The present invention relates to a feed apparatus for a printing press, which chucks sheets stacked on a pile board one by one from the uppermost one and feeds the chucked sheet.
As shown in Japanese Utility Model Laid-Open No. 3-24511, a conventional feed apparatus for a printing press comprises the first sucker member which chucks sheets which are supported to be vertically movable and stacked on a pile board one by one from the uppermost one, and the second sucker member which chucks the sheet transferred from the first sucker member and conveys it. Of the two sucker members, the first sucker member comprises a cylindrical guide nozzle, a sucker fitted on the outer surface of the guide nozzle to be vertically movable and having a chuck hole in its lower end face, and a sucker spring which is elastically mounted between the sucker and guide nozzle and biases the sucker downward with respect to the guide nozzle.
In this arrangement, when the first sucker member that has moved downward is moved close to the sheet and air in the guide nozzle is drawn, the sheet is chucked by the chuck hole of the sucker. When the sheet closes the chuck hole, the interior of the sucker is set in a negative pressure state, and the sucker moves upward against the spring force of the sucker spring. Subsequently, when the sheet is chucked by the second sucker member, it is transferred to the second sucker member. After that, air drawing into the guide nozzle is stopped, and the second sucker member conveys the sheet.
In the conventional feed apparatus for the printing press, when the second sucker member chucks the sheet and conveys it, drawing air supply to the guide nozzle of the first sucker member is stopped. Thus, the spring force of the sucker spring moves the sucker downward. At this time point, since the second sucker member has not completely conveyed the sheet yet, the sheet is present below the sucker of the first sucker member. Therefore, the sucker of the first sucker member that moves downward may come into contact with the sheet. This may scratch the sheet, or separate the chucked sheet from the second sucker member.
When the sucker of the first sucker member pushes the sheet downward, the sheet may interfere with blowing air discharged from a leveling foot. In this case, air discharged from the leveling foot is not supplied to the portion between the first and second sheets, and the sheets cannot be reliably fed one by one.
It is an object of the present invention to provide a feed apparatus for a printing press, which can reliably feed sheets one by one without scratching them.
In order to achieve the above object, according to the present invention, there is provided a feed apparatus for a printing press, comprising a first sucker device which chucks sheets, which are stacked and supported to be vertically movable, one by one from the uppermost one, and a second sucker device which chucks the sheet transferred from the first sucker device and conveys the sheet, the first sucker device comprising a guide nozzle, a sucker which is supported by the guide nozzle to be vertically movable and includes a chuck hole at a bottom for chucking the sheet, and a spring which biases the sucker toward a distal end of the guide nozzle, the guide nozzle comprising a first air passage for drawing the sheet and a second air passage for drawing the sucker, and the sucker comprising a closing portion which closes the second air passage when the sucker is located at an upper limit against a biasing force of the spring.
The first embodiment of the present invention will be described in detail with reference to
As shown in
The guide nozzle 10 has, at its central portion, a sheet drawing air passage 14 extending in the vertical direction and having an opening 14a at its lower end. When the guide nozzle 10 moves downward, the air passage 14 communicates with chuck holes 18a of the sucker 11 through the opening 14a, as shown in
As shown in
As shown in
When air is drawn into the air passages 14 and 16 of the guide nozzle 10 and the sucker 11 moves upward and reaches the upper limit, the valve seat 19 closes the exhaust port 16a of the air passage 16. A ring-shaped spring bearing 19a forms a recess at the upper edge of the valve seat 19 to surround the valve seat 19. The compression coil spring 12 loaded in the air passage 16 of the guide nozzle 10 is elastically mounted between the spring bearing 19a and the upper end of the air passage 16. A gap that does not interfere with the flow of air drawn from the air pipe 8 is reserved between the air passage 16 loaded with the compression coil spring 12 and the compression coil spring 12.
In this embodiment, the air passage 14 is formed at the central portion of the guide nozzle 10, and the air passage 16 loaded with the compression coil spring 12 is formed to surround the air passage 14. According to this embodiment, the structure of the guide nozzle 10 can be simplified and down-sized.
A sucker frame 20 provided above the sheets 2 stacked on the pile board projects backward from the upper end of a sheet feed frame. As shown in
A pair of arms 25 vertically hang downward from an arm shaft 24 axially supported by the sucker frame 20. The arms 25 support a support shaft 26 horizontally, and the pair of sucker devices 4 are fixed at the two ends of the support shaft 26. A cam lever 27 is pivotally mounted on a bracket 28 fixed to the sheet feed frame, and a pair of levers 29 which support the air pipe 7 are pivotally attached to a pin 9 formed at the free end of the cam lever 27. The air pipe 7, together with the air pipe 8, supports the guide nozzles 10. A cam follower 31 is pivotally mounted at the center of the cam lever 27. As shown in
In this arrangement, when the cam 22 rotates, the cam surface of the cam 22 cooperates with the tensile force of the tension coil spring 32 to swing the cam lever 27. This pushes the sucker 11 of the sucker device 3 upward. The spring force of the compression coil spring 12 pushes the sucker 11 of the sucker device 3 downward.
A cam follower 32 is pivotally mounted on one of the pair of arms 25. A spring member (not shown) brings the cam follower 32 into tight contact with the cam surface of the cam 23. When the cam 23 rotates, the arms 25 swing, and the sucker devices 4 reciprocate once per turn of the cam 23 between the position indicated by a solid line and the position indicated by an alternate long and two dashed line in
As shown in
The feed operation of the feed apparatus for the printing press having the above arrangement will be described with reference to
As air is continuously drawn into the air passages 14 and 16, the interiors of the sucker devices 3 are set in the negative pressure state. Thus, the external atmospheric pressure compresses the compression coil springs 12 in the guide nozzles 10, and the suckers 11 move upward, while chucking the sheet 2, due to the tensile operation of the compression coil springs 12. When the suckers 11 reach the upper limit as shown in
As air is continuously drawn into the air passages 16, the interiors of the air passages 16 are set in the negative pressure state. Thus, the suckers 11 are maintained at the upper limit. At this time, a small-diameter portion 22b of the cam 22 (
As the sucker devices 3 move upward, the sheet 2 chucked by the suckers 11 also moves upward to come close to the sucker devices 4. As shown in
At time T3 which is slightly after the time T2, as shown in
As described above, immediately after the sheet 2 is transferred from the sucker devices 3 to the sucker devices 4, the suckers 11 of the sucker devices 3 are maintained at the upper limit and do not move downward, and accordingly will not come into contact with the sheet 2 chucked by the sucker devices 4. Thus, the sheet 2 will not be scratched, or will be separated from the sucker devices 4. Since the sheet 2 released from the suckers 11 is not pushed down by the suckers 11, the sheet 2 does not interfere with air blowing from the leveling foot 5. Therefore, the leveling foot 5 reliably holds the second and subsequent sheets, and air is reliably discharged to the gap between the first and second sheets. Thus, the sheets 2 can be reliably supplied one by one.
When the sheet 2 is transferred from the sucker devices 3 to the sucker devices 4, the cam 23 and cam follower 32 swing the arms 25. Thus, the sucker devices 4 that chuck the sheet 2 move forward from the position indicated by the solid line to the position indicated by the alternate long and two short dashed line in
At time T4, as shown in
At time T5, as shown in
Although the timing to start air drawing into the air passages 16 is set at the time T1 in the above embodiment, it may be at any time between the time 1 when air drawing into the air passages 14 is started and the time T3 when air drawing is stopped. Although the timing to end air drawing into the air passages 16 is set at the time T4, it may be before the time T4 as far as it is a timing at which the sheet 2 conveyed by the sucker devices 4 is not located below the sucker devices 3.
As has been described above, according to the present invention, when transferring the sheet from the first sucker devices to the second sucker devices, although air drawing for the sheet is stopped, air drawing into the air passages is continued. Therefore, before the suckers of the first sucker devices move downward, the second sucker devices can convey the sheet. According to the present invention, the sheet can be prevented from being scratched by the suckers of the first sucker devices or from separated from the second sucker devices.
Number | Date | Country | Kind |
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207645/2007 | Aug 2007 | JP | national |