Stencil printing machine

A stencil printing machine is formed of a perforating section for perforating a stencil sheet produced by bonding a resin film to a substrate with an adhesive; a printing drum on the outer peripheral surface of which the stencil sheet perforated at the perforating section is wrapped with the resin film inside, and, after removal of a substrate from the stencil sheet thus wrapped, printing is done by passing ink supplied to an inner peripheral surface, through the perforated portion of the resin film remaining on the outer peripheral surface; an pressing member for pressing printing paper against the printing drum during printing; a separating device for separating and discharging the substrate from the stencil sheet wrapped around the printing drum, prior to starting printing; and a resin film removing section for removing the resin film of the stencil sheet from the printing drum after completion of printing.

BACKGROUND OF THE INVENTION 
The present invention relates to a stencil printing machine. 
There has been known such a stencil sheet as is produced by bonding a resin 
film and a multi-porous substrate made of a multi-porous sheet with an 
adhesive. 
This stencil sheet is prepared by perforating the film section by the use 
of a heat source such as a thermal head, and then is wrapped around a 
printing drum with the multi-porous substrate inside. Then, printing is 
done by passing ink through the stencil sheet to a printing paper. 
In this type of printing using the above-described stencil printing 
machine, however, the multi-porous substrate itself has low perviousness 
to ink, resulting in ununiform ink transfer to a printing paper, that is, 
in an ununiformly printed image. This is because the multi-porous 
substrate produced of a multi-porous sheet has uneven density and 
thickness. 
To make ink ununiformly transferred to paper look as if uniform, it is 
necessary to spread ink from the portion where ink has passed into the 
printing area of the paper, to the portion where no ink has been 
transferred. Thus spreading ink, however, will result in the presence of 
an excessive amount of ink within the printed area on the printing paper 
where ink passes through, and accordingly in ink offset and 
strike-through. 
As a means for improving the ununiform ink condition on paper, there is 
used only a resin-film stencil for printing, that is, without using the 
multi-porous sheet substrate. In this case, the stencil sheet can not be 
conveyed in the machine, and is wrinkled in stencil preparation or when 
wrapped around the printing drum, and accordingly printed matter faithful 
to an original master copy is unobtainable. Such a technology has been 
disclosed in Japanese Patent Laid-Open No. Hei 5-220919. 
The stencil sheet produced by bonding a conventional resin film and a 
porous substrate such as a porous sheet with an adhesive is generally of 
the order of 30 to 50 .mu.m in thickness. 
Therefore, for discharging the stencil sheet of this thickness by means of 
the stencil discharge section provided within the stencil printing 
machine, space as this thickness is needed. In this case, however, a 
limited quantity of discharged stencils is around 20 to 100, albeit it 
depends on the discharge system and capacity, and the discharge section is 
not capable of accommodating a large quantity of spent stencils. 
Furthermore, the substrate such as the multi-porous sheet of the stencil 
sheet to be discharged to the stencil discharge section contains a large 
amount of ink; that is, ink is used wastefully. 
By the way, the prior art technique for printing by the use of only a 
perforated resin-film stencil has been disclosed in Japanese Patents 
Laid-Open No. Hei 5-309932 and No. Hei 5-318900. According to the 
technique of Japanese Patent Laid-Open No. Hei 5-309932, a resin film and 
a substrate that have been separated are stripped off at the stencil 
discharge apparatus and received in a common receiving box. Therefore, the 
quantity of stencil paper discharged makes no difference from that of the 
stencil sheet made by bonding the prior art resin film and a multi-porous 
substrate of a multi-porous sheet with an adhesive. 
According to the technique disclosed in Japanese Patent Laid-Open No. Hei 
5-318900, the separated porous substrate is held inside the machine and 
accordingly the a space large enough to hold the porous substrate within 
the machine is required. 
For printing by the use of a prior art stencil sheet made by bonding a 
resin film and a multi-porous substrate such as a multi-porous sheet with 
an adhesive, the stencil sheet is wrapped around the printing drum. At 
this time, if a perforated resin film which is on the outer side of the 
stencil sheet is impressed, ink passes through the perforated portion of 
the resin film, smearing the pressed member. Therefore, the stencil sheet, 
when wrapped around the printing drum, can not be impressed, and 
accordingly it is necessary to wrap the stencil sheet around the printing 
drum by using an impressing member with the printing paper inserted 
between the printing drum and the impressing member. 
Furthermore, for fully impregnating a stencil sheet with ink from a 
multi-porous substrate such as a multi-porous sheet to a perforated resin 
film, a considerable pressure and/or impression time are required, 
resulting in excessive ink transfer to the printing paper used in wrapping 
the stencil sheet around the printing drum. 
When printing is continuously performed immediately after the wrapping of 
the stencil sheet around the printing drum, the printing paper used in 
wrapping the stencil sheet is discharged onto a discharge tray, on which 
succeeding paper is stacked continuously. Since a large amount of ink 
remains on the paper used in wrapping, ink will transfer to the back side 
of the paper discharged thereon. The paper used in wrapping is a printed 
matter not faithful to the original master copy because of presence of 
such a defect as excessive strike-through. That is, the printing paper is 
used wastefully. 
Furthermore, when the stencil sheet is wrapped around the printing drum 
with a decreased pressure and/or impression time required for wrapping 
around the printing drum, the first one to three printing sheets are not 
fully impregnated with ink, resulting in a failure in producing a printed 
matter faithful to an original master copy. 
SUMMARY OF THE INVENTION 
It is an object of the present invention to provide a stencil printing 
machine which is capable of smoothly conveying the stencil sheet, 
obtaining quality images, and remarkably increasing the discharged stencil 
sheet receiving capacity in a specific volume. 
The stencil printing machine according to the first aspect of the present 
invention has a stencil perforating section for perforating a stencil 
sheet made by bonding a resin film and a substrate with an adhesive; a 
printing drum for printing by passing ink supplied to the inner peripheral 
surface, through the perforated section of the resin film remaining in the 
outer peripheral surface after the stencil sheet prepared at the stencil 
perforating section is wrapped around the outer peripheral surface of the 
printing drum with the resin film inside and then the substrate is removed 
from the stencil sheet that has been wrapped; a pressing member for 
pressing printing paper, against the printing drum; a separating means for 
separating and discharging the substrate from the stencil sheet wrapped 
around the printing drum, before starting printing; and a stencil 
discharge section for removing the resin film of the stencil sheet from 
the printing drum after completion of printing. 
In the stencil printing machine according to the second aspect of the 
present invention, the separating means in the stencil printing machine of 
the first aspect has also a function to separate inked paper from the 
printing drum. 
In the stencil printing machine according to the third aspect of the 
present invention, the substrate of the stencil sheet used in the stencil 
printing machine of the first aspect has a cut made along a direction 
intersecting with the direction of rotation of the printing drum and a 
plurality of holes formed at a specific spacing along the direction of 
rotation of the printing drum. The separating means stated above is a 
rotatable roller provided with a plurality of engaging members which 
engage with the holes of the substrate; the engaging member of the roller 
is engaged with the holes of the substrate of the stencil sheet wrapped 
around the outer peripheral surface of the printing drum, thereby rotating 
the roller to cur off the substrate at the cut from the resin film. 
The stencil sheet according to the fourth aspect of the present invention 
is produced by separably bonding the resin film with an adhesive to an 
ink-receptive sheet as the substrate, said ink-receptive sheet being 
capable of being printed with said ink. 
In the stencil sheet according to the fifth aspect of the present invention 
the adhesive stated above in the stencil sheet of the fourth aspect is a 
thermoplastic resin adhesive which is dissolved or swollen with a 
component in the printing ink. 
The stencil sheet is wrapped around the printing drum with the perforated 
resin film inside and with the ink-receptive sheet outside. When wrapping 
the stencil sheet, a pressure is applied by the pressing member from the 
ink-receptive side, and thereafter the ink-receptive sheet of the stencil 
sheet is separated by the substrate separating part. 
To this ink-receptive sheet thus separated, ink is transferred through the 
perforated portion of the resin film to print an image, thus making a test 
printing. It is, therefore, unnecessary to use a printing paper P for the 
purpose of test printing at the time of wrapping the stencil sheet on the 
printing drum. That is, an printed image has been formed on the 
ink-receptive sheet discharged out of the stencil printing machine, from 
which the fidelity of the perforated stencil sheet to the original master 
copy can be ascertained. 
After the separation of the ink-receptive sheet, only the perforated resin 
film remains on the printing drum and is used for actual printing. 
Therefore, since there is used no multi-porous substrate that formerly gave 
an adverse effect to printing, it is possible to obtain a printed matter 
which is faithful to the original copy. 
After completion of printing, the stencil discharge section for removing 
the resin film from the printing section is required to receive only a 
very thin resin film, and consequently the discharge stencil sheet 
receiving capacity in a specific volume can be remarkably improved. 
The above and other objects, aspects and advantages will become apparent to 
those skilled in the art by the preferred embodiment consistent with the 
principle of the invention, which will be discussed and illustrated in 
connection with the accompanying drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
Hereinafter an embodiment of a stencil printing machine according to the 
present invention and a stencil sheet to be used in the same machine are 
explained. 
FIG. 1 is a schematic view of the stencil printing machine of the present 
invention. 
The stencil printing machine is provided with an original image reading 
section 5 including an image scanner 3, for reading an image of an 
original master copy to be printed; and a stencil perforating section 9 
having a stencil perforating device 7 for duplicating an image by 
perforating a stencil sheet S in accordance with an original image data 
read by the original image reading section 5. 
The stencil perforating device 7 adopts a perforating system using a 
thermal head or other to prepare the stencil sheet S. The shape of 
perforation is preferably independent by each dot, but each dot is 
unnecessarily fully independent. The stencil sheet is demanded to have a 
good printing resistance to withstand a tearing force during printing and 
can be smoothly conveyed to a stencil discharge section 27 described 
later. 
It should be noticed that the stencil sheet S perforated to a normal image 
by a stencil perforating section 9 is sufficient. Also it should be noted 
that, in the present invention, the stencil sheet S rolled as illustrated 
is fed out successively and cut to a specific length after being 
perforated by the perforating device, but the stencil sheet S may be fed 
in a form of sheets which will be used one by one by each stencil 
preparation. 
The stencil sheet S, after preparation, must be stably conveyed to a 
printing section 10. Since a perforated resin film S2 is integral with the 
ink-receptive sheet which is a substrate of the stencil sheet, the stencil 
sheet will never be wrinkled at the time of stencil perforation and 
wrapping around a printing drum 11. 
The resin film S2 thus perforated by the stencil perforating section 9 is 
mounted, integrally with the ink-receptive sheet S1, around the outer 
peripheral surface of the printing drum 11 in the printing section 10. At 
this time, the stencil sheet S is wrapped with the resin film S2 on the 
printing drum 11 side. This wrapping is done by rotating the printing drum 
11 in the direction of the arrow in the drawing with the leading edge of 
the stencil sheet S securely clamped with a clamper 11a. 
The stencil sheet S, when wrapped, is simultaneously pressed against the 
printing drum 11 side by means of an impressing member 13, thus completing 
the installation of the stencil sheet on the printing drum 11. Thereafter 
the ink-receptive sheet S1 is separated from the resin film by the 
substrate separating section, and discharged out of the machine. For this 
substrate separating section, an existing separating pawl 21 is usable as 
the printing paper separating section as shown in FIG. 2. In the present 
embodiment, the ink-receptive sheet S1 is discharged out of the machine by 
this separating pawl, not by a special support separating section. 
The printing drum 11 after the separation of the ink-receptive sheet Sl 
carries only the resin film S2 and is ready for printing on the printing 
paper P immediately by the use of the impressing member 13. At this time, 
no multi-porous substrate which will give an adverse effect to printing is 
in use, and the resin film S2 alone is present on the printing drum 11. It 
is, therefore, possible to obtain a printed matter faithful to the 
original master copy. 
The printing paper P is fed out from the paper feed table 15. After being 
fed out one by one by means of the paper feed roller 17, the paper is fed 
in at a specific timing by the paper feed timing roller 19 between the 
printing drum 11 and the impressing member 13. 
With the rotation of the printing drum 11, printing is done on the printing 
paper P, correspondingly to the image perforated on the stencil sheet S, 
with the pressure of the impressing member 13. 
The printing paper P is separated from the printing drum 11 by means of a 
separating pawl 21 as a printing paper separating section, and conveyed by 
a belt conveyor system of a delivery apparatus 23 to be discharged out to 
a paper receiving tray 25. 
In the case of a roll-type stencil sheet S, the ink-receptive sheet S1 
should be designed to be easily separable; for example, there should be 
provided a separating portion in other than a perforable area, so that the 
ink-receptive sheet S1 can easily be separated thereat. 
Furthermore, after the completion of printing, the resin film S2 of the 
stencil sheet S wrapped around the printing drum 11 is stripped from the 
printing drum 11 by means of the stencil discharge section 27 having the 
discharge pawl, discharge roller, etc. for discharging the stencil sheet S 
to be discharged into a stencil discharge box. 
Since the ink-receptive sheet S1 is used as a substrate, a molten component 
resulting from the perforation of the resin film S2 at the perforating 
section 9 permeates to the interior of the ink-receptive sheet S1. 
Therefore, the stencil sheet S having a low adhesive power increases in 
the adhesive power at the perforated portion more than at the unperforated 
portion. 
However, in the portion increased in the adhesive power by perforation, ink 
is permeated into the interior of the ink-receptive sheet S1 by the 
pressure of the impressing member 13, dissolving and/or swelling the 
molten component resulting from perforation, and therefore the adhesive 
power in the perforated portion decreases to facilitate the separation of 
the perforated resin film S2 from the ink-receptive sheet S1. 
Forming a separating section 35 in a fixed position from the edge of the 
ink-receptive sheet S1 of the stencil sheet S is effective. This 
separating section 35 facilitates the separation of the ink-receptive 
sheet S1 from the resin film S2. As a method for providing this separating 
section 35, perforations are formed. The length of the perforations nearly 
agrees with the width of the clamper 11a as shown in FIG. 2. Also, the 
separating section 35 may have been fully cut. Furthermore, the 
ink-receptive sheet S1 may be a sheet similarly designed for easy 
separation. 
The condition of a printed image on the paper evaluated by using an image 
analyzer on a whole solid-printed portion is shown in the table of FIG. 6. 
As an example of comparison is used a conventional stencil sheet S produced 
by attaching the resin film S2 to the multi-porous sheet S1. Figures of 
high values used in the table indicate printed matter faithful to the 
original master copy; that is, figures of low values indicate printed 
matter of low fidelity to the original master copy. 
In FIG. 1, a stencil discharge section 27 is disposed on the opposite side 
of the stencil perforating section 9; on the printing drum 11 only the 
perforated resin film S1 is present, and therefore only the extremely thin 
resin film S1 is received in the stencil discharge section. 
Also shown in FIG. 6 is the quantity of discharged stencil papers received 
in the stencil discharge section 27, the holding capacity of which is 2.0 
liters and is evaluated by a compression-type stencil discharge apparatus. 
As an example of comparison is used a conventional stencil sheet S produced 
by attaching the resin film S2 to the multi-porous sheet S1. Figures of 
high values used in the table indicate a large discharge stencil holding 
capacity, while figures of low values indicate a small discharge stencil 
holding capacity. 
By the way, in the present invention is used the ink-receptive sheet S1 as 
a substrate of the stencil sheet S. If an ink-unreceptive sheet is used, 
ink on the sheet that has been discharged out of the stencil printing 
machine will not permeate into the sheet but will remain on the sheet 
surface. 
if the operator holds the discharged ink-unreceptive sheet by hand, his 
hands will be smeared with ink. The ink-receptive sheet is not limited and 
may be any type of sheet pervious to printing ink such as a quality 
printing paper or a synthetic resin sheet, cloth, and unwoven cloth which 
has been so processed as to be ink-receptive. 
Furthermore, if a colored ink-receptive sheet is used, it can be realized 
from the printing paper P when discharged out of the machine, and also is 
usable as a tape sorter in order to sort the types of printing papers that 
have been stacked. 
For the resin film S2 of the stencil sheet S of the present invention, a 
thermoplastic resin film perforated by a heat source like a thermal head, 
is used, for example, polyethylene, polypropylene, polyvinyl chloride, 
polyvinylidene chloride, polyester, polystyrene, polyurethane, 
polycarbonate, acrylic resin, silicone resin, etc., of which particularly 
the poly-vinylidene chloride and polyester are desirable for use. 
It is also possible to use a resin film which is perforable by dissolving 
by an ink jet system other than the heat source such as the thermal head. 
For the adhesive for bonding the resin film S2 of the stencil sheet S of 
the present invention to the substrate for supporting the resin film S1, a 
thermoplastic adhesive is used. 
For example, polyethylene, polypropylene, polyvinyl chloride, 
polyvinylidene chloride, polyester, polystyrene, polyurethane, 
polycarbonate, acrylic resin, and silicone resin are usable. Of these, a 
material which is dissolved and/or swollen by a component of the printing 
ink used in the stencil printing machine must be selected. 
When the ink-receptive sheet is separated by using an adhesive material, 
which is not dissolved and/or swollen with the component of ink, for 
bonding the resin film to the ink-receptive sheet, the adhesive power 
required for bonding the resin film of the stencil sheet S of the present 
invention to the substrate supporting the resin film must be so weak as to 
allow easy separation of the resin film from the substrate supporting the 
resin film. 
Next, FIG. 3 shows another example of the stencil sheet of the present 
invention. 
The stencil sheet S, as illustrated, is a continuous body having a 
plurality of perforations 30 at a specific spacing at both ends. And the 
ink-receptive sheet S1 is provided with perforations 31 at a specific 
spacing. 
The printable area of the resin film S1 is to be a range L not extending to 
the perforations 30. 
The stencil sheet S is received in a rolled state in the stencil 
perforating section 9, and is sent out to the printing drum 11 side while 
being perforated similarly to the above-described embodiment. 
The stencil sheet S is discharged by the stencil printing machine partly 
shown in FIG. 4. 
In the lower part of the printing drum 11 is provided a feed roller 32 near 
the separating pawl 21. This feed roller 32 has engaging pawls 32a which 
engage with the perforations 30 as shown in the enlarged view of FIG. 5. 
The engaging pawls 32a are arranged at the same spacing as the pitch of 
the perforations 30. 
Therefore, the stencil sheet S after perforation is secured at the leading 
edge with the clamper 11a, and wrapped as far as the position shown in the 
drawing around the printing drum 11 with the rotation of the printing drum 
11. Then, with the rotating drum 11 rotating, the feed roller 32 is turned 
in the direction of the arrow in the drawing, thereby separating the 
ink-receptive sheet S1 at the perforations 31 from the printing drum 11 
and the resin film S2. Thus the stencil sheet S can easily be sent out and 
discharged. 
According to the stencil printing machine of the present invention, the 
perforated resin film, which is integral with the ink-receptive sheet 
which is a substrate, can be conveyed with stability without wrinkling at 
the time of perforation and wrapping around the printing drum. 
The ink-receptive sheet which is a substrate of the stencil sheet is 
separated from the resin film by means of the substrate separating section 
and discharged out of the stencil printing machine. Therefore, in the 
stencil discharge section for holding the resin film of the stencil sheet 
removed after printing from the printing section, only the resin film is 
discharged, thereby enabling to remarkably increase the capacity for 
holding discharged stencil papers in a specific volume. 
Furthermore, as only the perforated resin film is wrapped around the 
printing drum and printed, printed matter faithful to the original copy 
are obtainable. 
Furthermore, according to the stencil printing machine, since the 
constitution of an existing printing paper separating section is usable 
for separation and discharge of the printing paper, the substrate can be 
discharged out of the machine, thus enabling the simplification of the 
machine itself. 
Furthermore, according to the stencil sheet of the present invention, the 
ink-receptive sheet which is a substrate is used and discharged out of the 
stencil printing machine, and therefore the fidelity of the perforated 
stencil sheet to the original copy can be ascertained. Consequently, no 
printing paper will be wasted by test printing. 
Furthermore, according to the stencil sheet, since the ink-receptive sheet 
is used as the substrate, a component dissolved at the time of perforation 
of the resin film permeates into the interior of the ink-receptive sheet; 
however, because the component thus permeating is dissolved and/or swollen 
with a component in the ink, the perforated film can easily be separated 
from the ink-receptive sheet, thus enabling the provision of a highly 
reliable printing machine.