Patent Publication Number: US-8532524-B2

Title: Image formation device having first frame for supporting image formation unit and second frame of lower flexure rigidity

Description:
CROSS-REFERENCE TO RELATED APPLICATION 
     This application claims priority under 35 U.S.C. §119 from Japanese Patent Application No. 2010-102164 filed on Apr. 27, 2010. The entire subject matter of the application is incorporated herein by reference. 
     BACKGROUND 
     1. Technical Field 
     Aspects of the present invention relate to an image formation device having a frame which is composed of a plurality of members having different deflection rigidities. 
     2. Related Art 
     There has been known an image formation device of which a frame is composed of metal members and resin members. Typically, an electric substrate supplying electric power to an image formation unit is secured to a pair of frames, the frames being arranged to sandwich (straddle) the image formation unit. 
     SUMMARY 
     If the frame is composed of the metal members and the resin members, flexural deformation of the electric substrate may be relatively large. The metal member and the resin member generally have different flexural rigidities. Therefore, even if the same force is applied to the metal member and the resin member, the resin member may deform largely. Therefore, if the electric substrate is arranged to sandwich (straddle) a metal member and a resin member and fixed thereto, due to difference of the flexural deformation of the resin member and the metal member, flexural deformation of the electric substrate may be caused. 
     Aspects of the invention is advantageous in that, the flexural deformation of an electric substrate is suppressed when the electric substrate is arranged to straddle a plurality of member having different flexural rigidities and fixed thereto. 
     According to aspects of the invention, there is provided an image formation device, which is provided with an image formation unit configured to form an image on a recording sheet, a first frame arranged to support the image formation unit, a second frame connected to the first frame, flexure rigidity of the second frame being smaller than flexure rigidity of the first frame, an electric substrate electrically connected with the image formation unit. The electric substrate is arranged to extend from the first frame to the second frame and is secured onto the first frame. 
     According to aspects of the invention, there is also provided an image formation device, which is provided with an image formation unit including a photoconductive drum bearing developer, a charger configured to charge the photoconductive drum, a main frame arranged to support the image formation unit, the image formation unit being secured to the main frame, an electric substrate secured to the pair of main frame, the electric substrate providing electric power to the charger, a light emitter and a light receiver provided on the electric substrate, the light emitter emitting a light beam to a predetermined portion of the image formation unit, the light receiver receiving light beam emitted from the image formation unit, and an optical element provided on the electric substrate and arranged on an optical axis of one of the light emitter and the light receiver. 
    
    
     
       BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS 
         FIG. 1  schematically shows a cross sectional view of an image formation device according to an embodiment of the invention. 
         FIG. 2  is a perspective view showing removal/insertion of a drawer unit of the image formation device shown in  FIG. 1 . 
         FIG. 3  is a perspective view of a main frame of the image formation device shown in  FIG. 1  with an electric substrate being attached. 
         FIG. 4  is a perspective view of the main frame of the image formation device shown in  FIG. 1  with an electric substrate being detached. 
         FIG. 5  is an enlarged perspective view of a holding hook according to the embodiment of the invention. 
         FIG. 6  is a front view of the main frame with the electric substrate being attached according to the embodiment of the invention. 
         FIG. 7  is a cross sectional view of the main frame taken along line A′-A′ in  FIG. 6 , according to the embodiment of the invention. 
         FIG. 8  is an enlarged cross sectional view of the right-hand side main frame shown in  FIG. 7 . 
         FIG. 9A  is an enlarged view of a circled portion B in  FIG. 6 . 
         FIG. 9B  is a cross sectional view of the circled portion B taken along line A′-A′ in  FIG. 9A . 
         FIG. 10  shows a plan view of the light emitting unit, light receiving unit and lens as assembled. 
     
    
    
     DETAILED DESCRIPTION 
     Hereinafter, an exemplary embodiment according to aspects of the present invention will be described with reference to the accompany drawings. 
     In a housing  3  of an image formation device  1 , an image formation unit  5 , which forms images on sheets such as printing sheets, OHP sheets and the like (hereinafter, referred to as recording sheets or sheets) in accordance with an electrophotographic imaging method, is accommodated. The image formation unit  5  includes a process unit  7 , an exposure unit  9 , a fixing unit and the like. 
     The image formation device  1  according to the embodiment is a so-called tandem type device, which has a plurality of process units  7  which are arranged in a sheet feed direction T. According to the embodiment, four process units  7  are employed. Specifically, the four process units  7  includes a process unit  7 K accommodating black developer, a process unit  7 Y accommodating yellow developer, a process unit  7 M accommodating magenta developer, and a process unit  7 C accommodating cyan developer. 
     The four process units  7  have substantially the same structure and only the colors of the developer are different. Each process unit  7  (i.e., each of the process units  7 K,  7 Y,  7 M and  7 C) includes a photoconductive drum  7 A and a charger  7 B that charges a circumferential surface of the photoconductive drum  7 A. 
     The charged circumferential surface of the photoconductive drum  7 A is exposed to light emitted by the exposure unit  9  to form an electrostatic latent image on the circumferential surface of the photoconductive drum  7 . Then, by supplying charged developer to the photoconductive drum  7 A, the developer is selectively adhered on the circumferential surface of the photoconductive drum  7 A (an image is developed). 
     At a position facing the photoconductive drum  7 A, a transfer roller  15  is provided with the transfer belt  13 A being located therebetween. The transfer roller  15  is used for transferring the developer (i.e., developed image) on the circumferential surface of the photoconductive drum  7 A to the recording sheet. To the transfer roller  15 , a predetermined voltage, necessary for transferring the developer from the photoconductive drum  7 A to the recording sheet, is applied. 
     According to the embodiment, the plurality of photoconductive drums  7 A are arranged along the sheet feed direction T with their axes being aligned perpendicular to the sheet feed direction T. The plurality of photoconductive drums  7 A are secured to a drawer casing  21 A. The developed images carried by the plurality of photoconductive drums  7 A are transferred on the recording sheet with being overlapped as the recording sheet is fed by the transfer belt  13 A. 
     After the developed images carried by the photoconductive drums  7 A have been transferred, the recording sheet is further fed to the fixing unit  11 , at which the developed image is heated and fused, and fixed onto the recording sheet. Thereafter, the recording sheet is fed upward along the sheet feed path, discharged from the housing  3  and stacked on a sheet discharge tray  3 A defined on an upper surface of the housing  3 . 
     The transfer belt  13 A is an endless belt which is wound around a driving roller  13 B and a driven roller  13 C. As the driving roller  13 B rotates, the transfer belt  13 A moves and the driven roller  13 C is driven by the transfer belt  13 A to rotate. The transfer belt  13 A, the driving roller  13 B, the driven roller  13 C and a frame supporting the above constitute a belt unit  13 . 
     Below the belt unit  13 , a sheet feed tray  17  is provided. The recording sheets to be fed toward the image formation unit  5  (or transfer belt  13 A) are stacked on the sheet feed tray  17 . The sheets stacked on the sheet feed tray  17  are fed one by one toward the image formation unit by a feeder mechanism  19 . The sheet feed tray  17  is movable, in the direction parallel with a surface of a first electric substrate  29  (i.e., front-and-rear direction R in the embodiment). The sheet feed tray  17  is detachably attached to the main body. 
     According to the embodiment, the process units  7 K,  7 Y,  7 M and  7 C are assembled in a drawer casing  21 A, thereby defined is a drawer unit  21 . The drawer unit  21  is also movable in a direction parallel with the surface of the first electric substrate  29  (in the embodiment, the front-and-rear direction R) and is detachably inserted in the main body. With this configuration, the four process units  7 K,  7 Y,  7 M and  7 C can be inserted into/removed from the main body, integrally. 
     In this specification, the main body means a pair of main frames  23  and the like, which will not be disassembled or removed in normal use. Incidentally, the frames  23  are plate-like members and arranged on both sides, in the width direction, with the image formation unit  5  (i.e., a drawer unit  21 ) being located therebetween. The width direction means a direction which is perpendicular to the sheet feed direction T and thickness direction. According to the embodiment, the width direction is equal to the right-and-left direction of the image formation device  1 . The plate plane of the first electric substrate  29  is a virtual plane of the first electric substrate  29 , which coincides with a vertical surface according to the embodiment. It should be noted that the main body may be a single frame (not a pair of frames) and the image formation unit may be supported by the single frame. 
     Incidentally, according to the embodiment, an accommodating unit accommodating developer and a cartridge unit  7 E provided with a pair of developing rollers that applies the developer to the photoconductive drum  7 A is removably attached to the process unit  7  (or the drawer casing  21 A). Therefore, simply by exchanging the cartridge units  7 E, the developer can be supplied. 
     Each of the main frames  23  has a first frame  25  made of iron alloy such as SPCC and a second frame  27  made of resin such as ABS resin. The second frame  27  is arranged below the first frame  25 , and they are mechanically fastened at a plurality of positions (three, in the embodiment) with, for example, screws. 
     According to the embodiment, the Young&#39;s modulus E of the material of the second frame  27  is smaller than that of the first frame  25 . Therefore, the flexure rigidity of the second frame  27  is smaller than that of the first frame  25 , and a cross-sectional second order moment I of the second frame  27  is greater than a predetermined value so that the flexure rigidity (E·I) of the second frame  27  does not become excessively small. 
     The predetermined value (the cross-sectional second order moment I of the second frame  27 ) should be designed appropriately based on load acting on the second frame  27 , necessary rigidity and the like. An optimum value thereof should be determined based on try and error. Incidentally, the Young&#39;s modulus of the ABS resin is 1.5 GPa-7.1 GPa, and that of SPCC is 203 GPa. 
     The right-side and left-side second frames  27  are formed with recessed portions  27 A, respectively. The recessed portions  27 A are formed such that a space defined between the pair of main frames  23 , that is, the space accommodating the image formation unit  5  (i.e., the drawer unit  21 ) is narrowed by the recessed portions  27 A. The cross-sectional shape of each second frame  27  in the width direction is approximately U-shaped. 
     The main frames  23  (the right-side and left-side main frames  23 ) are connected with each other, as shown in  FIG. 3 , with beam-like bridge frames  23 A and a top plate  23 B to form a so-called Rahmen structure frame. It should be noted that the bridge frames  23 A and the top plate  23 B are made of metal (e.g., SPCC) and the top plate  23 B also serves as a support plate which supports the exposure unit  9 . 
     On the right-side main frame  23 , the first electric substrate  29  is secured. The first electric substrate  29  is a plate-like substrate supplying electricity to the image formation unit  5  (i.e., the photoconductive drums  7 A, chargers  7 B and transfer rollers  15 , etc.). On the left-side main frame  23 , a second electric substrate which supplies electricity to an electric motor (not shown) is secured (see  FIG. 3 ). 
     In the following description, unless specified, the “main frame  23 ” means the right-side main frame  23  and the electric substrate  29  means the first electric substrate  29  secured to the right-side main frame. 
     The electric substrate  29  is secured to the first frame  25 , with its position being adjusted with respect to the first frame  25 , on the side opposite to the accommodating space  22 , such that the electric substrate  29  extends over the first frame  25  and the second frame  27 . A relatively large electric component  29 C attached to the electric substrate  29  is arranged on the second frame  27  side (i.e., the main frame  23  side) as shown in  FIG. 7 . 
     The main frame  23  (in particular, the first frame  25 ) has a plate-like shape and arranged to be substantially parallel with the vertical direction as shown in  FIG. 2 . The first electric substrate  29  and the second electric substrate  35  are arranged such that their planar surfaces are parallel with the main frames  23  (the first frames  25 ) as shown in  FIG. 7 . 
     The first frame  25  is provided with positioning protrusions  25 A (see  FIG. 4 ) which protrude from the first frame  25  toward the electric substrate  29  and are used for adjusting the position of the electric substrate  29  with respect to the first frame, and holding hooks  25 D which hold the electric substrate  29  so as to prevent the electric substrate  29 , of which position is adjusted with the positioning protrusions  25 A, from displacing in the width direction (see  FIGS. 5 and 6 ). 
     The positioning protrusions  25 A include an origin positioning protrusion  25 B, and a rotation regulating protrusion  25 C. The positioning protrusions  25 A are aligned in an insertion/removal direction of the drawer unit  21  (i.e., in the front-and-rear direction R of the image formation device  1  in the embodiment) with spaced by a predetermined interval (see  FIG. 6 ). 
     The origin positioning protrusion  25 B is used for adjusting an origin, or a reference position defined on the electric substrate  29  (which is a hole  29 A of the electric substrate  29  in which the origin positioning protrusion  25 B is to be inserted) with a frame securing origin point (which is a point where the origin positioning protrusion  25 B is provided) defined on the first frame  25 . 
     The rotation regulating protrusion  25 C is inserted in a hole  29 B formed on the electric substrate  29  and regulates rotation of the electric substrate  29  about the frame securing origin point (i.e., the origin positioning protrusion  25 B in the embodiment). 
     The origin positioning protrusion  25 B and the rotation regulating protrusion  25 C are made of resin (PC/ABS resin according to the embodiment) and fixed to the first frame  25 . Each of the origin positioning protrusion  25 B and the rotation regulating protrusion  25 C has a crisscross cross-section taken along a plane perpendicular to protruding direction thereof. 
     The hole  29 A in which the origin positioning protrusion  25 B is inserted is formed to have a perfect-circular cross section, while the hole  29 B in which the rotation regulating protrusion  25 C is inserted is formed to have an oval cross section of which a longer diameter extends in a direction connecting the hole  29 A and the hole  29 B. 
     The positioning protrusions  25 A and the holes  29 A and  29 B are arranged (designed) such that the origin positioning protrusion  25 B and the rotation regulating protrusion  25 C slightly deform when they are inserted in the holes  29 A and  29 B, respectively, in order to prevent play of the electric substrate  29  with respect to the first frame  25 . 
     On the electric substrate  29  side, substrate electrodes  31 A- 31 D (which will also be referred to collectively as substrate side electrodes  31 ) which protrude from a wall surface of the main frame  23  towards the accommodating space  22  (i.e., image formation unit  5 ) as shown in  FIG. 7 . The substrate side electrodes  31  contact image formation device side electrodes  33 A- 33 D (which will also be referred to collectively as device side electrodes  33 ) as shown in  FIG. 8 . 
     According to the embodiment, the electric substrate  29  and the image formation unit  5  are electrically connected each other via the substrate side electrodes  31  and the device side electrodes  33 , electric power is supplied to the image formation unit  5 . At least one of the plurality of (six, in the embodiment) substrate side electrodes  31  is located between the origin positioning protrusion  25 B and the rotation regulating protrusion  25 C, as shown in  FIG. 6 . 
     Incidentally, the substrate side electrodes  31  include a spring  31 F which is a coil spring, a ring-shaped contact  31 E which is secured to a longitudinal end side of the spring  31 F and contacts the device side electrodes  33 , and a terminal  31 G which is provided to the electric substrate  29  and contacts the other longitudinal end of the spring  31 F. The spring  31 F and the contact  31 E are integrated. 
     Incidentally, according to the embodiment, the spring  31 F is held by the first frame  25  via a resin member secured to the first frame  25 . The resin member holding the spring  31 F and the resin member to which the positioning protrusion  25 A are integrated (see  FIG. 4 ). 
     The device side electrodes  33  are held by a frame of the drawer casing  21  and the belt unit  13 , and the device side electrodes  33 A- 33 D are provided on supply electric power to the process unit  7  etc. 
     According to the embodiment, by elastically deforming the spring  31 F to compress, a contacting pressure between the contact  31 E and the device side electrode  33 , and a contacting pressure between the terminal  31 G and the spring  31 F are increased so that an electric connection between the electric substrate  29  and the image formation device  5  is ensured. 
     With the above configuration, when the electric substrate  29  is installed on the main frame  23 , the electric substrate  29  always receives a force which separates the electric substrate  29  from the main frame  23  (hereinafter, this force will be referred to as a separating force), in the embodiment, holding hooks  25 D and  27 B (see  FIG. 6 ) are provided to countervail the separating force. 
     The holding hooks  25 D are received at a plurality of portions (two, in the embodiment) along a line extending in a direction parallel to a direction where the plurality of positioning protrusions  25 A ( 25 B and  25 C) are arranged with a predetermined interval therebetween. The holding hooks  25 D are, as shown in  FIG. 5 , engaging protrusions which fit in the engaging holes  29 D formed on the electric substrate  29 . 
     The holding hooks  25 D are beam-like protrusions which protrude from the first frame  25  toward the electric substrate  29  (toward right side, in the embodiment), and configured to be elastically deformable at least in the up-and-down direction. A tip (right end in the embodiment) of each protrusion is formed with a hook-like engaging portion  25 E which engages with the engaging hole  29 D. Incidentally, the holding hooks  25 D are integrally formed on the resin which is formed with the positioning protrusion  25 A. 
     The engaging portion  25 E is formed with a taper surface  25 F so that the cross section taken along a plane perpendicular to the protruding direction is smaller on the tip side. Therefore, when the electric substrate  29  is secured onto the first frame  25  (main frame  23 ), the taper surface  25 F and an edge of the engaging hole  29 D contact each other, and the holding hook  25 D elastically deforms. 
     When the edge of the engaging hole  29  passes over the taper surface  25 F and reaches an elementary part (proximal end) of the holding hook  25 D, the engaging hole  29 D and the engaging portion  25 E engage with each other, and the electric substrate  29  is held, against the separating force. 
     Incidentally, the holding hook  25 D is configured such that the electric substrate  29  is allowed to deform in a direction opposite to the positioning direction or a direction of the separating force, but that deformation of the electric substrate  29  in a upward direction is basically prohibited. 
     The holding hook  27 B is an engaging protrusion to fit in engaging hole  29 E as shown in  FIG. 9A . The holding hook  27 B is a beam-like member which protrudes from the second frame  27  toward the electric substrate  29 , and is at least elastically deformable in the positioning direction. 
     At the tip of the holding hook  27 B, similarly to the holding hook  25 D, a hook-shaped engaging portion  27 C which engages with an edge of an engaging hole  29 E is formed. Therefore, similarly to the holding hook  25 D, the edge of the engaging hole  29 E and the engaging portion  27 C engage and the electric substrate  29  is held against the separating force. Incidentally, according to the embodiment, the holding hook  27 B is integrally formed on the second frame  27 . 
     A size H 1 , in the up-and-down direction, of the engaging hole  29 E is, as shown in  FIG. 9A , greater than a size H 2 , in the up-and-down direction, of the holding hook  27 B. Therefore, the holding hook  27 B allows the electric substrate  29  to move in the up-and-down direction or a direction opposite to the direction of the separating force, but basically restricts a displacement of the electric substrate  29  in the positioning direction. The holding hook  27 B is configured to have a rectangular shape such that the size H 2  thereof in the up-and-down direction is greater than a horizontal size H 3 , that is, the size in a direction perpendicular to the protruding direction of the holding hook  27 B. 
     In order to detect the amount of the developer accommodated in a cartridge  7 E of the process unit  7 , a light emitter  37 A configured to emit light beam toward a predetermined portion defined on the image formation unit  5 , and a light receiver  37 B which receives the light emitted by the light emitter  37 A and passed through the image formation unit  5  are provided. 
     Specifically, a plurality of light emitters  37 A are arranged along the sheet feed direction T to face the cartridges  7 E, respectively, and emit light beams, in the width direction, toward the respective cartridges  7 E. Similarly, a plurality of light receivers  37 B are provided to receive the light beams emitted by the light emitters  37 A and passed through the cartridges  7 E, respectively. 
     If a sufficient amount of developer is contained in the cartridge  7 E, the light beams emitted by the light emitters  37 A are shielded by the developer and the light receivers  37 B do not receive the light beams. If the developer contained in the cartridge  7 E is reduced, the light receivers  37 B receive the light beams. Therefore, based on the light beams received by the light receivers  37 B, the remaining amount of the developer can be judged. 
     On an optical axis of the light emitter  37 A, a lens  37 C is arranged. Similarly, on an optical axis of the light receiver  27 B, a lens  37 C is arranged. The lenses  37 C are respectively fixed to the electric substrate  29  and  35 . 
     At a portion of the electric substrate corresponding to the photoconductive drums  7 A, a plurality of light emitters  37 D (see  FIG. 7 ) for discharging the circumferential surfaces of the photoconductive drums  7 A are arranged. The plurality of light emitters  37 D are arranged along the sheet feed direction T and face the respective photoconductive drums  7 A. 
     According to the embodiment, the electric substrate  29  is arranged in the main frame  23  such that it extends over the first frame  25  and the second frame  27 . Specifically, the electric substrate  29  is positioned with respect to the first frame  25  and secured thereto. Since the first frame  25  has higher flexure rigidity than the second frame  27 , even if the second frame  27  is deformed by a relatively large amount, effect of the deformation of the second frame  27  on the first frame  25  can be well suppressed, and the flexure deformation of the electric substrate  29  can be suppressed 
     According to the embodiment, the second frame  27  is made of resin, and arranged below the first frame  27 . With this structure, if the image formation device  1  is placed on a distorted plane and the flexure deformation of the second frame  27  occurs to absorb the distortion, relatively large flexure deformation of the electric substrate  29  can be suppressed. 
     On one of the second frame  27  and the electric substrate  29  (the second frame  27  in the embodiment), the holding hook  27 B that engages with the engaging hole  29 E formed on the other of the second frame  27  and the electric substrate  29  (the electric substrate  29  in the embodiment) is provided. Further, the size H 1  of the engaging hole  29  in the up-and-down direction is greater than the size H 2  of the holding hook  27 B in the up-and-down direction. 
     Therefore, according to the embodiment, the second frame side portion of the electric substrate  29  is prevented from exhibiting a play to move toward/away from the second frame  27 . Further, relative displacement of the second frame  27  with respect to the electric substrate  29  in the up-and-down direction due to the flexure deformation of the second frame  27  can be absorbed. 
     Further, according to the embodiment, the size H 2  of the holding hook  27 B in the up-and-down direction is greater than the size H 3  of the holding hook  27 B in the horizontal direction (i.e., a direction perpendicular to its protruding direction). With this configuration, the holding hook  27 B and the engaging hole  29 E engage within a relatively large range in the up-and-down direction. Therefore, the holding hook  27 B can move in the up-and-down direction relative to the engaging hole  29 E, while relative displacement of the second frame  27  with respect to the electric substrate  29  due to the flexure deformation of the second frame  27  can be absorbed, and the electric substrate  29  can be held. 
     On at least one of the electric substrate  29  and the image formation unit  5  (the electric substrate  29  in the embodiment), the substrate side electrode  31  that protrudes toward and contacts the image formation side electrode  33  provided to the other of the electric substrate  29  and the image formation unit  5  (the image formation unit  5  in the embodiment) is provided. Thus, the electric substrate  29  and the image formation unit  5  are electrically connected via the electrodes  31  and  33 . Therefore, the electric substrate  29  and the image formation unit  5  should be positioned accurately. 
     According to the embodiment, since the position of the electric substrate  29  is adjusted with respect to the first frame  25 , which has high flexure rigidity, and secured thereto, it is possible that the electric substrate  29  and the image formation unit  5  are accurately positioned. 
     Further, according to the embodiment, the electric substrate  29  is formed with the light emitters  37 A emitting light beams toward predetermined portions defined on the image formation unit  5 , and the light receivers  27 B receiving the light beams passed through the image formation unit  5 . Since the electric substrate  29  and the image formation unit  5  can be positioned accurately, the above-described feature functions appropriately. 
     Further, according to the embodiment, the positioning protrusions  25 A include the origin positioning protrusion  25 B for adjusting the origin of the electric substrate  29  to the frame side origin of the first frame  25 , and the rotation regulating protrusion  25 C for regulating the rotation of the electric substrate  29  about the frame side origin. 
     On at least one of the electric substrate  29  and the image formation unit  5  (the electric substrate  29  in the embodiment), the substrate side electrode  31  that protrudes toward and contacts the image formation side electrode  33  provided to the other of the electric substrate  29  and the image formation unit  5  (the image formation unit  5  in the embodiment) is provided. Further, the substrate side electrode  31  is located between the origin positioning protrusion  25 B and the rotation regulating protrusion  25 C. 
     With the above structure, the positional accuracy in assembling components is the highest between the origin positioning protrusion  25 B and the rotation regulating protrusion  25 C. According to the embodiment, the substrate side electrode  31  is located in the area where the accuracy is the highest, it is ensured that the electrode  31  and  33  contact each other. 
     According to the embodiment, the recessed portion  27 A is formed on the second frame  27 . The recessed portion  27 A is recessed in the direction opposite to the accommodating space  22  in which the image formation unit  5  is provided, with respect to the second frame  27 . Further, the electric substrate  29  is arranged on the side opposite to the accommodating space  22  with the second frame  27  therebetween, and the electrical component  29 C is provided on the second frame side of the electric substrate  29 . 
     With the above structure, by designing the electric component  29 C to fit in the recessed portion  27 A, the recessed portion can by effectively used and downsizing of the image formation device  1  can be achieved. 
     According to the embodiment, the sheet feed tray  17  and the drawer unit  21  (or drawer casing  21 A) are installed in the main body as units movable in a horizontal direction (i.e., in the direction parallel with a plane of the electric substrate  29 ). Therefore, if the electric substrate  29  is attached to the main frame such that it extends over the first frame  25  and the second frame  27 , the electric substrate  29  does not obstacle the movement of the sheet feed tray  17  or the drawer unit  21 . 
     Thus, freedom in designing the image formation device  1  can be obtained without losing the operability in moving the sheet feed tray  17  or the drawer unit  21 . 
     In the above-described embodiment, the first frame  25  is made of iron-type metal, and the second frame  27  is made of ABS resin. However, the invention needs not be limited to such a configuration. It should be noted that various modifications of the embodiment can be made without departing from the scope of the invention. 
     For example, in the exemplary embodiment, the first frame  25  is arranged above the second frame  27 . This structure can be changed such that the first frame  25  is arranged below the second frame  27 , or the first frame  25  and the second frame  27  are arranged at different positions on the same horizontal plane. 
     In the exemplary embodiment, the holding hooks  25 D and  27 B are provided to the main frame  23  (the first frame  25  and the second frame  27 ), and the engaging holes  29 D and  29 E are formed on the electric substrate  29 . However, the invention needs not be limited to such a configuration, and the engaging holes  29 D and  29 E may be formed on the main frame  23  and the holding hooks  25 D and  27 B may be provided to the electric substrate  29 . 
     In the exemplary embodiment, the size H 2  in the up-and-down direction of the holding hook  27 B is greater than the size H 3  in the horizontal direction. However, the invention needs not be limited to this configuration, and can be modified such that, for example, the size H 2  is equal to or less than the size H 3 . 
     In the exemplary embodiment, the size H 1 , in the up-and-down direction, of the engaging hole  29 E is greater than the size H 2 , in the up-and-down direction, of the holding hook  27 B. The invention needs not be limited to this configuration, and can be modified such that, for example, the size H 1  is equal to or less than the size H 2 . 
     In the exemplary embodiment, the positioning protrusions  25 A are to fit in the holes  29 A and  29 B formed on the electric substrate  29 . Such a configuration can be modified such that the holes  29 A and  29 B are formed on the first frame  25  and the protrusion  25 A is provided to the electric substrate  29 . 
     According to the embodiment, the image formation device is of the direct type which directly transfers the developer on the recording sheet fed on the transfer belt  13 A. The invention needs not be limited to this configuration, and can be modified. For example, the image formation device may be of the indirect type which once transfer the developer onto the transfer belt, and then transfer the developer on the transfer belt onto the recording sheet. The image formation device may be an inkjet printer.