Stencil printing machine

A stencil printing machine includes a printing drum having a flexible ink-permeable circumferential wall adapted to receive a perforated stencil sheet around an outer circumferential surface thereof, the printing drum being driven to rotate around a central axis thereof; a pressing device situated inside the printing drum for supplying ink to an inner surface of the circumferential wall, the pressing device being movable between a pressing position for pressing the circumferential wall to be deformed radially outwardly and a standing position for releasing the circumferential wall from deformation; an opposing drum disposed adjacent to the printing drum and driven to rotate in a direction opposite to that of the printing drum, the opposing drum having a recess formed in an outer circumferential surface thereof; a clamp disposed on an outer circumferential surface of the opposing drum and operating in synchronization with rotation of the opposing drum to hold a leading edge of a printing sheet supplied between the printing drum and the opposing drum; a clamp cover disposed on the outer circumferential surface of the opposing drum adjacent to the clamp relative to the direction of rotation of the opposing drum and covering the recess formed in the opposing drum for allowing operation of the clamp, the clamp cover selectively opening and closing the recess in synchronization with operation of the clamp; and a driving mechanism for driving the clamp cover to move alternately in a circumferential direction of the opposing drum and in a radial direction of the opposing drum.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to a stencil printing machine, especially to 
a machine having a mechanism for preventing ink-leakage from a printing 
drum. 
2. Description of the Related Art 
In Japanese Patent Application 63-28553 (Japanese Laid Open Publication No. 
1-204781), Japanese Patent Application 1-47029 (Japanese Laid Open 
Publication No. 2-225078), and Japanese Patent Application 2-223550 
(Japanese Laid Open Publication No. 4-105984), the present applicant 
proposed a stencil printing machine. This stencil printing machine has a 
printing drum, an ink-applying roller situated inside the printing drum, 
and a back-pressing roller (an opposing drum) disposed under the printing 
drum. The printing drum has a base body comprising two annular members 
coaxially arranged at a predetermined distance therebetween and a 
connecting member connecting the two annular members. A flexible and 
ink-permeable circumferential wall is wrapped around the base body. 
Namely, one end of the circumferential wall is fixed to the base body, and 
the other end is attached to the base body by an elastic member. The 
ink-applying roller is situated inside the printing drum for providing ink 
to an inner surface of the circumferential wall. The ink-applying roller 
is movable between a pressing position for pressing the circumferential 
wall to be deformed radially outwardly and a standing position for 
releasing the circumferential wall from deformation. The back-pressing 
roller is situated under the printing drum and arranged parallel with the 
printing drum. The back-pressing roller is driven to rotate in a direction 
opposite to that of the printing drum. In the constitution explained 
above, a perforated stencil sheet is wrapped around an outer 
circumferential surface of the circumferential wall of the printing drum, 
and then stencil printing is started. A printing sheet is supplied between 
the printing drum and the back-pressing roller. The ink-applying roller 
deforms the printing drum outwardly. The printing sheet is conveyed while 
being sandwiched between the printing drum and the back-pressing roller, 
thereby being printed. 
Further, in Japanese Patent Application No. 3-162218 (Japanese Laid Open 
Publication No. 4-361043), the present applicant proposed a stencil 
printing method using the stencil printing machine of the constitution 
stated above. In this method, the back-pressing roller has a clamp for 
holding a leading end of the printing sheet. The printing sheet held by 
the clamp on the back-pressing roller is peeled off from the printing drum 
just after printing, so that a distinct and uniform printed image without 
faintness can be obtained and set-off does not occur. 
Further, in Japanese Patent Application No. 5-306033 (Japanese Laid Open 
Publication No. 7-137419), the present applicant proposed a stencil 
printing machine in which a longitudinal position, i.e. head and tail 
position, of a printed image on a printing sheet can be adjusted by 
adjusting a rotational position of a printing drum relative to a 
back-pressing roller. 
Further, in the case where a clamp is disposed on the back-pressing roller 
for holding a leading end of the printing sheet, the back-pressing roller 
must have a recess formed therein for avoiding interference with a rear 
edge of the clamp, so that the clamp can open and close. However, when the 
clamp of the back-pressing roller meets the printing drum, ink may leak 
from between the printing drum and a stencil sheet, and transfer into the 
recess formed adjacent to the rear edge of the clamp. And, in Japanese 
Patent Application No. 7-214075 (Japanese Laid Open Publication No. 
9-39359), the present applicant proposed that a strip of an elastic sheet 
be attached to an outer circumferential surface of the back-pressing 
roller parallel to a generating line for covering the clamp to prevent 
such a trouble. 
FIG. 18 is a schematic view illustrating a publicly known basic 
constitution of a stencil printing machine. This machine comprises the 
printing drum, the ink-applying roller, the back-pressing roller, each of 
them are explained above, and the clamp disposed on the back-pressing 
roller for holding the leading end of the printing sheet. In this drawing, 
the reference numeral "10" indicates the printing drum, and "14" indicates 
the back-pressing roller. The printing drum 10 has a frame. The frame is 
composed of a pair of annular members 16, 16 and a connecting member 18 
connecting the pair of annular members. The annular members are arranged 
at both end portions of an axis of the printing drum. The connecting 
member is parallel to the axis of the printing drum. A flexible porous 
sheet 20 is in a developed form of rectangular, and the sheet is wound 
around the frame. Namely, a front edge 20a and a rear edge 20b are 
attached to the connecting member in such a manner that both side edges of 
the sheet contact outer circumferential surfaces of the annular members. 
Especially as concerns attachment of the rear edge 20b to the connecting 
member 18, Japanese Patent Application 1-47029 (Japanese Laid Open 
Publication No. 2-225078), Japanese Patent Application 5-306028 (Japanese 
Laid Open Publication No. 7-137415), and Japanese Patent Application 
5-306029 (Japanese Laid Open Publication No. 7-137416) should be referred 
to. 
A circumferential wall of the printing drum 10 is composed of the flexible 
porous sheet 20, and a stencil sheet 19 is wrapped around an outer surface 
of the wall with its leading end held on the connecting member 18 by a 
clamp 21. 
The front edge 20a and the rear edge 20b of the flexible porous sheet 20 
are of non-porous structure. A middle portion 20c between the edges is of 
porous structure allowing ink to pass through. The non-porous edges 20a 
and 20b of the flexible porous sheet 20 and the connecting member 18 
constitute a stencil-sheet leading-end attachment portion 10a. The portion 
is a non-porous strip-shaped area elongated along a generating line of the 
printing drum 10 between both side edges of the drum. 
On the back-pressing roller 14, a traverse groove 22 is formed parallel to 
its center axis along a generating line. The printing drum 10 and the 
back-pressing roller 14 have the same diameter. The drum and the roller 
are driven to rotate in directions opposite to each other in such a manner 
that the stencil-sheet leading-end attachment portion 10a and the traverse 
groove 22 of the back-pressing roller periodically meet in synchronization 
with each other. As shown in FIG. 18, the rotating direction of the 
printing drum 10 is anti-clockwise, and the rotating direction of the 
back-pressing roller 14 is clockwise. 
An ink supplying roller 12 is situated inside the printing drum 10. The ink 
supplying roller 12 is driven to rotate by an axis 13 with its outer 
circumferential surface contacted with an inner circumferential surface of 
the printing drum 10. A cam 24 is attached to the annular member 16 in the 
vicinity of the connecting member 18. An annular cam-follower 23 provided 
on the axis 13 engages with the cam 24. Thus, when the ink supplying 
roller 12 passes the connecting member 18 during the drum rotation, the 
roller 12 is lifted up from the inner circumferential surface of the 
printing drum 10 so that collisional contact of the roller with the 
connecting member can be avoided. 
On the back-pressing roller 14, a clamp 25 is attached to a rear portion of 
the traverse groove 22 relative to the rotating direction of the 
back-pressing roller. The clamp 25 holds a leading end of a printing sheet 
on the back-pressing roller 14. The printing sheet is attached to the 
back-pressing roller 14 with its leading end held by the. clamp 25. The 
printing sheet is inserted between the back-pressing roller 14 and the 
printing drum 10 during the clockwise rotation of the back-pressing roller 
14 as shown in the drawing. Ink is provided to the inside of the flexible 
porous sheet 20 by the ink supplying roller 12, and passes through holes 
formed in the ink supplying roller 12, thereby transferring to the 
printing sheet through perforations of the stencil sheet 19 to form an 
image thereon. 
In Japanese Patent Application 5-306033 (Japanese Laid Open Publication No. 
7-137419), there disclosed such a stencil printing machine that 
incorporates a head-and-tail adjusting device for adjusting a position of 
an printed image on a printing sheet. In such stencil printing machine, 
when a rotational phase of the printing drum 10 relative to the 
back-pressing roller 14 is in a standard condition, a border line 26 
dividing the porous structure 20c and the non-porous front edge 20a of the 
flexible porous sheet corresponds to a line 28 on the outer 
circumferential surface of the back-pressing roller 14. Similarly, a 
borderline 32 dividing the porous structure 20c and the rear edge 20b of 
the flexible porous sheet corresponds to a line 34 on the outer 
circumferential surface of the back-pressing roller 14. When a rotational 
phase of the printing drum 10 relative to the back-pressing roller 14 is 
changed for head and tail adjustment, the lines 28 and 34 move in the 
directions shown by arrows 38 and 40, respectively, and the porous 
structure 20c may meet the clamp 25. 
As illustrated in FIG. 19, rather large recess 27 is formed in the rear 
side of the clamp 25, so that the clamp 25 can lean in pivotally moving 
around an axis 62. Then, suppose that the porous structure 20c of the 
flexible porous sheet meets the clamp 25, as stated above. Ink is pressed 
by the ink supplying roller 12 against a part of an inner surface of the 
porous structure 20c corresponding to the recess 27. Ink is squeezed out 
into the inside of the stencil sheet 19 through holes of the porous 
structure 20c, but the ink is not fully supported by the stencil sheet on 
the outside. Accordingly, as illustrated in FIG. 19, a part of the stencil 
sheet 19 corresponding to the recess 27 swells locally. Once ink is 
squeezed out in this way, since it has high viscosity, all of the squeezed 
ink cannot return to the inside of the porous structure 20c even after 
releasing of the ink-pressing force. Thus, if such phenomenon is repeated 
during rotation of the printing drum, ink flows across the porous 
structure 20c from the inside to the outside of the printing drum, thereby 
accumulating between the outer circumferential surface of the printing 
drum and the stencil sheet. And, it is clear from FIG. 19 that such 
ink-leakage due to shortage of back-pressing at the recess 27 similarly 
occurs in a stencil printing machine having a rigid porous structure. 
Accumulation of the ink leads to ink-leakage at both axial end portions of 
the printing drum. Further accumulation of the ink may force the swelled 
stencil sheet to be strongly pressed against the clamp 25 or a corner of 
the recess 27, thereby causing damage to the sheet. 
An invention shown in FIG. 20 has been proposed by the present applicant in 
Japanese Patent Application 7-214075 (Japanese Laid Open Publication No. 
9-39359) in order to settle such problem. The drawing shows a strip-shaped 
elastic sheet 52 situated on the outer circumferential surface of the 
back-pressing roller 14 along a generating line for covering the clamp 25. 
The problem is settled to some extent by the strip-shaped elastic sheet 52. 
However, since the elastic sheet 52 easily bend, if the machine operates 
for a long time while the porous structure 20c of the flexible porous 
sheet repeatedly contacts the clamp 25, ink-leakage due to deformation of 
the elastic sheet 52 may occur through the ink-leakage process explained 
in referring to FIG. 19. 
Then, the present applicant improved the stencil printing machine and 
proposed a new one as shown in FIGS. 10 to 17 in Japanese Patent 
Application 9-183113 to further reliably prevent the ink-leakage by the 
leakage process explained above. 
As illustrated in FIG. 10 and FIG. 16, the back-pressing roller 14 is 
driven to rotate around an axis 68. The axis 68 is attached to a 
predetermined position of a non-illustrated frame. The back-pressing 
roller 14 is driven to rotate around the axis 68. 
Plural clamps 25 are disposed on the back-pressing roller 14. The 
back-pressing roller 14 has the axis 62. The plural clamps 25 are fixed to 
the axis 62 at a predetermined distance therebetween. One end of the arm 
101 is fixed to one end portion of the axis 62. A driven member 102 is 
attached to the other end of the arm 101. A cam 100 is adjacent to one end 
of the back-pressing roller 14 and fixed to the not-shown frame of the 
back-pressing roller 14. The arm 101, the driven member 102, and the cam 
100 are arranged on the distant end side in the perspective view of FIG. 
16. 
The driven member 102 engages with the cam 100. The cam 100 is fixed to the 
frame. The driven member 102 follows the cam 100 while rotating with the 
back-pressing roller 14. The outer shape of the cam 100 enables the clamp 
25 to open or close at appropriate timing in synchronization with rotation 
of the back-pressing roller 14. 
An arm 70 in the shape of L is rotatably connected to the axis 68 at an 
elbow-portion thereof. One end of the arm 70 is connected to a link 84. 
The link 84 is connected to one end of the axis 62 via a link 64. The 
other end of the axis 62 is connected to the arm 101. A clamp cover 66 is 
rotatably connected to the other end of the arm 70 via a connecting axis 
74. The clamp cover 66 is a member that covers gaps between the clamps 25 
arranged at intervals and the recess 27 formed in the back-pressing roller 
14 at a rear end side of the clamps 25. As illustrated in FIG. 16, a 
bracket 80 is fixed to an end surface of the back-pressing roller 14. A 
link 78 is rotatably connected to the bracket 80 via a pin 82. A pin 76 is 
fixed to an end portion of the clamp cover 66. The pin 76 is rotatably 
connected to the link 78 while passing through a groove 103 formed in the 
other end of the arm 70. 
Operation in the constitution explained above will be explained. The 
back-pressing roller 14 is driven to rotate. The cam 100 remains static 
since it is fixed to the frame side. The driven member 102 connected to 
the back-pressing member 14 follows the shape of the cam 100 while 
rotating around the axis 68. The movement of the driven member 102 causes 
the axis 62 to rotate, thereby opening or closing the clamp 25. The 
rotation of the axis 62 causes arm 70 to rotate, and the clamp cover 66 
connected to the arm 70 moves while being regulated by the link 78. 
In a predetermined timing at which a printing sheet is supplied between the 
back-pressing roller 14 and the printing drum, the driven member 102 
starts to contact and follow the cam 100, as illustrated in FIG. 11. The 
axis 62 rotates, thereby causing the clamp 25 to open. Simultaneously with 
this movement, the clamp cover 66 is slightly lifted up while moving 
backward from an initial position adjacent to the clamp 25. 
As illustrated in FIG. 12, the driven member 102 continuously follows the 
cam 100 while further being lifted up as the clamp 25 opens more broader. 
The clamp cover 66 slightly descends while moving further backward from 
the clamp 25. 
As illustrated in FIG. 13, the driven member 102 reaches the topmost 
position of the cam 100. The clamp 25 opens broadest. The clamp cover 66 
descends still further. 
As illustrated in FIG. 14, when the driven member 102 reaches a recess 
portion of the cam 100, the axis 62 begins to rotate in the other 
direction wherein the clamp 25 closes. Simultaneously with this movement, 
the clamp cover 66 switches from descending to ascending. 
As illustrated in FIG. 15, when the driven member 102 follows the recess 
portion of the cam 100, the clamp 25 further closes and the clamp cover 66 
moves back to the clamp 25 while ascending. And, the clamp 25 and the 
clamp cover 66 return to the initial position as shown in FIG. 10. 
In the above-explained operation of the stencil printing machine proposed 
in Japanese Patent Application 9-183113, a front end of the clamp cover 66 
describes a line (A) as shown in FIG. 17 when the clamp cover 66 opens and 
closes. The clamp cover 66 is connected to the other end of the arm 70 
rotating around the axis 68, and the movement of the other end of the arm 
70 is regulated by the link 78 pivotally movable around the pin 82. 
Accordingly, the clamp cover 66 describes a curved line both in opening 
and closing, and the curved lines in opening and closing coincide with 
each other. 
In the constitution utilizing such link-mechanism, when the clamp 66 opens 
and closes, it makes large impulsive sound, which has been desired to be 
reduced. 
An object of the present invention is to provide a stencil printing machine 
capable of surely preventing the ink-leakage and reducing the impulsive 
sound when the clamp cover opens and closes. 
SUMMARY OF THE INVENTION 
A stencil printing machine as defined in the first aspect of the present 
invention comprises a printing drum having a flexible ink-permeable 
circumferential wall adapted to receive a perforated stencil sheet around 
an outer circumferential surface thereof, the printing drum being driven 
to rotate around a central axis thereof; pressing means situated inside 
the printing drum for supplying ink to an inner surface of the 
circumferential wall, the pressing means being movable between a pressing 
position for pressing the circumferential wall to be deformed radially 
outwardly and a standing position for releasing the circumferential wall 
from deformation; an opposing drum disposed adjacent to the printing drum 
and driven to rotate in a direction opposite to that of the printing drum; 
a clamp disposed on an outer circumferential surface of the opposing drum 
and operating in synchronization with rotation of said the drum to hold a 
leading edge of a printing sheet supplied between the printing drum and 
the opposing drum; a clamp cover disposed on the outer circumferential 
surface of the opposing drum adjacent to the clamp relative to the 
direction of rotation of the opposing drum and covering the recess formed 
in the opposing drum for allowing operation of the clamp, the clamp cover 
selectively opening and closing the recess in synchronization with 
operation of the clamp; and driving mechanism for driving the clamp cover 
to move alternately in a circumferential direction and a radial direction 
of the opposing drum. 
A stencil printing machine as defined in the second aspect of the present 
invention comprises a printing drum having a flexible ink-permeable 
circumferential wall adapted to receive a perforated stencil sheet around 
an outer circumferential surface thereof; the printing drum being driven 
to rotate around a central axis thereof; pressing means situated inside 
the printing drum for supplying ink to an inner surface of the 
circumferential wall, the pressing means being movable between a pressing 
position for pressing the circumferential wall to be deformed radially 
outwardly and a standing position for releasing the circumferential wall 
from deformation; an opposing drum disposed adjacent to the printing drum 
and driven to rotate in a direction opposite to that of the printing drum; 
a recess formed in an outer circumferential surface of the opposing drum; 
a clamp having a rotational axis extending parallel to a central axis of 
the opposing drum and disposed adjacent to the recess and a plate member 
attached to the rotational axis, the clamp holding a leading edge of a 
printing sheet supplied between the printing drum and the opposing drum; a 
clamp cover disposed on the outer circumferential surface of the opposing 
drum at a rear side of the clamp relative to a direction of rotation of 
the opposing drum for covering the recess so as to be movable in a 
circumferential direction and a radial direction of the opposing drum; a 
clamp driving mechanism attached to the opposing drum for driving the 
clamp to open and close in synchronization with the rotation of the 
opposing drum; a circumferential movement mechanism disposed to the 
opposing drum for moving the clamp cover in a circumferential direction of 
the opposing drum in synchronization with the rotation of the opposing 
drum; and a radial movement mechanism disposed to the opposing drum for 
moving the clamp cover in a radial direction of the opposing drum in 
synchronization with the rotation of the opposing drum so that when the 
clamp opens, the clamp cover departs from the clamp in the circumferential 
direction and then moves radially outwardly of the opposing drum, and when 
the clamp closes, the clamp cover approaches the clamp in the 
circumferential direction and then moves radially inwardly of the opposing 
drum to cover the recess. 
A stencil printing machine as defined in the third aspect of the present 
invention comprises a printing drum having a flexible ink-permeable 
circumferential wall adapted to receive a perforated stencil sheet around 
an outer circumferential surface thereof, the printing drum being driven 
to rotate around a central axis thereof, pressing means situated inside 
the printing drum for supplying ink to an inner surface of the 
circumferential wall, the pressing means being movable between a pressing 
position for pressing the circumferential wall to be deformed radially 
outwardly and a standing position for releasing the circumferential wall 
from deformation; an opposing drum disposed adjacent to the printing drum 
and driven to rotate in a direction opposite to that of the printing drum; 
a recess formed in an outer circumferential surface of the opposing drum; 
a clamp having a rotational axis extending parallel to a central axis of 
the opposing drum and disposed adjacent to the recess and a plate member 
attached to the rotational axis, the clamp holding a leading edge of a 
printing sheet supplied between the printing drum and the opposing drum; a 
clamp driving mechanism having a first arm connected to the rotational 
axis, a first driven member attached to the first arm, and a first cam for 
rotating the rotational axis by moving the first driven member upon 
rotation of the opposing drum so that the clamp opens and closes 
alternately in synchronization with the rotation of the opposing drum; a 
clamp cover disposed on the outer circumferential surface of the opposing 
drum at a rear side of the clamp relative to a direction of rotation of 
the opposing drum for covering the recess so as to be movable in a 
circumferential direction and a radial direction of the opposing drum; a 
circumferential movement mechanism having a second arm, the second arm 
being rotatable around a central axis of the opposing drum and including 
one end portion connected to the clamp driving mechanism and the other end 
portion rotatably connected to the clamp cover with a connecting axis so 
that the clamp cover moves in the circumferential direction of the 
opposing drum when the clamp opens and closes; and a radial movement 
mechanism having a third arm rotatably connected to the connecting axis 
and connected to the clamp cover, a second driven member attached to an 
end of the third arm, and a second cam for driving the clamp cover to 
rotate around the connecting axis by moving the second driven member upon 
rotation of the opposing drum so that the clamp cover moves in the radial 
direction of the opposing drum when the second arm rotates around the 
central axis of the opposing drum while the clamp opens and closes, the 
clamp cover departing from the clamp in the circumferential direction when 
the clamp opens and next moves radially outwardly of the opposing drum, 
and approaching the clamp in the circumferential direction when the clamp 
closes and next moves radially inwardly of the opposing drum to cover the 
recess. 
A stencil printing machine as defined in the fourth aspect of the present 
invention further comprises urging means for urging the third arm so that 
the clamp cover is urged to move radially inwardly of the opposing drum in 
the third aspect. 
According to a stencil printing machine as defined in the fifth aspect of 
the present invention, in the stencil printing machine of the third 
aspect, the second arm includes a hole at the other end portion thereof, 
and the third arm is connected to the clamp cover with a connecting member 
inserted through the hole. 
According to a stencil printing machine as defined in the sixth aspect of 
the present invention, in the stencil printing machine of the third 
aspect, the stencil printing machine further comprises a frame for 
supporting the central axis of the opposing drum, and the first cam and 
the second cam are coaxially fixed to the frame on the central axis while 
pinching the opposing drum.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
One embodiment of the present invention will be explained referring to 
FIGS. 1 to 9. In the embodiment, a driving mechanism for moving a clamp 
cover in an opposing drum as a back-pressing roller will be mainly 
explained. The opposing drum explained in the embodiment is a part of a 
stencil printing machine having a printing drum and so on. Structure and 
its operation not explained herein are approximately identical to those of 
the related art. 
Referring to FIGS. 1, 2, and 8, structure of a paper roller 300 as the 
back-pressing roller will be explained. 
Plural clamps 204 are disposed on the opposing drum 300. A mechanism for 
opening and closing the clamp 204 will be explained. 
The opposing drum 300 has an axis 205. The plural clamps 204 are fixed to 
the axis 205 at a predetermined distance therebetween. One end of an arm 
206 is fixed to one end portion of the axis 205. A driven member 209 is 
attached to the other end of the arm 206. A cam 200 is adjacent to one end 
of the opposing drum 300 and fixed to a not-shown frame of the opposing 
drum 300. The arm 206, the driven member 209, and the cam 200 are arranged 
on the distant end-face side in the perspective view of FIG. 8. 
The driven member 209 engages with the cam 200. The cam 200 is fixed to the 
frame. The driven member 209 follows the cam 200 while rotating with the 
opposing drum 300. The outer shape of the cam 200 enables the clamp 204 to 
open or close at appropriate timing in synchronization with rotation of 
the opposing drum 300. 
A clamp cover 202 is disposed on the opposing drum 300. The clamp cover 202 
is a member that covers gaps between the clamps 204 arranged at intervals 
and a recess formed in the opposing drum 300 at a rear side of the clamps 
204. 
A circumferential movement mechanism will be explained. The mechanism is 
for moving the clamp cover in a circumferential direction of the opposing 
drum 300. An arm 208 in the shape of L is rotatably connected to the axis 
203 at an elbow-portion thereof One end of the arm 208 is connected to a 
link 212. The link 212 is connected to one end of the axis 205 via a link 
211. The other end of the axis 205 is connected to an arm 206. A driven 
member 209 is rotatably supported on the arm 206. The clamp cover 202 is 
rotatably connected to the other end of the arm 208 via a connecting axis 
210. 
Movement of the clamp 204 makes the arm 208 swing around the axis 203 via 
the link 211 and the link 212. The clamp cover 202 attached to the arm 208 
moves in the circumferential direction of the opposing drum 300 around the 
axis 203. 
A radial movement mechanism will be explained. The mechanism is for moving 
the clamp cover in a radial direction of the opposing drum 300. A 
connecting axis 210 is connected to the other end of the arm 208. An arm 
215 is rotatably connected to the connecting axis 210 at one end thereof. 
A driven member 214 is rotatably attached to the other end of the arm 215. 
A cam 201 is adjacent to the other end of the opposing drum 300 and fixed 
to the not-shown frame of the opposing drum 300. The arm 215, the driven 
member 214, and the cam 201 are arranged on the near end-face side in the 
perspective view of FIG. 8. 
The driven member 214 engages with the cam 201. The cam 201 is fixed to the 
frame. The driven member 214 follows the cam 201 while rotating with the 
opposing drum 300. The outer shape of the cam 201 enables the clamp cover 
202 to move in the radial direction of the opposing drum 300 at 
appropriate timing in synchronization with rotation of the opposing drum 
300. 
A pin 216 is fixed to an end portion of the clamp cover 202. The pin 216 is 
connected to the arm 215 while passing through a groove 207 formed in the 
other end of the arm 280. The arm 215 is connected to the end face of the 
opposing drum 300 by a spring 213 as urging means. Thus, the arm 215 is 
always urged by the spring 213 to rotate anticlockwise around the 
connecting axis 210 in FIG. 1. Accordingly, the clamp cover 202 is urged 
to move inward in the radial direction of the opposing drum 300. 
Operation of the clamp and the clamp cover in the above-explained 
constitution will be explained. 
(1) Operation of the clamp 204 
The opposing drum 300 is driven to rotate. The cam 200 remains static since 
it is fixed to the frame side. The driven member 209 connected to the 
opposing drum 300 follows the shape of the cam 200 while rotating around 
the axis 203. The movement of the driven member 209 connected to the arm 
206 causes the axis 205 to rotate, thereby opening or closing the clamp 
204. 
(2) Operation of the clamp cover 202 
Operation of the clamp cover 202 is composed of a circumferential movement 
in the circumferential direction of the opposing drum 300, namely a 
rotational movement around the axis 203, and a radial movement in the 
radial direction of the opposing drum 300, namely a rotational movement 
around the axis 210. 
The circumferential movement of the clamp cover 202 is to be effected as 
follows. When the driven member 209 is lifted up by the cam 200, the axis 
205 is driven to rotate. The rotational movement of the axis 205 is 
converted into the rotational movement of the clamp cover 202 around the 
axis 203 by the link 211, the link 212, and the L-shaped arm 208. Since 
the clamp cover 202 is urged by the spring, it remains closed radially 
inwardly over the opposing drum 300 if the driven member 214 is not lifted 
up by the cam 201. In FIG. 1, a circumferential surface of the driven 
member 214 is distant from a circumferential surface of the cam 201 by a 
very small gap. 
The radial movement of the clamp cover 202 in the radial direction of the 
opposing drum 300, namely a rotational movement around the axis 210, is 
effected only by the cam 201 and the driven member 214 engaged with each 
other. When the driven member 214 is lifted up by the cam 201, the arm 215 
is driven to rotate clockwise in FIG. 1, and the clamp cover 202 moves to 
open. 
Next, referring to FIGS. 1 to 7, consecutive movement of the clamp 204 and 
the clamp cover 202 will be explained. 
In FIG. 9, the arrows (1) to (4) are lines described by a front end of the 
clamp cover 202 moving relative to the opposing drum 300. The clamp cover 
202 opens in the circumferential direction of the opposing drum 300 as 
shown by the arrow (1), next opens in the radial direction of the opposing 
drum 300 as shown by the arrow (2), next closes in the circumferential 
direction while being opened in the radial direction as shown by the arrow 
(3), and closes in the radial direction as shown by the arrow (4). The 
consecutive movements shown by the arrows (1) to (4) effected in rotation 
of the opposing drum 300 will be explained referring to FIGS. 1 to 7. 
In FIGS. 1 and 2, the clamp 204 and the clamp cover 202 are closed. FIGS. 3 
to 7 illustrate consecutive rotating states of the opposing drum 300 
starting from the state of FIG. 1. 
Next, FIGS. 3,4, and 5 correspond to the movement (1). In FIG. 3, the 
driven member 209 starts to be lifted up by the cam 200, and the clamp 204 
starts to open. The clamp cover 202 starts to open in the circumferential 
direction. In FIG. 4, the clamp 204 opens broader, and the clamp cover 202 
opens broader in the circumferential direction. In FIG. 5, the clamp 204 
opens broadest, and the clamp cover 202 opens broadest in the 
circumferential direction. In a mid-state changing from the state of FIG. 
5 to that of FIG. 6, the driven member 214 is lifted up by the cam 201, 
thereby opening the clamp cover 202 in the radial direction, which 
movements correspond to the movement (2). 
Next, in FIG. 6, the driven member 209 lowers while following the cam 209. 
The circumferential return-movement of the clamp cover 202, i.e. the 
movement (3), and the closing movement of the clamp 204 are started. 
When the rotating state proceeds further from that of FIG. 7, the driven 
member 214 lowers while following the cam 201, and the clamp cover 202 
starts to close in the radial direction of the opposing drum 300, which 
movements correspond to the movement (4). Further rotation of the opposing 
drum 300 leads to the state of FIG. 1. The clamp cover 202 is completely 
closed in the radial direction of the opposing drum 300. Also, the clamp 
204 returns to the state where it is completely closed. 
According to the present invention, in operating a stencil printing machine 
comprising a printing drum having a pressing means disposed therein for 
supplying-ink and an opposing drum having a clamp and a clamp cover, 
circumferential movement and radial movement is separated and alternately 
conducted when the clamp cover is moved. Namely, the clamp cover departs 
from the clamp in the circumferential direction when the clamp opens, and 
then moves outwardly in the radial direction. The clamp cover approaches 
the clamp in the circumferential direction when the clamp closes, and then 
moves inwardly in the radial direction, thereby returning to the initial 
position. The constitution thus stated produces effects as follows: 
(1) Impulsive sound caused by operating a clamp cover is greatly reduced, 
since the clamp cover of the present invention moves only in the 
circumferential direction along the circumferential surface of the 
opposing drum when a printing sheet held by the clamp is discharged. 
Contrary to this, as illustrated in FIG. 17, in the case where the front 
end of the clamp cover of the opposing drum describes a curve, impulsive 
sound caused by operating the clamp cover is very large. 
(2) Clamping operation of a supplied printing sheet by the clamp cover can 
be conducted only by urging force of a spring. Impulsive sheet-clamping 
sound produced in the operation by the present invention can be further 
deteriorated relative to the one produced in the forceful sheet-clamping 
operation by the link mechanism of the related-art previously proposed by 
the applicant. 
(3) In the constitution using the link mechanism of the related art, the 
clamp and the clamp cover are requested to close at completely the same 
timing. If the timing is shifted to each other, problems such as a 
sheet-supplying jam and so on may occur. In the present invention, since 
the clamp driving mechanism, the circumferential movement mechanism of the 
clamp cover, and the radial movement mechanism of the clamp cover are 
separately constituted, the stencil printing machine can be adjusted in 
such a manner that the clamp cover closes after the clamp closes at a 
slight interval, so that the problems in the sheet-supplying process can 
be avoided.