JPH04128829U - rotary shear - Google Patents

Abstract

(57) [Summary] [Purpose] The aim was to prevent damage to the elastic lining applied to the anvil surface that the knife of the knife cylinder contacts. [Structure] A set of knife cylinders 2 having knives 3 spanning the entire width on the outer peripheral surface, an appropriate surface length that is equal to or narrower than half the width of the knife cylinder 2, and the outer periphery is lined with an elastic material. 2 with adjustable spacing covered with 21
It is characterized in that the set of receiving rolls 32a, 32b are disposed at right angles to or at a close angle to the travel path of the corrugated paperboard sheet 1.

Description

[Detailed explanation of the idea]

0001

[Industrial application field]

The present invention relates to a rotary shear applied to a corrugating machine.

0002

[Conventional technology]

Figures 4, 5, and 6 show a corrugated sheet cut across its entire width, and a corrugated cardboard sheet cut across its entire width. A rotary shear ( The schematic structure of Utility Model Application No. 57-196472) is shown. In FIG. 4, the knife cylinder 2 to which the knife 3 is fixed has both left and right shaft portions 2a, 2b is rotatably supported by the frames 22, 22' by bearings 7, 7'. ing. Further, a gear 14 is attached to the shaft portion 2a, and a gear 14 is mounted between the shaft portion 2a and the shaft portion 2c. is provided with an electromagnetic clutch 13 that can connect or release both shaft portions. Sara A V-pulley 12 is attached to the shaft portion 2c.

0003 20 indicates an anvil cylinder, whose outer peripheral surface is half of the circumference as shown in Figure 5. The entire width is covered with a soft elastic running 21, and the remaining half is covered with an anvil silicone. The areas near the left and right end surfaces of the cylinder 20 cover the entire width L of the anvil cylinder 20, and the center area covers the entire width L of the anvil cylinder 20. As shown in FIG. 5, the anvil cylinder 20 is covered by (L-l) in the width direction. A part of the cylinder 20 is continuously cut from both ends to the center. lacking. Further, in FIG. 4, the anvil cylinder 20 has both left and right shaft portions 20a. , 20b, the bearings 8, 8' allow the frames 22, 22' to rotate freely. It is supported by.

0004 Further, at the outer end of the shaft portion 20a, the shaft portion 20c and the shaft portion 20a can be connected or released. An electromagnetic clutch 24 is provided. The shaft portion 20c has a portion that meshes with the gear 14. A gear 15 is mounted at the position. Further, a V-pulley 30 is attached to the outer end of the shaft portion 20b. The shaft 27 The shaft 27 is rotatably supported on the frame 22' by a bearing 23. A V-pulley 28 is attached to the outer end of the V-pulley 28 in correspondence with the V-pulley 30. V-pulley 28 is driveably engaged with V-belt 29. Also The other end of the foot 27 is connected to the shaft of the indexing motor 25 so that it can be connected or released. An electromagnetic clutch 26 is provided.

[0005] Next, to explain the operation, in FIG. 4, the knife cylinder 2 turns on the clutch 13. When this happens, it is driven from the line shaft 9. Another cardboard box sent in succession If you want to completely cut the sheet 1 as shown in Figure 7, use the anvil cylinder 20. The surface on which the elastic lining 21 is wrapped over the entire width L (FIG. 5) of By the indexing motor 25, an electromagnetic clutch 26, a shaft 27, a V-pulley 28, It is indexed via the V belt 29 and V pulley 30, and the phase is adjusted so that it can contact the knife 3. match.

[0006] In addition, as shown in FIG. _n If you want to cut by /2, use the dimension l shown in Figure 5._nAnvil cylinder 2 corresponding to 0 phase, the knife 3 has the dimension l as before._nso that it touches the position corresponding to Indexing is performed by an indexing motor 25. In this way, only the dimensions necessary for cutting both ends are Insert the if 3 into the lining 21 of the anvil cylinder 20 and cut it. I can do that.

[0007] During the above indexing operation, both electromagnetic clutch 13 and electromagnetic clutch 24 are turned off. This prevents the knife cylinder 2 from rotating and prevents the anvil cylinder 20 from rotating. The rotation is not transmitted to the knife cylinder 2 via the gear 15 and the gear 14. stomach. When cutting the corrugated cardboard sheet 1, the electromagnetic clutch 13 and the electromagnetic clutch 24 are used. is turned on, and the knife cylinder 2 and the ambience are driven by the line shaft 9. The cylinders 20 rotate together and the cardboard sheet 1 is cut.

[0008] At this time, the electromagnetic clutch 26 is turned off and the index motor 25 is rotated. There isn't. Further, at the same time as the disconnection is completed, the electromagnetic clutch 13 is turned off, and the electromagnetic brake 4 6 stops the knife cylinder 2 and anvil cylinder 20 from rotating.

[0009]

[Problem that the idea aims to solve]

During the indexing operation, the knife cylinder and the electromagnetic clutch of the indexing motor shaft are both turned off, so the knife cylinder is not rotating. Therefore, in order to match the rotational phase with the knife cylinder during cutting after indexing, the anvil cylinder with a large moment of inertia (GD ² ) is accelerated from a stationary state at the same time as the knife cylinder starts rotating, and the anvil cylinder has a high moment of inertia (GD 2 ). (200 to 300 m/min) It is very difficult to achieve the same speed as the cardboard sheet traveling at the speed of the anvil cylinder due to the performance of the clutch and brake or from an economic point of view. This is done at a speed that can be reached (approximately 200 m/min). (There is a limit to the cutting speed.) Also, the amount of cut W-l _n /2 is determined at one fixed phase point on the circumference of the anvil cylinder, so the knife will move at the same phase every time it rotates. Since the cardboard sheet is cut at the lining, the life of the lining will be shortened. Furthermore, since the lining must be attached to the anvil cylinder while adjusting the phase, the lining cannot be easily replaced.

0010

[Means to solve the problem]

The present invention was proposed in order to eliminate the above-mentioned conventional drawbacks, and is based on a set of knife knife cylinder and an appropriate surface length that is equal to or narrower than half the width of this knife cylinder. Two sets of receiving rolls are provided, the outer periphery of which is coated with an elastic lining, and these It is possible to completely cut (separate) the corrugated cardboard sheet by adjusting the spacing between the receiving rolls. The purpose is to provide a rotary shear that can sometimes perform partial cutting.

[0011]

[Effect]

To achieve this purpose, the two sets of receiving rolls are rotated by a motor in the axial direction on a support shaft, and are moved by a guide that is screwed into each screw of a screw shaft having a pair of screws with opposite hands. and adjust the interval between these two sets of receiving rolls. When this interval l _n is 0, complete cutting is achieved, and when it is an arbitrary value l _n , the amount of cutting from both width edges of the corrugated board sheet is W-l _n /2. Furthermore, since there is no need to phase match the cutting position (in the rotational direction) with the knife cylinder, the receiving roll speed can be set to the machine speed after the interval is adjusted. Therefore, when cutting corrugated cardboard sheets, only the knife cylinder with a GD ² of not less than the stationary state can be brought to the same speed as the machine within a limited short period of time, and the speed can be stopped immediately after cutting. The performance is enough. That is, the cutting speed can follow the machine limit speed.

0012

【Example】

The schematic structure of the rotary shear according to the present invention is shown in FIGS. 1, 2, and 3. In Figure 1 , knife cylinder 2, knife 3, electromagnetic clutch 13, V pulley 12, V The bolt 11, V-pulley 10 and line shaft 9 are the same as in FIG. 4 except for the gear 14. It has the same structure. In addition, the knife cylinder 2 has both left and right shaft portions 2a and 2b. is rotatably supported by the frames 22, 22' via bearings 7, 7'. This is also the same as in FIG. 32a and 32b are frames 22 and 22', respectively. The outer peripheral surface of the receiving roll provided on the side is covered with a lining 21 made of soft elastic material. The support shaft 31 is configured to be movable in the axial direction and engaged in the rotational direction of the support shaft 31. Supported. Both left and right shaft portions 31a, 31b of the support shaft 31 are bearings 8, 8'. It is rotatably supported by the frames 22, 22'. Also, the outside of the shaft portion 31a An electromagnetic clutch 24 is provided at the end to connect or release the shaft portion 31c and the shaft portion 31a. is provided. A V-pulley 33 is installed on the shaft portion 31c, and the line shaft It is driven by a V-pulley 34 of the seat 9 via a V-belt 35.

[0013] Next, the ring grooves 36a, 36b provided at the ends of the receiving rolls 32a, 32b are The shift pieces 45a and 45b of the guides 37a and 37b are fitted into the respective guides 37a and 37b. , these shift pieces 45a and 45b have opposite sides machined on the screw shaft 38, respectively. It is screwed into the threaded portions 39a and 39b on the hand. Both left and right ends 3 of this screw shaft 38 8a and 38b are rotatable on frames 22 and 22' by bearings 39 and 39'. is supported by Further, a V-pulley 40 is fixed to the frame 22 on the shaft portion 38a. The V-pulley 43 on the shaft of the motor 42 is mounted on the bracket 41 that is attached to the It is engaged so that it can be driven by a V-belt 44.

[0014] Also, as shown in FIG. 2, the knife cylinder 2 is located at a fixed position on the frames 22, 22' The lining 21 made of soft elastic material is rotated at A support that can move the anvil cylinder 4 and the support shafts 31 of the receiving rolls 32a and 32b. The supports supported by the frames 22, 22' in FIG. Like the holding shaft 31, these cylinders 4 and the supporting shaft 31 are supported rotatably.

Next, the operation will be explained. In FIG. 1, the knife cylinder 2 is driven from the line shaft 9 when the clutch 13 is turned on, as in FIG. 4. Further, since the support shaft 31 is driven by the V-pulley 34 when the clutch 24 is turned on, the receiving rolls 32a and 32b also rotate at the same speed as the machine speed. As shown in FIG. 8, when it is desired to cut both end faces of the corrugated cardboard sheet 1 by an arbitrary dimension W-l _n /2, the distance between the receiving rolls 32a and 32b is changed by the dimension l _n shown in FIG. , 37b is opened via the screw shaft 38 by the moving motor 42. Therefore, the corrugated cardboard sheet is cut only at the portion where the knife of the knife cylinder 2 bites into the receiving rolls 32a, 32b. In FIG. 1, it is possible to perform notch cutting, but complete cutting is not possible. Therefore, when complete cutting is to be performed as shown in FIG. 7, the subframes 6, 6' are moved to the positions indicated by the dashed lines in FIG. 2 and placed on the anvil cylinder 4 directly below the knife cylinder 2. The receiving rolls 32a, 32b and the anvil cylinder 4, which are rotating together with the support shaft 31, are rotating at the same speed as the machine speed via the V pulley 34 of the line shaft 9, etc. Further, the anvil cylinder 4 may be placed on either side with respect to the receiving rolls 32a, 32b in the direction of movement of the corrugated board sheet, and the receiving rolls 32a, 32b and the anvil cylinder 4 are also used for conveying the sheet, but in this case, the driving is By means of a drive, not shown.

[0016] The above method involves cutting the corrugated sheet completely across its entire width or cutting the sheet to any desired dimension. This is an explanation of the case where both ends are cut, but in order to cut by the above-mentioned arbitrary dimension, the receiving roll 32 is When moving a, 32b, the clutch 24 is turned off and the receiving rolls 32a, 32 b stops rotating. Therefore, after moving, turn on the clutch 24 and connect the V-pulley as described above. At step 34, the speed of the receiving roll 32 is set to the machine speed.

Next, FIG. 3 shows how to cut a corrugated sheet over the entire width without replacing the anvil cylinder 4 and the receiving rolls 32a, 32b, and cutting both ends of the sheet by an arbitrary dimension. The structure differs from that in Fig. 1 in that the interval W _o between the frames 22 and 22' is widened, the surface lengths W _{1 and} W ₂ of the receiving rolls 32a and 32b are increased, and the range of movement is expanded. As a result, the distance l _n between the receiving rolls 32a and 32b can be changed from Omm to the maximum sheet width, making it possible to perform the full-width cutting and notch cutting as described above. In this case, W ₁ +W ₂ ≧corrugated paper sheet width W, and the ring grooves 36a, 36b of the receiving rolls 32a, 32b are provided on the frames 22, 22', respectively.

[0018]

[Effect of the idea]

In this way, according to the present invention, a pair of knife cylinders having a knife spanning the entire width on the outer peripheral surface and a knife cylinder having a width equal to half the width of the knife cylinder are arranged at an angle perpendicular to or close to the running path of a corrugated sheet produced by a corrugating machine. Corrugated cardboard sheets are continuously fed because they are equipped with two sets of receiving rolls having an appropriate surface length narrower than this and whose outer periphery is covered with an elastic lining and whose spacing can be adjusted freely. It is possible to completely cut the entire width of the corrugated cardboard sheet as shown in Fig. 7, or it is possible to cut the width of both ends of the corrugated cardboard sheet by an arbitrary length W-l _n /2 as shown in Fig. 8. By constantly rotating the blade, high-speed cutting is possible, and since it does not matter which phase of the receiving roll the knife is in, the life of the lining of the receiving roll is longer than before, and the lining can be easily replaced.

[Brief explanation of drawings]

FIG. 1 is a front sectional view showing a first embodiment of the present invention.

FIG. 2 is a side view showing a second embodiment of the present invention.

FIG. 3 is a front sectional view showing a third embodiment of the present invention.

FIG. 4 is a front sectional view showing a conventional example.

FIG. 5 is a perspective view of the anvil cylinder in FIG. 4;

FIG. 6 is a sectional view taken along line AA in FIG. 5;

FIG. 7 is a perspective view of the corrugated cardboard sheet in a cut state.

FIG. 8 is a perspective view of a corrugated cardboard sheet with a portion cut away.

[Explanation of symbols]

1 Cardboard sheet 2 Knife cylinder 3 Knife 21 Lining 32a Receiving roll 32b Receiving roll

Claims (2)

[Scope of utility model registration request] [Claim 1] A knife having a knife extending the entire width on the outer peripheral surface.
A set of knife cylinders and two sets of receiving rolls having an appropriate surface length that is equal to or narrower than half the width of the knife cylinder and whose outer periphery is covered with an elastic lining and whose spacing can be adjusted freely are assembled into a corrugated cardboard sheet. A rotary shear characterized in that the rotary shear is arranged at right angles to or at an angle close to the travel path of the rotary shear. 2. A set of anvil cylinders lined with an elastic body serving as receivers for the knives are provided in parallel with the two sets of receiving rolls, and the positions of the anvil cylinders and the two sets of receiving rolls are adjusted to match the positions of the two sets of receiving rolls. 2. The rotary shear according to claim 1, wherein the rotary shear is switchable relative to the cylinder.