, and detailed descriptions thereof are omitted. 
     Next, a fifth embodiment of the image forming apparatus of the present invention will be explained, with reference to FIG.  14 . 
     In the development-intensification processing section of the image forming apparatus according to the present fifth embodiment, the second alkaline processing solution and the second solution including hydrogen peroxide in the above-described second example of the first embodiment, are each applied onto the photosensitive material with separate processing solution applying means. In addition, the fifth embodiment is structured by disposing a stabilizing section and a drying section at a portion of the conveying path set so that the emulsion surface of the photosensitive material faces substantially downward in the vertical direction. The stabilizing section serves as the means for post-processing which is a step for ensuring preservation properties of the image formed on the photosensitive material  40 . The image forming apparatus of the present fifth embodiment has no cleaning section. 
     In the image forming apparatus shown in FIG. 14, the development-intensification processing section  20  disposed inside the apparatus body  10  comprises two processing solution applying means, i.e., the applying devices  310 , which are disposed side by side, each of which is similar to the applying device illustrated in the previously described FIGS. 3-7. 
     The jetting tank  312 A of the applying device  310  is disposed at a position more upstream the conveying path  14  than the jetting tank  312 B, and applies the second alkaline processing solution only on the emulsion surface  40 A, which is one side of the photosensitive material  40 . 
     The jetting tank  312 B of the applying device  310  applies the second solution including hydrogen peroxide on the emulsion surface  40 A immediately after the second alkaline processing solution has been applied thereon. Accordingly, on the emulsion surface  40 A of the photosensitive material  40 , the applied second solution including hydrogen peroxide is mixed with the second alkaline processing solution which has been applied thereon. 
     Each of the jetting tanks  312 A and  312 B of the applying devices  310  jets the respective processing solution from the nozzle holes  324  (shown in FIG. 4) which do not touch the emulsion surface  40 A of the photosensitive material  40 . This can prevent the second solution including hydrogen peroxide from deteriorating. The cause of such deterioration is that the chemical substance on the emulsion surface  40 A flows in reverse into the nozzle holes  324  and mixes in the second solution including hydrogen peroxide stored in the jetting tank  312 B of the applying device  310 , and then chemical changes and the like are caused. 
     Therefore, the second solution including hydrogen peroxide, which is stored in the jetting tank  312 B of the applying device  310  so as not to deteriorate, can be used up without wasting. 
     On the emulsion surface  40 A of the photosensitive material  40 , the second alkaline processing solution and the second solution including hydrogen peroxide are separately deposited in a short time so as to be layered on each other by the jetting tanks  312 A and  312 B of the two applying devices  310  in the above-described manner. The photosensitive material  40  is then conveyed along the heat-control section  354  which is at a position along the conveying path  14  that is downstream with respect to the jetting tanks  312 A and  312 B of the applying devices  310  on the conveying path  14 . During the conveyance, chemical changes are caused and the development-intensification processing is performed. 
     As shown in FIG. 14, the stabilizing section  25  is disposed at a position downstream with respect to the development-intensification processing section  20  on the conveying path  14 . The stabilizing section  25  is disposed at a portion of the conveying path at which the photosensitive material  40  is conveyed in a substantially horizontal direction in a state in which the emulsion surface  40 A thereof faces the vertically downward direction. The stabilizing section  25  is the means for post-processing which is a step for ensuring preservation properties of an image formed on the photosensitive material  40 . 
     As shown in FIG. 14, the conveying path  14  is set in a u-shaped form, from the development-intensification processing section  20 , the stabilizing section  25 , and to the drying section  26 . The stabilizing section  25  is disposed at a portion at the beginning of the conveying path  14  at the upper side (of FIG.  14 ), which is set in the substantially horizontal direction. 
     At the stabilizing section  25 , the roller bead  90  for applying the second stabilizing solution on the emulsion surface  40 A is disposed, which second stabilizing solution is a post-processing solution and is described in the second example of the first embodiment. The roller bead  90  comprises the roller  94  immersed halfway into the second stabilizing solution in the stabilizing solution tank  92 . A suitable amount of the second stabilizing solution is applied on the emulsion surface  40 A, by rotating the roller  94  on the emulsion surface  40 A, which corresponds to the down-faced side of the photosensitive material  40  conveyed on the conveying path  14 . 
     If the second stabilizing solution is applied on the down-faced emulsion surface  40 A of the photosensitive material  40  by the roller bead  90  in this manner, the second stabilizing solution deposited on the emulsion surface  40 A does not resist gravity to move onto the upper side surface of the photosensitive material  40  and thus does not wet the upper side surface. In this way, the second stabilizing solution can be applied only on the emulsion surface  40 A. 
     At a portion adjacent to the roller bead  90  in the downstream direction on the conveying path  14 , the pair of rollers  96  are disposed, which rotate on the photosensitive material  40  while nipping the photosensitive material  40  therebetween so as to squeeze off the post-processing solution. Above the rollers  96 , the cleaning section  97  is provided. The cleaning section  97  is for cleaning the rollers  96  by causing the cleaning solution to drip down from external peripheral surfaces thereof. Further, the pan  98  is disposed vertically below the rollers  96 . The pan  98  catches spent cleaning solution dripping from the rollers  96  and recovers the dripped cleaning solution. 
     At the portion extending from the rollers  96  to the outlet  16  on the conveying path  14 , the drying section  26  is provided. 
     In the image forming apparatus of the fifth embodiment, the structure and effect other than those described above are the same as those of the previously described second embodiment. Accordingly, the same members are given the same reference numerals, and detailed descriptions thereof are omitted. 
     Further, in the image forming apparatus of the present fifth embodiment, the photosensitive material  40 , and each of the processing solutions and post-processing solutions are equivalent to those described in the second example of the first embodiment. 
     Next, a description will be provided of operation and method of use of the image forming apparatus relating to the fifth embodiment structured as described above, with reference to FIG.  14 . 
     First, image signals of an original are input by using the scanner of the like, and are subjected to the image processing, so as to prepare the exposing section  18  for operation. 
     Subsequently, when a command for forming the image of the original document on the photosensitive material  40  is input to the controlling section (not shown) of the apparatus body  10 , the paper feeding section  12  is operated by the command of the controlling section, and the band-shaped photosensitive material  40  is fed onto the conveying path  14 . The photosensitive material  40 , which has been fed a predetermined length onto the conveying path in this matter, is cut into a predetermined size by the cutter  38 , and is then conveyed to the exposing section  18 . 
     At the exposing section  18 , the emulsion surface  40 A, which is one side of the photosensitive material  40 , is exposed in accordance with an image processed-data to form a latent image which corresponds to the image on the original document. The photosensitive material  40  is then conveyed to the development-intensification processing section  20 . At the development-intensification processing section  20 , the second alkaline processing solution (alkaline activator solution) at a predetermined temperature (approximately of from 35 to 45° C.) is applied onto the emulsion surface  40 A of the photosensitive material  40 . The second alkaline solution is applied with the applying device  310  serving as the processing solution applying means. 
     The conditions for application at this time are as follows: the quantity of the second alkaline processing solution applied is 20 cc/m 2 , the pitch P between the nozzle holes is ({square root over (3+L )})·D/2 or less =150 μm, the width of the nozzle (the width from one end to the other of the plurality of nozzle holes of the jetting tank  312 , in the direction intersecting the direction the photosensitive material  40  is moved) is 5.5 cm, and the length for application (the length of the second alkaline processing solution applied as the photosensitive material is moved beneath the nozzle) is 12 cm. 
     Further, immediately after the second alkaline processing solution is applied, the second solution including hydrogen peroxide is layered by the jetting tank  312 B, onto the second alkaline processing solution on the emulsion surface  40 A of the photosensitive material  40 . The conditions for application at this time are as follows: the quantity of the second solution including hydrogen peroxide applied is 20 cc/m 2 , the pitch P between the nozzle holes is ({square root over (3+L )})·D/2 or less=150 μm, the width of the nozzle is 5.5 cm, and the length for application is 12 cm. 
     The photosensitive material  40  is then subjected to the developing processing for 18 seconds, during which the photosensitive material  40  is conveyed on the conveying path  14 , which is on the heat panel. The heat panel is means for adjusting heating temperature of the development-intensification processing section  20 , and adjusts the temperature to approximately 40° C. Next, the photosensitive material  40  is conveyed to the stabilizing section  25 . 
     At the stabilizing section  25 , the second stabilizing solution adjusted to a solution temperature of between 35 to 45° C. is deposited onto the emulsion surface  40 A of the photosensitive material  40  to carry out stabilizing processing. The second stabilizing solution is deposited with the roller bead  90 . Thereafter, the photosensitive material  40  is conveyed to the drying section  26 . 
     At the drying section  26 , the emulsion surface  40 A of the photosensitive material  40  wetted with the post-processing solution is dried during the 10 seconds that the photosensitive material  40  is conveyed on the conveying path  14 , in an atmosphere adjusted to a temperature of between 60 to 100° C. The photosensitive material  40  is then conveyed from the outlet  16  onto the tray as a finished product on which the image has been formed. As a result, a series of controlling operations for the image forming processing is completed. 
     The processing in each of the above-described operation processes is performed only for the emulsion surface  40 A which is one side of the photosensitive material  40 . Accordingly, compared with the case in which both the emulsion surface  40 A of the photosensitive material  40  and the surface opposite to the emulsion surface  40 A are wetted in the same manner, such as in a conventional so-called dipping method or the like, the amount of the processing solutions and the post-processing solutions to be applied can be reduced and the deterioration of the processing solutions and the post-processing solutions as a whole can be decreased. Further, compared with the case in which the entirety of the two surfaces of the photosensitive material  40  are dried in the same manner, the time for drying can be shortened and thus the time for processing can be shortened considerably, because the emulsion surface  40 A side of the photosensitive material  40  is primarily required to be dried. 
     Plural series of routes, in which the previously described processing operations such as exposing, developing, drying and the like are performed, may be provided in the image forming apparatus. 
     In the present fifth embodiment, by carrying out post-processing in which the acidic second stabilizing solution is applied, residual silver on the emulsion surface  40 A of the photosensitive material  40  forms a complex compound, thus effecting stabilization. Simultaneously, citric acid in the second stabilizing solution neutralizes the alkaline component which is applied on the emulsion surface  40 A by applying the second alkaline processing solution thereon, in a prior step. As a result, the preservation properties of an image formed on the photosensitive material  40  are ensured. 
     Accordingly, one of the processing steps, i.e., cleaning off the alkaline components of the photosensitive material  40 , may be omitted from among all of the processing steps for forming an image with the image forming apparatus. Thus, the structure of the image forming apparatus can be simplified correspondingly to the omission of one of the processing steps and the image forming apparatus can be manufactured at reduced cost. 
     Next, a sixth embodiment of the image forming apparatus of the present invention will be explained, with reference to FIG.  15 . 
     In the development-intensification processing section  20  of the image forming apparatus according to the present sixth embodiment, the second alkaline processing solution and the second solution including hydrogen peroxide described in the second example of the first embodiment, are each applied onto the photosensitive material with separate processing solution applying means. The image forming apparatus of the present sixth embodiment does not include a cleaning section. 
     In the image forming apparatus shown in FIG.  15 . three processing solution applying means total are comprised between the development-intensification processing section  20 , which is disposed inside the apparatus body  10 , and the stabilizing section  25 . The stabilizing section  25  serves as the means for post-processing, which is a step for ensuring preservation properties of an image formed on the photosensitive material  40 . The development-intensification processing section  20  may comprise two processing solution applying means, i.e., the applying devices  310 , which are disposed side by side, each of which is non-contacting type applying means similar to that illustrated in the previously described FIGS. 3-7. The processing solution applying means of the stabilizing section  25  is structured by disposing an applying device  310 , which is non-contacting type applying means similar to that illustrated in the previously described FIGS. 3 to  7 , at a position separated a predetermined distance from the two applying devices  310  serving as processing solution applying means of the development-intensification processing section  20 . 
     The jetting tank  312 A of the applying device  310  is disposed at a position furthest upstream the conveying path  14 , among the jetting tank  312 A, the jetting tank  312 B, and a jetting tank  312 C of the three applying devices  310 , respectively. The jetting tank  312 A applies the second alkaline processing solution only on the emulsion surface  40 A, which is one side of the photosensitive material  40 . 
     The jetting tank  312 B of the applying device  310  is disposed at a position further upstream the conveying path  14  than the jetting tank  312 C, and applies the second solution including hydrogen peroxide on the emulsion surface  40 A immediately after the second alkaline processing solution has been applied thereon. Accordingly, on the emulsion surface  40 A of the photosensitive material  40 , the applied second solution including hydrogen peroxide is mixed with the second alkaline processing solution which has been applied thereon. 
     The jetting tank  312 C of the applying device  310  applies the second stabilizing solution, which is a post-processing solution described above, on the emulsion surface  40 A a predetermined amount of time after the second solution including hydrogen peroxide has been applied thereon. 
     Due to this structure, on the emulsion surface  40 A of the photosensitive material  40 , the second alkaline processing solution is applied, and immediately thereafter, the second solution including hydrogen peroxide is applied thereon to mix therewith. Next, after a predetermined amount of time elapses, the second stabilizing solution is applied. 
     Each of the jetting tanks  312 A,  312 B,  312 C of the applying devices  310  jets the respective processing solution from the nozzle holes  324  thereof (shown in FIG. 4) which do not touch the emulsion surface  40 A of the photosensitive material  40 . This can prevent the second solution including hydrogen peroxide and the second stabilizing solution, from deteriorating. The cause of such deterioration is that the chemical substance on the emulsion surface  40 A flows in reverse into the nozzle holes  324  and mixes in the second solution including hydrogen peroxide stored in the jetting tank  312 B of the applying device  310  or with the second stabilizing solution stored in the jetting tank  312 C and then chemical changes and the like are caused. 
     Therefore, the second solution including hydrogen peroxide and the second stabilizing solution as a post-processing solution, which are stored in the jetting tank  312 B and the jetting tank  312 C of the applying device  310 , respectively, so as not to deteriorate, can be used up without wasting. 
     On the emulsion surface  40 A of the photosensitive material  40 , the second alkaline processing solution and the second solution including hydrogen peroxide are separately deposited in a short time so as to be layered on each other by the jetting tanks  312 A and  312 B of the two applying devices  310  in the above-described manner. The photosensitive material  40  is then conveyed along the heat-control section  354  which is at a position along the conveying path  14  that is downstream with respect to the jetting tanks  312 A and  312 B of the applying devices  310  on the conveying path  14 . During the conveyance, chemical changes are caused and the development-intensification processing is performed. 
     As shown in FIG. 15, the stabilizing section  25 , which serves as the means for post-processing which is a step for ensuring preservation properties of the image formed on the photographic material  40 , is disposed at a vicinity of a furthest-downstream position with respect to the heat-control section  354 . The stabilizing section  25  effects stabilizing processing by applying the second stabilizing solution as the post-processing solution from the jetting tank  312 C of the applying device  310 , onto the emulsion surface  40 A of the photosensitive material  40  on the conveying path  14 . 
     Rollers  100  are disposed at an adjacent position further downstream than the jetting tank  312 C on the conveying path  14 . The rollers  100  rotate on the photosensitive material  40  while nipping the photosensitive material  40  therebetween so as to squeeze off the post-processing solution. 
     Further, a drying section may be included at the portion extending from the rollers  100  to the outlet  16 . 
     In the image forming apparatus of the sixth embodiment, the structure and effects other than those described above are the same as those of the previously described second embodiment. Accordingly, the same members are given the same reference numerals, and detailed descriptions thereof are omitted. 
     Further, the photosensitive material  40  and each of the processing solutions and post-processing solutions in the image forming apparatus of the present sixth embodiment are equivalent to those described in the second example of the first embodiment. 
     Next, a description will be provided of operation and method of use of the image forming apparatus relating to the sixth embodiment structured as described above, with reference to FIG.  15 . 
     First, image signals of an original document are input by using the scanner of the like, and are subjected to the image processing, so as to prepare the exposing section  18  for operation. 
     Subsequently, when a command for forming the image of the original document on the photosensitive material  40  is input to the controlling section (not shown) of the apparatus body  10 , the paper feeding section  12  is operated by the command of the controlling section, and the band-shaped photosensitive material  40  is fed onto the conveying path  14 . The photosensitive material  40 , which has been fed a predetermined length onto the conveying path in this matter, is cut into a predetermined size by the cutter  38 , and is then conveyed to the exposing section  18 . 
     At the exposing section  18 , the emulsion surface  40 A, which is one side of the photosensitive material  40 , is exposed in accordance with an image processed-data to form a latent image which corresponds to the image on the original document. The photosensitive material  40  is then conveyed to the development-intensification processing section  20 . At the development-intensification processing section  20 , the second alkaline processing solution (alkaline activator solution) at a predetermined temperature (approximately of from 35 to 45° C.) is applied onto the emulsion surface  40 A of the photosensitive material  40 . The second alkaline solution is applied with the jetting tank  312 A of the applying device  310  serving as the processing solution applying means. 
     The conditions for application at this time are as follows: the quantity of the second alkaline processing solution applied is 20 cc/m 2 , the pitch P between the nozzle holes is ({square root over (3+L )})·D/2 or less =150 μm, the width of the nozzle (the width from one end to the other of the plurality of nozzle holes of the jetting tank  312 , in the direction intersecting the direction the photosensitive material  40  is moved) is 5.5 cm, and the length for application (the length of the second alkaline processing solution applied as the photosensitive material is moved beneath the nozzle) is 12 cm. 
     Further, immediately after the second alkaline processing solution is applied, the second solution including hydrogen peroxide is layered by the jetting tank  312 B, onto the second alkaline processing solution on the emulsion surface  40 A of the photosensitive material  40 . The conditions for application at this time are as follows: the quantity of the second solution including hydrogen peroxide applied is 20 cc/m 2 , the pitch P between the nozzle holes is ({square root over (3+L )})·D/2 or less=150 μm, the width of the nozzle is 5.5 cm, and the length for application is 12 cm. 
     The photosensitive material  40  is then subjected to the developing processing for 18 seconds, during which the photosensitive material  40  is conveyed on the conveying path  14 , which is on the heat panel. The heat panel is means for adjusting heating temperature of the development-intensification processing section  20 , and adjusts the temperature to approximately 40° C. 
     The stabilizing section  25  is disposed towards the furthest downstream portion of the development-intensification processing section  20 . At the stabilizing section  25 , the second stabilizing solution adjusted to a solution temperature of between 35 to 45° C. is deposited by the jetting tank  312 C onto the emulsion surface  40 A of the photosensitive material  40  to carry out stabilizing processing. The post-processing solution is then squeezed off by nipping the photosensitive material  40  between the rollers  100 . Thereafter, the photosensitive material is conveyed on the conveying path so as to be conveyed from the outlet  16  onto the tray as a finished product on which the image has been formed. As a result, a series of controlling operations for the image forming processing is completed. 
     The processing in each of the above-described operation processes is performed only for the emulsion surface  40 A which is one side of the photosensitive material  40 . Accordingly, compared with the case in which both the emulsion surface  40 A of the photosensitive material  40  and the surface opposite to the emulsion surface  40 A are wetted in the same manner, such as in a conventional so-called dipping method or the like, the amount of the processing solutions and the post-processing solutions to be applied can be reduced and the deterioration of the processing solutions and the post-processing solutions as a whole can be decreased. Further, compared with the case in which the entirety of the two surfaces of the photosensitive material  40  are dried in the same manner, the time for drying can be shortened and thus the time for processing can be shortened considerably, because the emulsion surface  40 A side of the photosensitive material  40  is primarily required to be dried. 
     Plural series of routes, in which the previously described processing operations such as exposing, developing, drying and the like are performed, may be provided in the image forming apparatus. 
     In the present sixth embodiment, by carrying out post-processing in which the acidic second stabilizing solution is applied, residual silver on the emulsion surface  40 A of the photosensitive material  40  forms a complex compound, thus effecting stabilization. Simultaneously, citric acid in the second stabilizing solution neutralizes the alkaline component which is applied on the emulsion surface  40 A by applying the second alkaline processing solution thereon, in a prior step. As a result, the preservation properties of an image formed on the photosensitive material  40  are ensured. 
     Accordingly, one of the processing steps, i.e., cleaning off the alkaline components of the photosensitive material  40 , may be omitted from among all of the processing steps for forming an image with the image forming apparatus. Thus, the structure of the image forming apparatus can be simplified correspondingly to the omission of one of the processing steps, and the image forming apparatus can be manufactured at reduced cost. 
     Further, the second alkaline processing solution, the second solution including hydrogen peroxide and the second stabilizing solution applied onto the emulsion surface  40 A of the photosensitive material by the jetting tanks  312 A,  312 B, and  312 C, respectively, of the applying devices  310  are each of a small amount. Accordingly, the photosensitive material  40  to which processing solutions have been applied dries out while it is conveyed on the conveying path  14 , even if a drying section is not provided. Thus, the processing time can be significantly reduced, and the structure of the image forming apparatus can be simplified correspondingly with reducing the steps of the image forming apparatus. The image forming apparatus can thereby be manufactured at less cost. 
     Further, the processing solution and the post-processing solution can be stably stored so as not to deteriorate with time. Accordingly, the present invention may be favorably applied to a case in which image forming processing is effected intermittently between long rest periods. 
     In each of the above-described embodiments, image forming processing of each type can be effected suitably and speedily by the processing solution applying means of the image forming apparatus, even if a silver halide photographic photosensitive material has a photographic structuring layer on both surfaces of the support thereof. 
     In the case of using a silver halide photographic photosensitive material having a photographic structuring layer on both surfaces of the support thereof, images can be formed on both sides of the photosensitive material  40  by using the respective image forming apparatus of the embodiments and effecting the image forming processings twice. 
     In this way, an image forming apparatus of each embodiment can be used for a single-sided silver halide photographic photosensitive material, as well as for a two-sided silver halide photographic photosensitive material. Accordingly, usage applications of the image forming apparatus are expanded, and the merits of using the image forming apparatus can be increased. 
     In the above case, an image forming apparatus of the present invention may comprises two (post-) processing solution applying means, separately from each other or in an integral structure connected together so as to effect image forming processing on both sides simultaneously 
     In this case, in which the image forming processings for the obverse and reverse surface are effected at the same time, each of the processings for the photosensitive material  40  can be effected suitably and speedily, using the processing solutions and the post-processing solutions efficiently, even when so-called dipping means is used as the processing solution applying means. This is because excess processing solution or post-processing solution is not applied to a reverse surface of the photosensitive material at which a photographic structuring layer is not provided, as in the case of dipping a material provided with a photographic structuring layer on only one surface of the photosensitive material  40 . 
     Accordingly, in the case in which image forming processings are effected at the same time for the obverse and reverse surfaces, a structure is used in which so-called dipping means is included among the (post-) processing solution applying means. 
     Further, in the present specification, “post-processing” indicates a step for ensuring preservation properties of a formed image. The term “post-processing” includes, for example: “rinsing” in which residue on photosensitive material is removed after fixing processing (rinsing off silver components on the photosensitive material using a hypo or the like); and processing for applying a second stabilizing solution for ensuring preservation properties of an image formed on a photosensitive material (so-called stop processing), in which an acid is used to neutralize alkaline components applied in a prior step, while effecting stabilization in which residual silver on the photosensitive material forms a complex compound.