JP7556568B2 - Slip Sheet Bending Machine - Google Patents

Description

Application of Article 30, Paragraph 2 of the Patent Act (1) ▲1▼ Test date January 11, 2022 ▲2▼ Test location Ueda Paper Machinery Co., Ltd. (160 Maruko Shinden, Suruga-ku, Shizuoka City, Shizuoka Prefecture) ▲3▼ Visitor Matsumoto Kogyosho Co., Ltd. (466 Mawarimachi, Kasugai City, Aichi Prefecture) ▲4▼ Discloser Ueda Paper Machinery Co., Ltd. (160 Maruko Shinden, Suruga-ku, Shizuoka City, Shizuoka Prefecture) ▲5▼ Content of disclosed invention Ueda Paper Machinery Co., Ltd. test-ran the slip sheet folding machine invented by Ueda Tsukasa and Aoyama Hiroki at Ueda Paper Machinery Co., Ltd., and this was observed by Matsumoto Naoyuki and Osawa Yusuke of Matsumoto Kogyosho Co., Ltd. (2) ▲1▼ Test date January 25, 2022 ▲2▼ Test location Ueda Paper Machinery Co., Ltd. (160 Maruko Shinden, Suruga-ku, Shizuoka City, Shizuoka Prefecture) ▲3▼ Visitor Matsumoto Kogyosho Co., Ltd. (466 Mawarimachi, Kasugai City, Aichi Prefecture) ▲4▼ Discloser Ueda Paper Machinery Co., Ltd. (160 Maruko Shinden, Suruga-ku, Shizuoka City, Shizuoka Prefecture) ▲5▼ Details of disclosed invention Ueda Paper Machinery Co., Ltd. test-ran the slip sheet folding machine invented by Ueda Tsukasa and Aoyama Hiroki at Ueda Paper Machinery Co., Ltd., and it was observed by Matsumoto Naoyuki and Osawa Yusuke of Matsumoto Kogyosho Co., Ltd. (3) ▲1▼ Date of sale: February 26, 2022 ▲2▼ Location of sale: Matsumoto Kogyosho Co., Ltd. (466 Mawarimachi, Kasugai City, Aichi Prefecture) ▲3▼ Discloser: Ueda Paper Machinery Co., Ltd. (160 Maruko Shinden, Suruga Ward, Shizuoka City, Shizuoka Prefecture) ▲4▼ Details of disclosed invention: Ueda Paper Machinery Co., Ltd. sold the slip sheet folding machine invented by Ueda Tsukasa and Aoyama Hiroki to Matsumoto Kogyosho Co., Ltd.

The present invention relates to a slip sheet folding machine that folds cardboard sheets that have been processed for use as slip sheets, and in particular to a machine that can efficiently fold multiple cardboard sheets into slip sheets and is designed to stably ensure the bending angle, a necessary condition for slip sheets.

In loading and unloading operations using forklifts, a frame structure or a trapezoidal pallet made of wooden boards and timber or the like having a space for inserting the forks of the forklift, as shown in Figures 1(a) and 1(b) of Patent Document 1 listed below, has traditionally been used.
However, because such frame-structured or trapezoidal pallets have a large height due to their structure, there is a limit to the number of layers that can be stacked in a warehouse when not in use, and a large storage space is required within the warehouse.

Against this background, so-called "slip sheets" made of resin, for example, have been developed, as described in Patent Document 2 below. With this type of slip sheet, the height dimension required when stacking them is the sheet thickness, so more slip sheets can be stored in a limited storage space, and manufacturing costs are low.

This type of slip sheet can also be made from cardboard sheets. In this case, a cardboard sheet that has been processed for slip sheets is folded into a slip sheet using a known cardboard sheet folding machine.

Utility Model Publication No. 51-646 JP 2016-53223 A

However, the above conventional configuration has the following problems.
In other words, the work of folding cardboard sheets processed for slip sheets using a known cardboard sheet folding machine relies almost entirely on the manual labor of workers, who must feed the cardboard sheets one by one into the cardboard sheet folding machine, which poses the problem of requiring a lot of labor and a long time for the work.
Furthermore, there was also the problem that the bending angle, which is a necessary condition for slip sheets, could not be stably secured when folding using a conventional cardboard sheet folding machine.

The present invention was made based on these points, and its purpose is to provide a slip sheet folding machine that can efficiently fold multiple cardboard sheets into slip sheets and can stably ensure the bending angle, which is a necessary condition for slip sheets.

In order to achieve the above object, a slip sheet folding machine according to claim 1 of the present invention comprises a conveying means for conveying a cardboard sheet, and a folding means for folding the leading end of the cardboard sheet conveyed by the conveying means to form a slip sheet, the folding means comprising a lower guide for supporting the cardboard sheet conveyed by the conveying means from below, a holder installed above the lower guide so as to be rotatable about a pivot point, a stopper portion attached to the holder against which the leading end of the cardboard sheet conveyed by the conveying means abuts, and a stopper portion attached to the holder abuts at a predetermined position on the leading end of the cardboard sheet. and a pull-up cylinder mechanism connected to the holder for rotating the holder around the pivot point, wherein when the leading edge of the cardboard sheet abuts against the stopper portion, the holder is urged to rotate in one direction around the pivot point, and as the cardboard sheet is further transported, the holder is further urged to rotate in one direction, the claw abuts against a predetermined position on the cardboard sheet, and as the cardboard sheet is further transported, the holder is further urged to rotate in one direction, and the holder folds the cardboard sheet at the abutment position as a crease .
Furthermore, the slip sheet folding machine according to claim 2 is a slip sheet folding machine according to claim 1, characterized in that the conveying means is equipped with a pair of conveying rollers which clamp and convey the cardboard sheet, the leading end of which has been folded by the folding means, in a folded state .
Furthermore, the slip sheet folding machine according to claim 3 is a slip sheet folding machine according to claim 1 or 2, characterized in that the holder is equipped with a support member for supporting the leading end of the cardboard sheet which abuts against the stopper portion, the claw corresponds to a punch, and the lower guide and the support member correspond to a die .
Furthermore, the slip sheet folding machine according to claim 4 is a slip sheet folding machine according to claim 3, characterized in that the support member has an upwardly convex arc shape, and the leading end of the cardboard sheet is configured to gradually move away from the support member when the folding operation is completed .
Furthermore, the slip sheet folding machine according to claim 5 is a slip sheet folding machine according to claim 1 or 2 , characterized in that the pull-up cylinder mechanism rotates the holder in the other direction opposite to the one direction for a predetermined period of time after the leading edge of the cardboard sheet abuts against the stopper portion, thereby applying a load to the cardboard sheet .
Furthermore, the slip sheet folding machine according to claim 6 is a slip sheet folding machine according to claim 4 , characterized in that the pull-up cylinder mechanism applies a load for a predetermined period of time and then releases the load when the tip of the cardboard sheet has been folded by a predetermined angle, and at the same time, the pull-up cylinder mechanism urges the holder to rotate in the one direction .
Furthermore, the slip sheet folding machine according to claim 7 is a slip sheet folding machine according to claim 1 or 2 , characterized in that the pull-up cylinder mechanism is installed on each of the left and right sides of the holder in the width direction .
Furthermore, the slip sheet folding machine according to claim 8 is a slip sheet folding machine as described in claim 1 or claim 2 , wherein a support rod is installed so as to be swingable around one end, the pivot point of the holder is installed at the other end of the support rod, the pull-up cylinder mechanism is installed so as to be swingable around the pivot point, and a lift cylinder mechanism is installed, and when the holder which is biased to rotate in one direction is returned in the other direction, the support rod is swung by the lift cylinder mechanism to raise the position of the pivot center of the holder .

As described above, the slip sheet folding machine according to claim 1 of the present invention is configured with a conveying means for conveying the corrugated cardboard sheet processed for slip sheets and a folding means for folding the leading end of the corrugated cardboard sheet to make a slip sheet, so that the corrugated cardboard sheet can be folded without stopping, and a large number of corrugated cardboard sheets can be efficiently folded to make a slip sheet. Also, the bending angle, which is a necessary condition for a slip sheet, can be stably secured.
According to a slip sheet folding machine according to claim 2, in the slip sheet folding machine according to claim 1, the folding means comprises a lower guide for supporting from below the cardboard sheet conveyed by the conveying means, a holder installed on the upper side of the lower guide so as to be rotatable about a pivot point, a stopper portion installed on the holder against which the leading edge of the cardboard sheet abuts, a claw installed on the holder abuts at a predetermined position on the leading edge of the cardboard sheet, and a pull-up cylinder mechanism for rotating the holder about the pivot point, When the tip of the claw abuts against the stopper portion, the holder is urged to rotate in one direction around the pivot point, and as the cardboard sheet is further transported, the holder is urged to rotate further in one direction so that the claw abuts against a predetermined position on the tip of the cardboard sheet, and as the cardboard sheet is further transported, the holder is urged to rotate further in one direction so that the tip of the cardboard sheet is folded with the abutment position of the claw as a crease, so that a large number of cardboard sheets can be efficiently folded into slip sheets.
In addition, according to the slip sheet folding machine of claim 3, in the slip sheet folding machine of claim 2, the conveying means is equipped with a pair of conveying rollers that clamp and convey the cardboard sheet folded by the folding means in a folded state, thereby ensuring reliable folding.
In addition, according to the slip sheet folding machine of claim 4, in the slip sheet folding machine described in claim 2, a support member is installed on the holder to support the leading end of the cardboard sheet that abuts against the stopper portion, and the claw corresponds to the punch, and the lower guide and this support member correspond to the die, thereby ensuring reliable folding.
In addition, the slip sheet folding machine according to claim 5 is a slip sheet folding machine described in claim 4, in which the support member has an upwardly convex arc shape, and the leading end of the cardboard sheet is structured so that it gradually deviates from the support member when the folding operation is completed.
In addition, according to the slip sheet folding machine of claim 6, in the slip sheet folding machine of claim 2, the pull-up cylinder mechanism applies a load by rotating the holder in the other direction opposite to the one direction for a predetermined period of time after the leading end of the cardboard sheet abuts the stopper portion, thereby ensuring reliable folding.
In addition, according to the slip sheet folding machine of claim 7, in the slip sheet folding machine of claim 6, the pull-up cylinder mechanism applies a load for a predetermined period of time and then releases the load when the tip of the cardboard sheet is folded by a predetermined angle, and at the same time, the pull-up cylinder mechanism urges the holder to rotate in the one direction, thereby ensuring reliable folding.
In addition, according to the slip sheet folding machine of claim 8, in the slip sheet folding machine of claim 2, the pull-up cylinder mechanism is installed on each side of the width direction of the holder, so that the folding operation can be performed in a balanced manner on the left and right.
In addition, according to the slip sheet folding machine of claim 9, in the slip sheet folding machine described in claim 2, the support rod has a pivot point for the holder at one end and a swingable pivot point at the other end, and a lift cylinder mechanism is installed, and when the holder, which is urged to rotate in one direction, is returned in the other direction, the support rod is swung by the lift cylinder mechanism, and the position of the pivot point of the holder is raised, so that contact between the claw and the lower guide can be prevented when the holder is returned in the other direction.

FIG. 1 is a side view showing an embodiment of the present invention, illustrating a slip sheet in use. FIG. 1 is a perspective view showing a slip sheet according to an embodiment of the present invention. FIG. 1 is a left side view showing a slip sheet folding machine according to an embodiment of the present invention. FIG. 1 is a front view of a slip sheet folding machine according to an embodiment of the present invention. FIG. 1 is a plan view showing a slip sheet folding machine according to an embodiment of the present invention. FIG. 1 is a perspective view showing a main portion of a slip sheet folding machine according to an embodiment of the present invention. FIG. 2 is a right side view showing a roller drive unit of a slip sheet folding machine according to an embodiment of the present invention. FIG. 1 is a plan view showing a roller drive section of a slip sheet folding machine according to an embodiment of the present invention. FIG. 2 is a right side view showing a roller drive transmission mechanism of a slip sheet folding machine according to an embodiment of the present invention. FIG. 10 is a cross-sectional view of the roller drive transmission mechanism of the slip sheet folding machine according to an embodiment of the present invention taken along line XX in FIG. FIG. 10 is a cross-sectional view taken along the line XI-XI in FIG. 9 showing a roller drive transmission mechanism of a slip sheet folding machine according to an embodiment of the present invention. FIG. 10 is a cross-sectional view taken along line XII-XII in FIG. 9 showing a roller drive transmission mechanism of a slip sheet folding machine according to an embodiment of the present invention. FIG. 10 is a cross-sectional view taken along line XIII-XIII in FIG. 9 showing a roller drive transmission mechanism of a slip sheet folding machine according to an embodiment of the present invention. FIG. 1 is a side view showing the main parts of a slip sheet folding machine showing the folding action in sequence according to one embodiment of the present invention. FIG. 1 is a side view showing the main parts of a slip sheet folding machine showing the folding action in sequence according to one embodiment of the present invention. FIG. 1 is a side view showing the main parts of a slip sheet folding machine showing the folding action in sequence according to one embodiment of the present invention. FIG. 1 is a side view showing the main parts of a slip sheet folding machine showing the folding action in sequence according to one embodiment of the present invention. FIG. 1 is a side view showing the main parts of a slip sheet folding machine showing the folding action in sequence according to one embodiment of the present invention. FIG. 1 is a side view showing the main parts of a slip sheet folding machine showing the folding action in sequence according to one embodiment of the present invention. FIG. 1 is a side view showing the main parts of a slip sheet folding machine showing the folding action in sequence according to one embodiment of the present invention. FIG. 1 is a side view showing the main parts of a slip sheet folding machine showing the folding action in sequence according to one embodiment of the present invention. FIG. 1 is a side view showing the main parts of a slip sheet folding machine showing the folding action in sequence according to one embodiment of the present invention. FIG. 1 is a side view showing the main parts of a slip sheet folding machine showing the folding action in sequence according to one embodiment of the present invention. FIG. 1 is a side view showing the main parts of a slip sheet folding machine showing the folding action in sequence according to one embodiment of the present invention. FIG. 1 is a side view showing the main parts of a slip sheet folding machine showing the folding action in sequence according to one embodiment of the present invention. FIG. 1 is a side view showing the main parts of a slip sheet folding machine showing the folding action in sequence according to one embodiment of the present invention. FIG. 1 is a side view showing the main parts of a slip sheet folding machine showing the folding action in sequence according to one embodiment of the present invention. FIG. 1 is a side view showing the main parts of a slip sheet folding machine showing the folding action in sequence according to one embodiment of the present invention. FIG. 1 is a side view showing the main parts of a slip sheet folding machine showing the folding action in sequence according to one embodiment of the present invention. FIG. 1 is a side view showing the main parts of a slip sheet folding machine showing the folding action in sequence according to one embodiment of the present invention. FIG. 1 is a side view showing the main parts of a slip sheet folding machine showing the folding action in sequence according to one embodiment of the present invention. FIG. 1 is a side view showing the main parts of a slip sheet folding machine showing the folding action in sequence according to one embodiment of the present invention. FIG. 1 is a side view showing the main parts of a slip sheet folding machine showing the folding action in sequence according to one embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A slipsheet folder according to one embodiment of the present invention will now be described with reference to FIGS.
In the following description, the structure and use of the slip sheet will be described first with reference to Figures 1 and 2. Next, the overall structure of the slip sheet folding machine according to the present embodiment will be outlined with reference to Figures 3 to 6.

Next, the configuration of the main parts of the slip sheet folding machine according to this embodiment will be specifically explained based on Figures 3 to 13, and the folding action of the slip sheet folding machine according to this embodiment will be explained based on Figures 14 to 33.
Finally, reference will be made to another embodiment of a slipsheet folder having a partially different configuration from the above embodiment.

(1) Structure and usage of slip sheet (see Figures 1 and 2)
As shown in Figures 1 and 2, the slip sheet 1 is used when cargo handling work is performed using a forklift 3 or the like. Specifically, it is basically composed of a sheet body 5 on which cargo W is placed, a folded piece 9 formed by forming a crease 7 on one end 13 of the sheet body 5 and folding it at a predetermined angle α, and a reinforcing piece 11 that straddles the crease 7 and is attached to one end 13 of the sheet body 5 and the folded piece 9.

When using the slip sheet 1, as shown in FIG. 1, the slip sheet 1 is laid on the floor F with the folded portion 9 facing up, and the luggage W is placed thereon.
Next, a forklift 3 approaches from the side where the folded piece 9 is formed, grips the folded piece 9 with a push-pull attachment 17, and pulls the slip sheet 1 forward onto the forks 19.

The push-pull attachment 17 is a forklift attachment mechanism for handling thin sheets such as slip sheets.

After this, just like with conventional wooden or plastic pallets with a frame structure and trapezoidal shape, the forks 17 are raised to lift the cargo W and slip sheet 1, and the cargo is then carried to the desired location to carry out the specified loading and unloading operation.

(2) Overview of the overall configuration of a slip sheet folding machine (see Figures 3 to 6)
The slip sheet folding machine 21 of the present invention is a folding machine for the cardboard sheet A processed for the above-mentioned slip sheet 1, and specifically, is basically composed of a conveying means 23 that conveys the cardboard sheet A from the entrance side (right side in Figure 3) to the exit side (left side in Figure 3), and a folding means 25 provided midway along this conveying means 23.

First, the configuration of the conveying means 23 will be described.
As shown in Fig. 3, there is a support stand 29, on which side frames 31, 31, one on each side, are installed extending along the conveying direction Y. Two roller support brackets 33, 33, one on each side, are attached to the side frames 31, 31. A conveying roller 35 is rotatably installed between the left and right roller support brackets 33, 33. The roller support brackets 33, 33 and the conveying roller 35 are configured to be movable within a predetermined range along the conveying direction Y. The conveying roller 35 is connected to a drive motor (not shown) via a clutch (not shown).

Further, a fall prevention roller 36 is rotatably disposed in front of the transport roller 35 (on the left side in FIG. 3).
In addition, four casters 37 and four anchor bolts 39 are attached to the lower part of the support stand 29, for example.

Two left and right side plates 41, 41 are erected on the support stand 29 in front of the fall prevention roller 36 (left side in FIG. 3). Between the left and right side plates 41, 41, for example, four lower drive rollers 43A, 43B, 43C, 43D are spanned, three sets of upper drive roller units 45A, 45B, 45C are arranged to face and correspond from above to the three lower drive rollers 43A, 43B, 43C, excluding the lower drive roller 43D on the upstream side in the conveying direction Y, a roller drive unit 51 that imparts power to the four lower drive rollers 43A, 43B, 43C, 43D, and a roller drive transmission mechanism 53 that transmits the power of the roller drive unit 51 to the four lower drive rollers 43A, 43B, 43C, 43D. In addition, a front ruler 46 is provided on the lower drive roller 43D.
14, a number of cardboard sheets A are stacked and arranged on the conveying roller 35 and the lower drive roller 43D. The leading ends 15 of the number of cardboard sheets A are brought into contact with the front ruler 46. Starting from the lowest cardboard sheet A, the sheets are conveyed in the Y direction successively at predetermined timings through the gap between the front ruler 46 and the lower drive roller 43D.

Also provided is, as an example, a control device 57 that controls each section, and sensors 59A and 59B that detect a predetermined position O and another predetermined position P on the cardboard sheet A. The sensors 59A and 59B are, for example, photoelectric sensors.

As shown in Figures 3 and 5, in front of the lower drive roller 43A and the drive roller unit 45A (on the left side in Figure 3), a horizontal support table 63 extending from the support stand 29 toward downstream in the conveying direction Y is installed on the vertical frame 61. The height of this horizontal support table 63 is adjustable.

(3) Configuration of Main Parts of Slip Sheet Bending Machine (See Figures 3 to 14)
Next, the configuration of the folding means 25, which is a main part of the slip sheet folding machine 21, and the configurations of the roller drive unit 51 and the roller drive transmission mechanism 53 will be specifically described.
(A) Configuration of the folding means 25 (see FIGS. 3 to 6 and 14)
The folding means 25 includes a holder 67 rotatably installed around a pivot point C, a stopper portion 69 against which the tip 15 abuts, a claw 71 that abuts against a predetermined position of the tip 13 (the position where the fold 7 is formed), and a pull-up cylinder mechanism 73 connected to the holder 67.

When the leading end 15 of the cardboard sheet A being conveyed by the conveying means 23 comes into contact with the stopper portion 69, the holder 67 is forced to rotate in one direction (clockwise in FIG. 14) around the pivot point C, and as the cardboard sheet A is further conveyed, the holder 67 is further forced to rotate in one direction, the claw 71 comes into contact with a predetermined position of the leading end 13, and as the cardboard sheet A is further conveyed, the holder 67 is further forced to rotate in one direction, and the leading end 13 is folded at the contact position of the claw 71 (crease 7).

The support rod 79 is, for example, a square pipe member having flanges on both ends in the width direction X.
The side plates 77, 77 are members having a side shape as shown in Figures 6 to 14, for example.
As an example, the claw 71 is a generally flat plate-shaped member having approximately the same length as the length of the support rod 79 in the width direction X. The tip of the claw 71 is bent downward at approximately 45°, and the tip is cut diagonally to form a claw portion 85. The portion extending horizontally from the bent portion toward the support rod 79 forms an action position setting flat plate portion 87 that determines the action position of the claw portion 85. The base of the action position setting flat plate portion 87 is attached to the lower part of the support rod 79.
The stopper portion 69 is, for example, a flat plate member having a rectangular cross section. A plurality of sets of the stopper portion 69 are attached to the lower surface of the operating position setting flat plate portion 87 between the left and right side plates 77, 77 at appropriate intervals.
The support members 75 are, for example, thin plates with curved tips. A plurality of support members 75 are attached to the lower surface of the stopper portion 69 in the same manner as the stopper portion 69 .

As an example, the holder 67 is installed between the first lower drive roller 43A and upper drive roller unit 45A and the second lower drive roller 43B and upper drive roller unit 45B from downstream in the transport direction Y. The holder 67 is composed of a support rod 79, side plates 77, 77, a claw 71, a stopper portion 69, and a support member 75, and is provided with a pivot point B that is rotatably connected to the tip of the piston rod 81, and a pivot point C that is rotatably connected to the tip of the support rod 83.

As shown in FIG. 4, the upper drive roller unit 45A has eight disk-shaped drive rollers 49 attached at appropriate intervals to a rotating shaft 47 that is horizontally suspended between the left and right side plates 41, 41. The upper drive roller unit 45B and the upper drive roller unit 45C are similar.

The pull-up cylinder mechanism 73 is composed of a cylinder body 80 connected to the side plate 41 via a swing fulcrum D, and a piston rod 81 extending axially from the cylinder body 80 so as to be freely movable, and one unit is installed on each side of the holder 67 in the width direction X.
A support rod 83 is provided below the pull-up cylinder mechanism 73 and connected to the side plate 41 via a swing fulcrum E. The support rods 83 are also provided on each of the left and right sides of the holder 67 in the width direction X.

As an example, the lift cylinder mechanism 84 is installed below the support rod 83. The lift cylinder mechanism 84 is composed of a cylinder body 86 and a piston rod 88, and one is installed on each side of the holder 67 in the width direction X.
In addition, the tip of the piston rod 88 is located at a distance where it can come into contact with the support rod 83. When the lift cylinder mechanism 84 is in the Push state, it lifts the support rod 83 clockwise in FIG.

The lower guide 74 is disposed so as to support from below the conveyed cardboard sheet A. The upper guide 94 is disposed above the lower guide 74.
In addition, the upstream portions of the lower guide 74 and the upper guide 94 in the conveying direction Y are bent so as to expand vertically, making it easier for the cardboard sheet A to enter between the lower guide 74 and the upper guide 94.

In this embodiment, the claw 71 functions as a punch, and the lower guide 74 and the support member 75 function as a die. The cross-sectional shape of the support member 75 is an upwardly convex arc shape, and the tip 13 is designed to gradually deviate from the support member 75.

(B) Configuration of the roller drive unit and roller drive transmission mechanism (see Figures 7 to 13)
Next, the roller drive unit 51 and the roller drive transmission mechanism 53 will be described.
As an example, as shown in Figures 7 and 8, the roller drive unit 51 is composed of two roller drive units: a first roller drive unit 51A that drives the first lower drive roller 43D from the upstream side in the conveying direction Y, and a second roller drive unit 51B that drives the three lower drive rollers 43C, 43B, 43A that are the second, third, and fourth from the upstream side in the conveying direction Y.

As an example, the first roller driving section 51A is composed of a gear motor M1, a coupling 95 and an electromagnetic clutch brake 97 which are connected in series. A first driving sprocket 99 is attached to the output shaft of the electromagnetic clutch brake 97.
The second roller driving section 51B is, for example, composed only of a gear motor M2, and a second driving sprocket 101 having two sprockets 101A and 101B integrally formed therewith is attached to the output shaft of the gear motor M2.

As an example, as shown in Figures 9 to 13, the roller drive transmission mechanism 53 is composed of a first roller drive transmission mechanism 53A for transmitting power from the upstream side in the conveying direction Y to the first lower drive roller 43D, and a second roller drive transmission mechanism 53B for transmitting power to the three lower drive rollers 43C, 43B, and 43A that are the second, third, and fourth from the upstream side in the conveying direction Y.

As an example, the first chain transmission mechanism 108 is composed of a first driving sprocket 99, a first driven sprocket 103, a first chain 105 wound around the first driving sprocket 99 and the first driven sprocket 103, and two sprocket idlers 107, 107 that adjust the tension of the first chain 105.
The first roller drive transmission mechanism 53A has a first chain transmission mechanism 108.

As an example, the second chain transmission mechanism 112 is composed of a sprocket 101A in front of the second driving sprocket 101, a second driven sprocket 109, a second chain 111 wound around the sprocket 101A and the second driven sprocket 109, and two sprocket idlers 107, 107 that adjust the tension of the second chain 111.
The second roller drive transmission mechanism 53B has a second chain transmission mechanism 112 .

As an example, the third chain transmission mechanism 116 is composed of a rear sprocket 101B of the second driving sprocket 101, a rear sprocket 113B of the third driven sprocket 113, a third chain 115 wound around sprocket 101B and sprocket 113B, and two sprocket idlers 107, 107 that adjust the tension of the third chain 115.
The second roller drive transmission mechanism 53B has a third chain transmission mechanism 116 .

As an example, the fourth chain transmission mechanism 120 is composed of a sprocket 113A in front of the third driven sprocket 113, a fourth driven sprocket 117, a fourth chain 119 wound around the sprocket 113A and the fourth driven sprocket 117, and a single sprocket idler 107 that adjusts the tension of the fourth chain 119.
The second roller drive transmission mechanism 53B has a fourth chain transmission mechanism 120.

The second gear transmission mechanism 124 is, for example, composed of a second drive gear 121 and a second driven gear 123 which mesh with each other. The second drive gear 121 is attached to the lower drive roller 43C, and the second driven gear 123 is attached to the rotation shaft 47 of the upper drive roller unit 45C.
The second roller drive transmission mechanism 53B has a second gear transmission mechanism 124 .

The third gear transmission mechanism 128 is composed of, for example, a third drive gear 125 and a third driven gear 127 which mesh with each other. The third drive gear 125 is attached to the lower drive roller 43B, and the third driven gear 127 is attached to the rotation shaft 47 of the upper drive roller unit 45B.
The second roller drive transmission mechanism 53B has a third gear transmission mechanism 128.

As an example, the fourth gear transmission mechanism 132 is composed of a fourth drive gear 129 and a fourth driven gear 131 which mesh with each other. The fourth drive gear 129 is attached to the lower drive roller 43A, and the fourth driven gear 131 is attached to the rotation shaft 47 of the upper drive roller unit 45A.
The second roller drive transmission mechanism 53B has a fourth gear transmission mechanism 132 .

Compared to the first roller drive transmission mechanism 53A, the second roller drive transmission mechanism 53B has a reduction ratio between gear motor M1 and gear motor M2, and the number of teeth of the first drive sprocket 99 and second drive sprocket 101, the first driven sprocket 103 and second driven sprocket 109, and the third driven sprocket 113, which are adjusted to increase the rotation speed. As a result, slackness in the cardboard sheet A transported between the lower drive roller 43D and the lower drive roller 43C can be prevented.

(4) Folding action of the cardboard sheet A (see Figures 3, 14 to 33)
Next, the folding action of the cardboard sheet A processed for the slip sheet 1 will be described.

The cardboard sheets A are stacked and placed on the conveying rollers 35 and the lower drive rollers 43D of the conveying means 23. As shown in FIG.
When an operation switch (not shown) is turned ON, the gear motors M1 and M2 start operating.
Next, when a foot switch (not shown) is turned on, a series of folding operations is started. First, the clutch for the conveying roller 35, the clutch of the electromagnetic clutch brake 97, is turned on, and conveying begins. The sheets are conveyed one by one in the conveying direction Y starting from the bottom cardboard sheet A at a predetermined timing.
The clutch for the transport roller 35 is turned off after a predetermined time has elapsed.

When the cardboard sheet A passes between the lower drive roller 43D and the front ruler 46 and reaches a predetermined position, the sensor 59A turns ON. When the sensor 59A turns ON, the clutch of the electromagnetic clutch brake 97 turns OFF after a preset time has elapsed. The cardboard sheet A is further transported along the transport direction Y and is fed into between the lower drive roller 43C and the upper drive roller unit 45C.

The cardboard sheet A is further transported along the transport direction Y, passes between the lower drive roller 43B and the upper drive roller unit 45B, and is fed into between the lower guide 93 and the upper guide 94. Figure 14 shows this state.
15, when the cardboard sheet A is further conveyed, the leading edge 15 of the cardboard sheet A comes into contact with the stopper portion 69. When the cardboard sheet A is conveyed to a predetermined position where the leading edge 15 of the cardboard sheet A comes into contact with the stopper portion 69, the sensor 59B is turned ON.

Since the conveying operation of the cardboard sheet A continues even after the leading edge 15 of the cardboard sheet A abuts against the stopper portion 69, a force acts on the holder 67 to rotate the holder 67 in the clockwise direction in FIG. 15 around the pivot point C. Meanwhile, the pull-up cylinder 73 is in the push state, and a force acts on the piston rod 81 in the direction that causes the piston rod 81 to protrude. As a result, the holder 67 rotates in the clockwise direction in FIG. 15 while receiving resistance from the pull-up cylinder 73.

16, the claw portion 85 of the claw 71 comes into contact with the tip 13 of the cardboard sheet A at a predetermined position, and the cardboard sheet A is further conveyed and the holder 67 is further rotated. The holder 67 gradually folds the tip 13 of the cardboard sheet A with the contact position as the fold 7. This state is shown in FIGS. 16 and 17.
In the series of bending operations, the claw 71 functions as a punch, and the lower guide 74 and the support member 75 function as a die.

Thereafter, when the folding of the cardboard sheet A progresses a predetermined amount and reaches the state shown in Fig. 18, the pull-up cylinder 73 is put into the Pull position, whereby a force acts on the piston rod 81 in the direction of retracting the piston rod 81.
Next, in the state shown in Fig. 19, the cylinder switch of the pull-up cylinder 73 is turned ON. After that, as shown in Fig. 20, the bending operation continues and the cylinder switch of the pull-up cylinder 73 is turned OFF.

After that, as shown in FIG. 21, the leading edge 15 of the cardboard sheet A separates from the support member 75 and is unfolded. The lift cylinder 84 also goes into Push mode. This occurs a predetermined time after the cylinder switch of the pull-up cylinder 73 is turned ON. As a result, the piston rod 88 of the lift cylinder 84 starts to rise, and the support rod 83 starts to swing clockwise in FIG. 21 around the swing fulcrum E, causing the holder 67 to rise.

The conveyance of the cardboard sheet A continues thereafter, and as shown in Figures 22 and 23, the leading end 13 of the cardboard sheet A is folded and fed between the lower drive roller 43A and the upper drive roller unit 45A. Then, as shown in Figure 24, the leading end 13 passes between the lower drive roller 43A and the upper drive roller unit 45A in a folded state, and then becomes unfolded. In this state, the sensor 59A is turned OFF, and the electromagnetic clutch brake 97 is turned ON.

After that, the cardboard sheet A is further transported and reaches the state shown in FIG. 25. At this time, the sensor 59B is ON, the pull-up cylinder 73 is in Pull, the lift cylinder 84 is in Push, and the electromagnetic clutch brake 97 is in ON state.

When cardboard sheet A is further conveyed, the state shown in FIG. 26 is reached and sensor 59B is turned OFF. When cardboard sheet A is further conveyed, the state shown in FIG. 27 is reached, pull-up cylinder 73 is put into the Push state, and a force acts on piston rod 81 of pull-up cylinder 73 in a direction that causes piston rod 81 to protrude. As a result, holder 77 begins to rotate counterclockwise in FIG. 27 around pivot point C and returns to its original position. At the same time, the electromagnetic clutch brake 97 is turned OFF.

When the cardboard sheet A is further conveyed, it reaches the state shown in FIG. 28. The clutch of the electromagnetic clutch brake 97 is turned ON, and the clutch of the conveying roller 35 is also turned ON, and conveying of the next cardboard sheet A begins. When the cardboard sheet A is further conveyed, it reaches the state shown in FIG. 29, and the cylinder switch of the pull-up cylinder 73 is turned ON and then turned OFF.

When cardboard sheet A is further transported, it reaches the state shown in FIG. 30, and the clutch of transport roller 35 is turned OFF. When cardboard sheet A is further transported, it reaches the state shown in FIG. 31, and a new cardboard sheet A reaches the detection position by sensor 58A, and sensor 58A is turned ON.

When the cardboard sheet A is further conveyed, it reaches the state shown in Figure 32, and the lift cylinder 84 is pulled. The folded cardboard sheet A is discharged. When the cardboard sheet A is further conveyed, it reaches the state shown in Figure 33, and the clutch of the electromagnetic clutch brake 97 is turned OFF. The next cardboard sheet A is then subjected to the same folding action.
Thereafter, the same action is repeated.

As described above, according to this embodiment, the following effects can be obtained.
First, since the cardboard sheet A can be folded without stopping, a large number of cardboard sheets A can be efficiently folded into slip sheets 1, and the time and labor required for the work can be reduced. Specifically, it is sufficient to simply stack and place a large number of cardboard sheets A on the conveying roller 35 and the lower drive roller 43D and turn on the foot switch.
In addition, the bending angle, which is a necessary condition for the slip sheet 1, can be stably secured. This is because the claws 71 as a punch, the support member 75 as a die, and the lower guide 74 are configured to provide reliable bending.
In addition, when the claw portion 85 of the claw 71 abuts the tip end 13 of the cardboard sheet A at a predetermined position to bend it, a load is applied to the cardboard sheet A by the pull-up cylinder mechanism 73, which also enables a highly accurate and reliable bending.
In addition, since a force is applied in the opposite direction after a certain period of time, the cardboard sheet A can be removed from the support member 75 smoothly.
Furthermore, since the support member 75 has an arc shape, the cardboard sheet A can be gradually removed from the support member 75 .
Furthermore, the cardboard sheet A with its leading end 13 folded is pinched and conveyed by the lower drive roller and upper drive roller unit 45A, so that the cardboard sheet A can be folded reliably.

The present invention is not limited to the above-described embodiment, and therefore partial modifications of the configuration are possible within the scope of the gist of the present invention.
For example, although the slip sheet has been described as having a reinforcing piece, the reinforcing piece may not be necessary. Also, the reinforcing piece may be provided by attaching a separate member to the sheet body or the folding piece.
Moreover, instead of the pull-up cylinder mechanism, other mechanisms such as a cam mechanism may be employed.
Additionally, the configurations shown in the drawings are merely examples.

The present invention relates to a slip sheet folding machine that folds cardboard sheets that have been processed for use as slip sheets, and in particular to a machine that can efficiently fold multiple cardboard sheets into slip sheets and is designed to stably ensure the bending angle, a necessary condition for slip sheets, and is ideal for this type of folding work site, which has traditionally been left to manual labor by workers.

1 slip sheet 7 fold 23 conveying means 25 folding means 59A position sensor 59B position sensor 67 holder 69 stopper portion 71 claw 73 pull-up cylinder mechanism 74 lower guide 75 support member 80 cylinder body 81 cylinder rod 83 support rod 84 lift cylinder mechanism 85 claw portion W baggage A cardboard sheet Y conveying direction

Claims (8)

A conveying means for conveying the cardboard sheet;
A folding means for folding the leading end of the cardboard sheet conveyed by the conveying means to form a slip sheet;
Equipped with
The folding means includes a lower guide that supports the cardboard sheet conveyed by the conveying means from below, a holder that is installed above the lower guide so as to be rotatable around a pivot point, a stopper portion attached to the holder that is abutted by the leading edge of the cardboard sheet conveyed by the conveying means, a claw attached to the holder that abuts at a predetermined position on the leading edge of the cardboard sheet, and a pull-up cylinder mechanism that is connected to the holder and rotates the holder around the pivot point ,
a slip sheet folding machine characterized in that when the leading edge of the cardboard sheet abuts against the stopper portion, the holder is urged to rotate in one direction around the pivot point, and as the cardboard sheet is further transported, the holder is urged to rotate further in one direction, the claw abuts against a predetermined position on the cardboard sheet, the cardboard sheet is further transported, the holder is urged to rotate further in one direction, and the holder folds the cardboard sheet at the abutment position as a crease . 2. The slipsheet folder of claim 1,
A slip sheet folding machine characterized in that the conveying means is provided with a pair of conveying rollers which sandwich and convey the cardboard sheet whose leading end has been folded by the folding means in a folded state . 3. The slip sheet folding machine according to claim 1 or 2,
A slip sheet folding machine characterized in that a support member is attached to the holder to support the leading end of the cardboard sheet that abuts against the stopper portion, the claw corresponds to a punch, and the lower guide and the support member correspond to a die . 4. The slipsheet folder of claim 3,
This slip sheet folding machine is characterized in that the support member has an upwardly convex arc shape, and is configured so that the leading end of the cardboard sheet gradually moves away from the support member when the folding operation is completed . 3. The slip sheet folding machine according to claim 1 or 2 ,
A slip sheet folding machine characterized in that the pull-up cylinder mechanism rotates the holder in the opposite direction to the one direction for a predetermined period of time after the leading edge of the cardboard sheet abuts the stopper portion, thereby applying a load to the cardboard sheet . 5. The slipsheet folder of claim 4 ,
A slip sheet folding machine characterized in that the pull-up cylinder mechanism applies a load for a predetermined period of time and then releases the load when the leading end of the cardboard sheet has been folded by a predetermined angle, and at the same time, the pull-up cylinder mechanism urges the holder to rotate in the one direction . 3. The slip sheet folding machine according to claim 1 or 2 ,
A slip sheet folding machine characterized in that the pull-up cylinder mechanisms are installed on each of the left and right sides of the holder in the width direction . 3. The slip sheet folding machine according to claim 1 or 2 ,
A slip sheet folding machine characterized in that a support rod is installed so as to be swingable around one end, the pivot point of the holder is installed at the other end of the support rod, the pull-up cylinder mechanism is installed so as to be swingable around the pivot point, and a lift cylinder mechanism is installed, and when the holder biased to rotate in one direction is returned in the other direction, the support rod is swung by the lift cylinder mechanism to raise the position of the pivot center of the holder .

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