JPH0631524A - Cutting device of belt-shaped member - Google Patents

Abstract

PURPOSE:To draw a belt-shaped member stuck to a lower edge apart from the lower edge after cutting without causing any transformation of the member. CONSTITUTION:A belt-shaped member B is stuck to a lower edge 14 because it is strongly pressed against the lower edge 14 by means of a cutter and a presser plate 68 during cutting operation. For this reason, a separation member 96 is inserted between the belt-shaped member B and the lower edge 14 to draw the belt-shaped member B apart from the lower edge 14 but on the occasion of doing so the belt-shaped member B is scarely deformed because the separation member 96 is a thin plate and, moreover, it moves in the direction almost orthogonal to the longitudinal direction of the lower edge 14 along the upper surface of the lower edge 14.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cutting device for cutting a belt-shaped member in a width direction by using a linear lower blade and a cutter.

[0002]

2. Description of the Related Art As a conventional device for cutting a belt-shaped member, a device described in, for example, JP-A-60-135108 is known. This is a linear lower blade that is installed immediately below the belt-shaped member and extends intersecting the belt-shaped member, a disc-shaped upper blade that partially contacts the lower blade and rotates freely, and an upper blade. By moving along the lower blade, the moving mechanism that cuts the belt-shaped member in the width direction by the lower blade and the upper blade, the pressing claw that is installed directly above the belt-shaped member and extends along the lower blade, and the pressing claw. A pressing mechanism that regulates the movement of the belt-shaped member during cutting by moving it to press the belt-shaped member against the lower blade, and a swing mechanism that is provided directly below the belt-shaped member near the cutting position and extends parallel to the lower blade and that is parallel to the lower blade. A comb-teeth-shaped peeling pawl that can be swung up and down about a moving shaft, and when the pressing pawl is separated from the belt-shaped member immediately after cutting, swing the peeling pawl upward about the rocking shaft. The band-shaped member near the cutting position Push, there has been known one provided with a pull peeled off the cylinder from the lower blade profile strip which is stuck to the lower blade.

[0003]

However, in such a conventional band-shaped member cutting device, the lower blade is moved by swinging the peeling claw upward and pushing up the band-shaped member in the vicinity of the cutting position. Since the strip-shaped member that adheres to the bottom blade is peeled off from the lower blade, the strip-shaped member near the cutting position is deformed into a chevron and stretched during the peeling, and as a result, the cut strip-shaped member is cut. However, there is a problem that the quality of the product deteriorates.

It is an object of the present invention to provide a band-shaped member cutting device capable of peeling a band-shaped member adhered to a lower blade after cutting without substantially deforming the lower blade.

[0005]

SUMMARY OF THE INVENTION Such an object is to provide a linear lower blade that is installed immediately below a belt-shaped member and extends so as to intersect the belt-shaped member, and to move along the lower blade so as to move the belt-shaped member. A cutter that cuts in the width direction in cooperation with the lower blade at the cutting position, a pressing plate that is installed immediately above the band-shaped member and extends along the lower blade, and the pressing plate is moved to press the band-shaped member against the lower blade. As a result, the pressing mechanism that restricts the movement of the belt-shaped member at the time of cutting, the thin plate-shaped peeling member that is provided immediately below the belt-shaped member near the cutting position and is parallel to the lower blade, and the pressing plate separated from the belt-shaped member immediately after cutting. At this time, by moving the peeling member along the upper surface of the lower blade in a direction substantially orthogonal to the longitudinal direction of the lower blade, the peeling member is pushed between the strip-shaped member and the lower blade to adhere to the lower blade. Obi belt A pushing mechanism which peeled off the member from the lower edge, it can be achieved by providing a.

[0006]

When the band-shaped member is cut, the pressing plate is moved toward the lower blade by the pressing mechanism, and the band-shaped member near the cutting position is pressed against the lower blade by the pressing plate.
Next, by moving the cutter along the lower blade,
The band-shaped member is cut in the width direction at the cutting position. At this time, since the pressing plate presses the strip-shaped member against the lower blade, the movement of the strip-shaped member is restricted. Next, the pressing mechanism moves the pressing plate to separate it from the belt-shaped member. Here, the band-shaped member is strongly pressed against the lower blade by the cutter and the pressing plate during cutting,
Stick to the lower blade. Therefore, the peeling member is pushed between the strip-shaped member and the lower blade by the pushing mechanism, and the strip-shaped member adhered to the lower blade is peeled from the lower blade, but at this time, the stripping member is a thin plate, and, Since it can be moved along the upper surface of the lower blade in a direction substantially orthogonal to the longitudinal direction of the lower blade,
There is almost no deformation of the strip-shaped member when peeled off, and as a result, the quality of the cut strip-shaped member is improved.

According to the second aspect of the present invention, the drive mechanism can be made smaller and less expensive, and the timing of the pressing mechanism and the pushing mechanism can be eliminated to improve the efficiency of cutting work.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. In FIGS. 1 and 2, reference numeral 11 denotes a cutting device for cutting a belt-shaped member B, for example, a belt-shaped rubber member having a cord made of polyester, nylon or the like embedded therein, in a substantially width direction,
The cutting device 11 has a base 13 installed on a floor surface 12, on which a horizontal straight line which is located directly below the strip-shaped member B and which intersects and extends with respect to the strip-shaped member B. The lower blade 14 is attached.

2, 3, 4, and 5, legs 17 are erected on the floor surface 12 on both sides of the base 13, respectively.
A fixed beam 18, which is parallel to the lower blade 14 and is located substantially directly above the lower blade 14, is fixed to the upper end of the lower blade 17. This fixed beam
A pair of guide rails 19 parallel to the lower blade 14 are attached to the lower part of 18. Reference numeral 21 denotes a carriage, and a plurality of guide rolls 23 are rotatably supported on an upper portion of the carriage 21 via a vertical mounting shaft 22, and the guide rolls 23 sandwich the guide rail 19 from the front and rear. As a result, the carriage 21 is movably supported by the fixed beam 18. A horizontal support hole 24 extending in the front-rear direction, that is, the longitudinal direction of the belt-shaped member B is provided in the carriage 21.
In the support hole 24, a holder 26 is supported via a pair of bearing rings 25 so as to be rotatable about the swivel axis S. An insertion hole 27 that is inclined by a small angle a in the horizontal plane with respect to the swivel axis S is formed in the holder 26, and a hollow shaft 29 is rotatable in the insertion hole 27 via a pair of bearings 28. Supported by. Here, since the hollow shaft 29 is coaxial with the insertion hole 27, its rotation axis K intersects the swivel axis S at a small angle a in the horizontal plane. Reference numeral 30 denotes a fitting shaft fitted and attached to the front end portion of the hollow shaft 29, and a disc-shaped cutter 31 coaxial with the hollow shaft 29 is integrally formed at the front end of the fitting shaft 30. There is. As a result, the cutter 31 can swing around the turning axis S when the holder 26 rotates about the turning axis S. Here, since the cutter 31 is supported by the holder 26 via the bearing 28, the cutter 31 can rotate freely together with the fitting shaft 30 and the hollow shaft 29, and can be minutely moved in the horizontal plane with respect to the lower blade 14. It is inclined at an angle b. Here, the inclination direction of the cutter 31 with respect to the lower blade 14 is such that when the strip-shaped member B is cut from one side of the lower blade 14 to the other side by the cutter 31 and the lower blade 14, the cutter 31 moves toward the other side. Is a direction toward the lower blade 14, and on the other hand, when the belt-shaped member B is cut from the other side toward one side, the cutter 31 is a direction closer to the lower blade 14 toward the one side. In this example,
The minute angle a and the minute angle b are set to the same angle of 0.05 to 0.08.
It is about a degree.

Reference numeral 34 denotes a spring receiver fixed to the rear portion of the carriage 21, a spring receiver 35 is housed in the carriage 21 in front of the spring receiver 34, and the spring receiver 34 and the spring receiver 35 are connected to each other. A spring 36 is interposed between them. The urging force of the spring 36 is transmitted to the hollow shaft 29 and the cutter 31 via the spring receiver 35 and the bearing 37 that connects the spring receiver 35 and the hollow shaft 29, and a part of the outer edge of the cutter 31 is moved downward. The blade 14 is pressed against the cutting edge 15 with a constant force and brought into contact therewith. A pulley 38 that rotates around a horizontal axis is supported at one end and the other end of the fixed beam 18 at the rear surface thereof, and one of these pulleys 38 is driven by an AC servomotor (not shown). Power is transmitted. A belt 39 is stretched between the pulleys 38, and both ends of the belt 39 are connected to the carriage 21.
As a result, when the pulley 38 rotates and the belt 39 travels,
Carriage 21 is guided by guide rail 19
Follow along 14.

Reference numeral 41 denotes a rack shaft parallel to the lower blade 14 slidably inserted in the carriage 21, and a rack 42 formed on the rack shaft 41 has pinion teeth 43 formed on the outer periphery of the holder 26. It is in mesh. Permanent magnets 44 and 45 are fixed to one end and the other end of the rack shaft 41, respectively.
The permanent magnet 4 is provided on one end surface and the other end surface of the carriage 21.
Iron pieces 46 and 47 that can come into contact with 4 and 45 are fixed, respectively. The rack shaft 41 has a position where the permanent magnet 44 and the iron piece 46 contact each other inside the carriage 21, and the permanent magnet 45 and the iron piece 47.
It is possible to move along the lower blade 14 between the positions where and contact, and by moving between these two positions, the holder 26 rotates 180 degrees, and the inclination of the cutter 31 with respect to the lower blade 14 is increased. The direction is reversed. Brackets 48 and 49 are fixed to the leg 17, and stoppers 52 and 53 having a cushioning function by springs 50 and 51 are supported on the brackets 48 and 49, respectively. Then, when the carriage 21 moves to one side by the traveling of the belt 39 and the rack shaft 41 comes into contact with the stopper 52, the rack shaft 41 is moved to the carriage.
When the permanent magnet 44 and the iron piece 46 are pushed into the inside 21 toward the other side until the carriage 21 moves to the other side and the rack shaft 41 comes into contact with the stopper 53, the rack shaft 41
41 is a permanent magnet 45 and an iron piece toward one side in the carriage 21.
It is pushed until it contacts 47. Rack axis 4 mentioned above
1, the permanent magnets 44 and 45, the iron pieces 46 and 47, and the stoppers 52 and 53 as a whole, the holder 26 with the turning axis S as the center.
By rotating the cutter 31 by 80 degrees,
When the strip-shaped member B is cut from one side of the lower blade 14 toward the other side by the lower blade 14 and the cutter 31, the inclination direction of the cutter 31 with respect to the lower blade 14 is directed toward the other side. Accordingly, the cutter 31 is inclined toward the lower blade 14, and when the lower blade 14 and the cutter 31 cut the strip-shaped member B from the other side toward one side,
The tilting mechanism 54 forms the tilting direction of the cutter 31 with respect to the lower blade 14 toward the one side as the tilting direction of the cutter 31 approaches the lower blade 14, and the turning mechanism 54 includes a moving mechanism 55 described later.
It operates by receiving driving force from. Further, the pulley 38, the belt 39, and the motor as a whole include the cutter 31, the holder 26.
By moving the lower blade 14 along the lower blade 14, the lower blade 14 and the cutter 31 cooperate with each other to cut the belt-shaped member B at the cutting position in the width direction.

1, 2 and 6, a bracket 60 is fixed to the front surface of the fixed beam 18 directly above one end and the other end of the lower blade 14, and each bracket 60 has a lower blade through a pair of bearings 61. A transmission shaft 62 parallel to 14 is rotatably supported. Revolving units 63 are fixed to the inner ends of these transmission shafts 62 that are close to each other, and the transmission shafts 62 are attached to the respective revolving units 63.
A support shaft 64 that is eccentric from the rotation shaft of is fixed. A cam follower 66 inserted in the upper end of the link 65 is rotatably supported on each support shaft 64. Link 65
The lower end portion of each is connected to both ends of a lifting beam 67 extending above the lower blade 14 in parallel with the lower blade 14 via support shafts 74. 68 is a presser plate installed between the lifting beam 67 and the lower blade 14 just above the strip-shaped member B and extending along the lower blade 14. The both ends of the pressing plate 68 and the both ends of the lifting beam 67 are They are connected to each other via a plurality of springs 69. Reference numeral 70 denotes a plurality of (three in this case) slide rails whose lower ends are fixed to the presser plate 68 and extend in the vertical direction. These slide rails 70 are arranged at a predetermined distance from each other in the longitudinal direction of the lower blade 14. There is. 71 is a plurality (here, 3) attached to the front of the fixed beam 18.
The slide bearings 72 with which the upper ends of the slide rails 70 are slidably engaged are fixed to the brackets 71, respectively. Reference numeral 73 denotes three slide bearings fixed to the elevating beam 67, and the central portion of the slide rail 70 is slidably engaged with these slide bearings 73. As a result,
When the transmission shaft 62 rotates and the revolving structure 63 revolves around the transmission shaft 62, since the support shaft 64 and the cam follower 66 are eccentric from the transmission shaft 62 as described above, the link 65 moves up and down to raise and lower the beam 67. The holding plate 68 moves up and down while being guided by the slide rail 70 and the slide bearings 72 and 73. When the lifting beam 67 descends and the pressing plate 68 presses the strip-shaped member B against the upper surface of the lower blade 14 immediately before the cutting position by the elastic force of the spring 69, the movement of the strip-shaped member B at the time of cutting is restricted. . 76 is a fixed beam 18
An AC servomotor mounted on the upper surface of the motor. The rotation of the motor 76 is transmitted via a belt 77 to a transmission shaft 79 rotatably supported by a bearing 78, and the rotation of the transmission shaft 79 is transmitted via a belt 80. Pulley attached to the transmission shaft 62
It is transmitted to 81. Revolving structure 63, support shaft 64, link described above
65, the cam follower 66, the elevating beam 67, and the slide bearings 72, 73 as a whole move the pressing plate 68 to press the strip-shaped member B near the cutting position against the upper surface of the lower blade 14 by the pressing plate 68, and at the time of cutting. A pressing mechanism 82 that restricts the movement of the belt-shaped member B is configured.

1, 2 and 7, a support beam 85 extending in the front-rear direction is fixed to the front surface of each leg 17, and a slide rail 86 attached to the lower surface of each support beam 85 extending in the front-rear direction. A slide bearing 88 fixed to the slider 87 is slidably engaged. 89 is an eccentric cam formed on the outer end of each transmission shaft 62, and each eccentric cam 89 is eccentric by a predetermined distance from the rotation axis of the transmission shaft 62. Reference numeral 90 denotes a vertically extending link in which the eccentric cam 89 is inserted and connected at the upper end.
The lower end of is connected to one end of an L-shaped link 93 that is swingably connected to a bracket 91 attached to the leg 17 via a pin 94. The slider 87 is connected to the other end of each L-shaped link 93 via a pin 95. Further, both ends of a thin plate-like peeling member 96 which is provided immediately below the strip-shaped member B near the cutting position and extends parallel to the lower blade 14 and which is parallel to the upper surface of the lower blade 14 are connected to these sliders 87. And this peeling member 96 is the lower blade 1
4. When the band-shaped member B is cut by the cutter 31 at the cutting position, and immediately after that, when the pressing plate 68 moves upward and separates from the band-shaped member B, along the upper surface of the lower blade 14, in the longitudinal direction of the lower blade 14. It moves between the strip-shaped member B and the lower blade 14 in a direction substantially orthogonal to each other, here, rearward, and the lower blade 14 and the strip-shaped member B move.
Is pushed between and. And such a peeling member 96
The eccentric cam 89 is moved by the rotation of the transmission shaft 62.
The link 90 is moved up and down by turning around the rotation axis of 62, whereby the L-shaped link 93 swings around the pin 92. The slider 87, the eccentric cam 89, the link 90, and the L-shaped link 93 as a whole, as a whole, push the peeling member 96 between the strip-shaped member B and the lower blade 14 to thereby attach the strip-shaped member B to the lower blade 14. A push-in mechanism 97 for peeling the blade from the lower blade 14 is configured. The transmission shaft 62 described above,
The motor 76, the belt 77, the transmission shaft 79, the belt 80, and the pulley 81 constitute one drive mechanism 98 that applies a drive force to both the pressing mechanism 82 and the pushing mechanism 97 as a whole. If a driving force is applied to both the pressing mechanism 82 and the pushing mechanism 97 by the driving mechanism 98, the driving mechanism 98
Is small and inexpensive, and the timing of the pressing mechanism 82 and the pressing mechanism 97 is eliminated, thus improving the efficiency of cutting work.

Next, the operation of the embodiment of the present invention will be described. Now, the cutting position of the strip-shaped member B is the cutting edge 15 of the lower blade 14.
It is assumed that the elevator beam 67 and the pressing plate 68 are positioned above and above the cutting position of the belt-shaped member B, and that the carriage 21 and the cutter 31 are waiting at one end of the lower blade 14. At this time, the cutter 31 is inclined at a minute angle b so as to approach the lower blade 14 toward the other side with respect to the lower blade 14 as shown by the solid line in FIG.

Next, the motor 76 is activated to rotate the transmission shafts 79 and 62. The rotation of the transmission shaft 62 causes the eccentric cam 89 to eccentrically rotate around the rotation shaft of the transmission shaft 62, and the link 90 is pushed down by the eccentric cam 89. As a result, the L-shaped link 93 swings around the pin 92, and the slider 87 moves forward while being guided by the slide rail 86. As a result, the peeling member 96 has a cutting edge 15 of which the rear end is the lower blade 14.
It moves backward until it is located further forward, and retracts from the movement path of the cutter 31. On the other hand, the rotation of the transmission shaft 62 causes the cam follower 66 to eccentrically rotate about the rotation shaft of the transmission shaft 62. By this eccentric turning, the link 65 is pushed down, the lifting beam 67 descends while being guided by the slide rail 70 and the slide bearing 72, and the holding plate 68 moves toward the lower blade 14. Since the link 65 is pushed down even after the pressing plate 68 contacts the upper surface of the belt-shaped member B, the spring 69 is compressed and its elastic force is transmitted to the pressing plate 68, and the pressing plate 68 cuts the belt-shaped member B. Immediately before the position is pressed against the upper surface of the lower blade 14 with a constant force. Then, in this state, the motor 76 temporarily stops.

Next, a pulley is driven by a motor (not shown).
38 is driven and rotated, and the belt 39 runs. This allows
The carriage 21 and the cutter 31 move from one side to the other side along the lower blade 14 while being guided by the guide rail 19. At this time, the cutter 31 is inclined at a small angle b with respect to the lower blade 14 as described above, and a part of its outer edge is pressed against the cutting edge 15 of the lower blade 14 by the biasing force of the spring 36. Since it is supported by the carriage 28 so as to be free to rotate about the rotation axis K by the bearing 28, the cutter 31 and the cutting edge 15 of the lower blade 14 cause the strip-shaped member B to have a substantially width at the cutting position. Is cut in the direction. At this time, since the pressing plate 68 presses the strip-shaped member B near the cutting position against the lower blade 14 as described above, the strip-shaped member B
Is restricted from moving. The process of cutting the strip-shaped member B by moving the cutter 31 from one side to the other side in this way is the forward cutting process.

When the cutting of the belt-shaped member B is completed as described above, the traveling speed of the belt 39 is reduced, and then the other end of the rack shaft 41 supported by the carriage 21 is stopped by the stopper 53.
Abut the tip surface of. Since the carriage 21 moves toward the other side at a low speed even after this contact, the rack shaft 41 is pushed into the carriage 21 toward one side. At this time, since the pinion teeth 43 of the holder 26 mesh with the rack 42 of the rack shaft 41, the movement of the rack shaft 41 causes the holder 42 to move.
26 rotates about the turning axis S. And holder
When 26 rotates by 180 degrees, the belt 36 stops traveling, but at this time, since the rotation axis K and the turning axis S intersect with each other while maintaining a small angle a, the rotation of the holder 26 causes the cutter to rotate. 31 is the lower blade that swings around the turning axis S
The inclination direction with respect to 14 is reversed, and the inclination direction with respect to the lower blade 14 of the cutter 31 becomes a direction closer to the lower blade 14 toward one side, as shown by a virtual line in FIG. Then, the rotation of the holder 26 is stopped when the inclination angle of the cutter 31 with respect to the lower blade 14 becomes a predetermined minute angle b. At this time,
The permanent magnets 45 fixed to the rack shaft 41 come into contact with the iron pieces 47 and attract each other. And the above state is
In this way, the permanent magnets 45 and the iron pieces 47 are attracted to each other to regulate the movement of the rack shaft 41, so that the rack shaft 41 is reliably maintained. The process of reversing the inclination direction of the cutter 31 with respect to the lower blade 14 is the reversing process.

Next, the motor 76 is activated again and the transmission shaft 79,
62 rotates. As a result, the cam follower 66 eccentrically rotates around the rotation axis of the transmission shaft 62, and the link 65 and the lifting beam
67, the presser plate 68 moves upward and the presser plate 68
Separates upward from the belt-shaped member B. Since the strip-shaped member B near the cutting position is strongly pressed against the lower blade 14 by the cutter 31 and the pressing plate 68 as described above,
Stick to the lower blade 14. Therefore, the transmission shaft 62 also causes the eccentric cam 89 to eccentrically rotate about the rotation shaft of the transmission shaft 62, and the link 90 is pulled up by the eccentric cam 89, whereby the L-shaped link 93 swings about the pin 92. Then, the slider 87 is moved rearward along the slide rail 86. The stripping member 96 is pushed between the strip-shaped member B near the cutting position and the lower blade 14 by the movement of the slider 87 as shown by the phantom line in FIG. B is peeled off from the lower blade 14, but at this time, the peeling member 96 is in the shape of a thin plate, and the lower blade 14 extends along the upper surface of the lower blade 14.
Since it is moved in a direction (rearward) substantially orthogonal to the longitudinal direction of 14, the band-shaped member B is hardly deformed at the time of peeling, and as a result, the quality of the cut band-shaped member B is improved. Next, the belt-shaped member B is sent out by a predetermined length in the arrow direction in FIG. 5 by a conveyor (not shown), and the next cutting position reaches the cutting edge 15 of the lower blade 14.

Next, the motor 76 is operated to retract the peeling member 96 forward so as not to get in the way of the cutter 31, and the elevating beam 67 descends to lower the strip member B immediately before the cutting position by the pressing plate 68. Pressed on the blade 14.
In this state, the belt 39 runs again and the cutter 31 moves the lower blade 14
While moving to the other side from the other side along the lower blade 14,
The band-shaped member B is cut substantially at the cutting position in the width direction.
The step of cutting the strip-shaped member B by moving the cutter 31 from the other side to the one side is a re-cutting step.

When the cutting of the belt-shaped member B is completed, the belt 39 starts running while being decelerated at a low speed, so that the rack shaft 41 comes into contact with the stopper 52 and the inside of the carriage 21 is permanently moved to the other side. The magnet 44 and the iron piece 46 are pushed in at a low speed until they abut and attract each other. This makes the holder 26 180
The tilt direction and the tilt angle with respect to the lower blade 14 of the cutter 31 return to the tilt direction and the tilt angle in the forward cutting step. Next, the strip-shaped member B is sent out backward by a predetermined length. Such a process is a return process. The above is one cycle of the operation of this embodiment, and this cycle is repeated thereafter, and the strip-shaped member B is cut into a predetermined length one after another.

[0021]

As described above, according to the present invention, the band-shaped member adhered to the lower blade after cutting can be peeled off from the lower blade with almost no deformation.

[Brief description of drawings]

FIG. 1 is a front cross-sectional view of a pressing mechanism and a pressing mechanism according to an embodiment of the present invention.

FIG. 2 is an overall front view.

FIG. 3 is a partial cross-sectional rear view of the vicinity of the carriage.

4 is a cross-sectional view taken along the line II of FIG.

FIG. 5 is a schematic plan sectional view of the vicinity of a cutter and a lower blade.

6 is a sectional view taken along the line II-II of FIG.

FIG. 7 is a view taken along the line III-III in FIG.

[Explanation of symbols]

 14 ... Lower blade 31 ... Cutter 68 ... Pressing plate 82 ... Pressing mechanism 96 ... Peeling member 97 ... Pushing mechanism 98 ... Driving mechanism B ... Band-shaped member

Claims (2)

[Claims] 1. A linear lower blade installed immediately below the strip-shaped member and extending to intersect with the strip-shaped member, and by moving along the lower blade, the strip-shaped member cooperates with the lower blade at a cutting position. And a cutter that cuts almost in the width direction, a pressing plate that is installed just above the belt-shaped member and extends along the lower blade, and the pressing plate moves to press the belt-shaped member against the lower blade to move the belt-shaped member during cutting. A pressing mechanism that regulates, a thin plate-shaped peeling member that is provided immediately below the band-shaped member near the cutting position and is parallel to the lower blade, and when the pressing plate is separated from the band-shaped member immediately after cutting, remove the peeling member from the upper surface of the lower blade. By moving the peeling member between the strip-shaped member and the lower blade by moving the strip-shaped member in a direction substantially orthogonal to the longitudinal direction of the lower blade, and peeling the strip-shaped member adhered to the lower blade from the lower blade. Push Cutting apparatus of the belt-shaped member, characterized in that it comprises a structure, a. 2. The band-shaped member cutting device according to claim 1, further comprising a single driving mechanism for applying a driving force to both the pressing mechanism and the pushing mechanism.