JP2019072708A - Box-shaped object compression apparatus - Google Patents

Abstract

To provide a vacant cardboard box compression apparatus which is a simple and low-cost apparatus and is capable of decreasing an object to be compressed such as a vacant cardboard box.SOLUTION: A box-shaped object compression apparatus 1 comprises a belt conveyer 340 for transporting by mounting an object to be compressed K, a bottom compression roller 313 wound with the belt conveyer 340, a top compression roller 440 for compressing the object to be compressed K transported by the belt conveyer 340, a first paddle 420 arranged upstream of the belt conveyer 340, and a second paddle 430 located downstream of the belt conveyer from the first paddle 420 and upstream of the top compression roller 440, thereby feeding the object to be compressed K transported by the belt conveyer 340 while gradually being compressed by the first paddle 420 and the second paddle 430, and being compressed by the bottom compressed roller 313 and the top compressed roller 440.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a box-like material compressing apparatus, and more particularly, to an apparatus for compressing a paper container such as an empty cardboard box, which is conveyed by an endless belt conveyor and forcedly in the conveying direction by a paddle provided. The present invention relates to an apparatus for feeding and compressing with a compression roller.

  As a device for reducing the volume of cardboard boxes, etc., "corrugated cardboard box crusher" described in U.S. Pat. No. 3,194,380 (Patent Document 1) and "discarded cardboard box disassembly device" disclosed in JP-A-2017-105480 (Patent Document 2) And dismantling methods are disclosed.

The "cardboard box crushing apparatus" disclosed in Patent Document 1 inputs "empty cardboard boxes from one end side of the apparatus body, and crushes the cardboard boxes in the apparatus body to form crushed pieces, and fragments" Is carried out from the other end side of the apparatus main body.
In addition, “disassembling apparatus and disassembling method of cardboard box” disclosed in Patent Document 2 is an apparatus for disassembling “the assembled cardboard box into a flat expanded cardboard box, and the outside of one opening is disclosed. Pressure with a pressing plate that acts on at least one bent portion of the cardboard box in a state where the lid and the inner lid are bent inward to simultaneously break the connection sides of both ends of the portion connected by the bent portion It is an apparatus equipped with a mechanism and the disassembly method.

True No. 3194380 JP, 2017-105480, A

From the aspect of transportation efficiency, it is desirable that the empty cardboard boxes and the like discarded from the store be transported by a collection company after being reduced in volume such as compression.
In large-scale retail stores and large-scale distribution stores, the volume reduction of empty cardboard boxes and the like to be discarded has been automated by the introduction of fully automatic presses and the like. However, in small and medium-sized retail stores and distribution stores, there is no space for installation because the fully automatic press is large. In addition, the mechanism of the device is also complicated due to its high cost, and it has not been adopted in terms of introduction cost. Furthermore, since the empty cardboard box etc. compressed and reduced in volume by the above-mentioned fully automatic press machine is compressed until it becomes a large and hard block-like block, the existing recovery packer car recovers the block too large There is a present condition that it is impossible, or it is too hard and is clogged with the rotating plate or pushing plate of the recovery packer car.
Based on the above-mentioned circumstances, in the small- and medium-sized retail stores and distribution stores, the empty cardboard boxes etc. are manually disassembled and then collected by a packer car of a collection company, etc. The cycle of recycling is customary. The volume reduction of an empty cardboard box or the like by hand as described above is the current situation where the adhesive tape and adhesive are peeled off, the fasteners and the like are removed, and the box is folded and disassembled or reduced in volume.

In order to reduce the volume of an empty cardboard box or the like, the "cardboard box crushing apparatus" of Patent Document 1 is configured to shred the volume of the empty cardboard box or the like. However, as described above, the crushing process of an empty cardboard box or the like is performed by a specialized contractor after being collected from the store and is disposed of, so the crushing process by the crushing apparatus by the store is an unnecessary process, The manufacturing cost of the device increases. In addition, since the fragments may be scattered, the number of processes to be collected is increased, which is not suitable as a low running cost installed at retail stores and distribution stores and a low installation cost and low cost apparatus.
Next, the "disassembling apparatus and method for disassembling cardboard boxes" of Patent Document 2 can not be introduced in small- and medium-sized retail stores and distribution stores because the mechanism for disassembling and folding the cardboard raises the manufacturing cost. .

  From this, the object of the present invention is to compress the empty cardboard box and the like with a simple mechanism, and at a low cost device, release the worker from the dismantling work of the empty cardboard box and the like manually, An object of the present invention is to provide a compression device such as an empty cardboard box which can easily reduce the volume of the empty cardboard box etc.

In order to solve the above problems, the present invention is
A belt conveyor for placing and transporting a compacted object such as a box-like material;
A lower compression roller disposed downstream of the belt conveyor and having the belt conveyor wound thereon;
An upper compression roller disposed above the lower compression roller and in parallel with the rotational axis of the lower compression roller, and cooperating with the lower compression roller to compress the object conveyed by the belt conveyor; ,
And one or more paddles provided parallel to the rotational axis of the upper compression roller and disposed upstream of the belt conveyor,
The rotational axis of the paddle is positioned above the rotational axis of the upper compression roller,
A box characterized in that the compressed material conveyed by the belt conveyor is fed while being gradually compressed by a paddle, compressed by the lower compression roller and the upper compression roller, and then discharged from the end of the belt conveyor. Rod compactor,
It is.

Moreover, in order to solve the above-mentioned subject, this invention is further
The paddle is
A first paddle disposed parallel to the rotation axis of the upper compression roller and disposed upstream of the belt conveyor;
And a second paddle provided parallel to the rotation axis of the first paddle and located downstream of the belt conveyor from the first paddle and upstream of the upper compression roller.
The rotation axis of the first paddle is positioned above the rotation axis of the second paddle,
A box compactor, wherein the rotation axis of the second paddle is positioned above the rotation axis of the upper compression roller.
It is.

Moreover, in order to solve the above-mentioned subject, this invention is further
The paddles are provided with a plurality of projecting plates radially outward from the rotation axis,
The flat portion of the projecting plate is directed in the rotational direction of the paddle,
A box-like material compression device for compressing the material to be compressed conveyed by the belt conveyor;
It is.

Moreover, in order to solve the above-mentioned subject, this invention is further
The tip of each of the plurality of protruding plates provided radially outward from the rotation axis of the paddle is rotated backward from the rear surface of the protruding plate on the front side in the rotation direction A construction board provided to bridge the front surface of the projecting board on the side;
And further
A box-like object compression device, wherein the diameter of the outer periphery of rotation of the installation board is smaller than the diameter of the outer periphery of the outer periphery of the projection plate to which the installation plate is attached;
It is.

Moreover, in order to solve the above-mentioned subject, this invention is further
A box-like object compression device, wherein the outer peripheral diameter of the paddle is larger than the outer peripheral diameter of the upper compression roller,
It is.

Moreover, in order to solve the above-mentioned subject, this invention is further
The number of revolutions of the paddle is set smaller than the number of revolutions of the upper compression roller.
Box compactor,
It is.

Moreover, in order to solve the above-mentioned subject, this invention is further
A door is provided upstream of the belt conveyor,
A box compactor wherein the belt conveyor, the lower compression roller, the upper compression roller and the paddle stop operating when the door is opened.
It is.

Moreover, in order to solve the above-mentioned subject, this invention is further
A box-shaped object compacting apparatus further comprising a plurality of projections attached to the outer peripheral portion of the compression roller with a length substantially the same as the length of the roller portion of the compression roller,
It is.

  According to the present invention, it is possible to provide a device for compressing and reducing the volume of an empty cardboard box required for recovery of a box-like material compacting device, in particular, an empty cardboard box, etc. with an inexpensive structure, It is easy to compress empty cardboard boxes and other boxes.

It is a perspective view of the box-like object compression apparatus of 1st Example of this invention. It is a side view of a box-like thing compression device of a 1st example of the present invention. It is a top view of the box-like object compression apparatus of 1st Example of this invention. It is a front view of the box-like object compression apparatus of 1st Example of this invention. It is the side view cut by the AA shown in FIG. 3 of the box-like object compression apparatus of 1st Example of this invention. It is the rear elevation figure which cut the conveyance part and compression part of the box-like object compression apparatus of 1st Example of this invention by BB shown in FIG. It is the side view which cut the conveyance part and compression part of the box-like object compression apparatus of 1st Example of this invention by CC shown in FIG. It is a side view of the box-like object compression apparatus of 2nd Example of this invention. It is an internal structure perspective view of the compression part of the box-like object compression apparatus of 2nd Example of this invention. It is a side view of the box-like object compression apparatus of 2nd Example of this invention, and is a figure showing the correlation of a rotation direction. It is a side view of the box-like object compression apparatus of 3rd Example of this invention. It is an internal structure perspective view of the compression part of the box-like object compression apparatus of 3rd Example of this invention. It is a side view of the box-like object compression apparatus of 3rd Example of this invention, and is a figure showing the correlation of a rotation direction. It is a partially expanded side view of the compression roller of the box-like object compression apparatus of 3rd Example of this invention. It is a partially expanded perspective view of the compression roller of the box-like object compression apparatus of 3rd Example of this invention. It is a partially expanded side view of the use condition of the box-like object compression apparatus of 1st Example of this invention. It is a partially expanded side view of the use condition of the box-like object compression apparatus of 3rd Example of this invention.

A first embodiment which is an embodiment of the present invention will be described based on FIGS. 1 to 7.
The apparatus 1 for compressing an empty cardboard box or the like according to the present invention comprises a transport unit 3, a compression unit 4 and an insertion unit 5 supported by a frame 2, and an operation unit 6. It is a device for compressing and reducing the volume of an equal box (hereinafter referred to as a compression target K). The to-be-compressed object K is loaded from the loading unit 5 on the left side shown in FIG. 2 by the worker, and the worker performs the operation with the operation unit 6 to be placed on the belt conveyor 340 of the transport unit 3 The object to be compressed K is conveyed in the downstream direction on the right side shown in FIG. The compressed object K transported in the downstream direction is subjected to primary compression, secondary compression, and final compression in the compression unit 4. The compressed object K compressed gradually and finally compressed is further conveyed to the downstream side of the belt conveyor 340 and discharged from the rear end of the belt conveyor 340. In the description of the first embodiment, it is assumed that the left side shown in FIG.

The frame portion 2 shown in FIG. 2 is a frame portion which constitutes a box-like object compressing apparatus 1 such as an empty cardboard box, and is rigidly configured to support the conveying portion 3, the compression portion 4 and the input portion 5. It is done.
The transport unit 3 is installed on the top of the frame unit 2. The to-be-compressed object K loaded from the loading unit 5 and placed on the belt conveyor 340 provided in the transport unit 3 is transported from the left side to the right side shown in FIG. 2 and transported to the compression unit 4 .
The compression unit 4 performs primary compression by the first paddle 420, secondary compression by the second paddle 430, and final compression by the upper compression roller 440 by the first paddle 420. It is a part that compresses gradually. The to-be-compressed object K compressed by the compression unit 4 is conveyed further downstream by the belt conveyor 340 and discharged from the rear end portion of the right side belt conveyor 340 shown in FIG.
The input unit 5 is a portion where the operator places the object K on the belt conveyor 340.
The operation unit 6 is disposed in the vicinity of the input unit 5 and is a portion where a worker operates a switch in order to operate the box-like object compressing apparatus 1 such as the empty cardboard box.

The frame portion 2 mainly includes a base frame 210, a motor mounting plate 211, and a side frame 220. The base frame 210 shown in FIG. 2 is a base of the box compacting device 1 such as the empty cardboard box, and is configured to be surrounded by a rectangular bar in a rectangular frame. The rectangular parallelepiped is the longest in the left-right direction shown in FIG. 2 and the shortest in the vertical direction shown in FIG.
Furthermore, at the corner on the discharge side N of the base frame 210 formed of a rectangular parallelepiped, on the right side shown in FIG. 4, a motor mounting plate 211 formed of a square plate member is located above the base frame 210. It is arranged and fixed so as to bridge the side of the side and the lower side.

  The motor mounting plate 211 is provided with holes at a plurality of places so that the motor 310 for driving the transport unit 3 and the compression unit 4 can be mounted. The motor 310 attached to the motor attachment plate 211 is attached from the inside of the base frame 210 with the output shaft 311 directed outward in the horizontal direction. The rotation direction of the output shaft 311 in the first embodiment is clockwise rotation in the side view of FIGS. 2 and 5.

Casters 240 are attached to four corners of the lower surface of the base frame 210, and the box-like object compacting apparatus 1 such as the empty cardboard can freely move. A lever for fixing the rotation of the foil portion is attached to the caster 240, and by fixing the rotation of the foil portion, the box-like object compression device 1 such as the empty cardboard can be fixed.
Further, on the upper part of the frame portion 2, a side frame left 23L and a side frame right 23R for attaching the transport portion 3 and the compression portion 4 are attached.

  The side frame left 23L and the side frame right 23R are formed of plate-like members, and are vertically hung from the top of the left and right ends of the base frame 210 shown in FIG. In the first embodiment, the side frame left 23L is from the upper portion on the left side of the base frame 210 shown in FIG. 4, and the side frame right 23R is from the upper portion on the right side. Arranged parallel to The shape of the side frame left 23L and the side frame right 23R is symmetrical with respect to the belt conveyor 340, and is a substantially square plate in a side view shown in FIG. The corners are cut off at a large angle, and the upper and lower corners of the input side M are cut off at a shallow angle with respect to the horizontal plane. Ribs for securing strength on the outer surface of the side frame left 23L and the side frame right 23R at their respective outer peripheral parts, the vertical direction of the central part, the horizontal direction of the lower part, and the lower end. Is provided.

  In order to support the lower compression roller 313 of the transport unit 3 described later so as to be positioned above the motor 310 on the lower side outer surface of each of the side frame left 23L and the side frame right 23R. The bearing holder 321 is fixed. The bearing holding portion 321 is a rectangular thick plate and is formed to be long in the vertical direction. At two places in the vertical direction of the bearing holding portion 321, stepped holes are provided in parallel with the lower compression roller 313, and a small diameter is positioned inside. The bearings 322 are inserted into the stepped holes provided at two positions above and below the bearing holding portion 321.

  The transport unit 3 for transporting the object K is located between the side frame left 23L and the side frame right 23R. The transport unit 3 includes a lower compression roller 313, a belt conveyor 340, and a tension roller 350.

  The lower compression roller 313 is disposed above the motor 310 with its rotation axis parallel to the output shaft 311. The lower compression roller 313 is disposed below the side frame left 23L and the side frame right 23R in the vicinity of the discharge side N on the right side shown in FIGS. 2 and 5.

  The lower compression roller 313 is fixed so as to cover both ends of the pipe with a circular plate material, and a shaft portion serving as a rotation axis is parallel to the pipe from the central portion of the plate toward the outside direction It has a protruding shape. The pipe of the lower compression roller 313 is set shorter than the length between the side frame left 23L and the side frame right 23R. The lower compression roller 313 has the shaft portion provided at both ends held by the bearing holding portion 321 disposed on the outer surface of the side frame left 23L and the side frame right 23R. It is inserted into and rotatably supported.

  The shaft portion of the lower compression roller 313 is long on the side of the side frame right side 23R and protrudes from the bearing 322. A tension roller 350 is provided on the input side M opposite to the lower compression roller 313 located on the output side N.

  The tension roller 350 has a pipe shape and is set to have substantially the same length as the lower compression roller 313, and is a lower portion of the side frame left 23L and the side frame right 23R, as shown in FIGS. It is arranged to bridge over in the vicinity of the input side M of. The tension roller 350 is set such that the position of the rotation shaft is approximately the same height as the lower compression roller 313 or a slightly rigid height, and the rotation shaft of the tension roller 350 is provided parallel to the lower compression roller 313 .

The tension roller 350 is rotatably supported by a bearing 352 held by the inner diameter at both ends and a tension shaft 351 inserted into the bearing 352. Both ends of the tension shaft 351 protrude from the side frame left 23L and the side side frame right 23R.
At both ends of the tension shaft 351, screw holes are provided in a direction perpendicular to the shaft portion, and the screw holes are directed in the horizontal direction. The position of the tension shaft 351 is fixed and supported by screwing a bolt 353 fixed to the side frame left 23L and the side frame right 23R into the screw hole.

A belt conveyor 340 is wound around the lower compression roller 313 and the tension roller 350. The belt conveyor 340 has an endless shape in which the start and end are continuous, has a width substantially the same as the length of the lower compression roller 313, and the outer peripheral surface is smooth without large unevenness.
Further, the wound belt conveyor 340 is installed so that the upper surface portion is substantially horizontal, and the object K is placed on the upper surface portion and conveyed from the input side N to the output side M. Can.

  When the tension is loose, the belt conveyor 340 may slip by the lower compression roller 313 serving as a driving source of the belt conveyor 340 and may not be conveyed. In order to eliminate the slip, it is possible to adjust the tension of the belt conveyor 340 by moving the tension roller 350 in the horizontal direction parallel to the conveyance direction of the belt conveyor 340. The tension roller 350 is moved in the horizontal direction by rotating the bolt 353. When the tension adjustment is completed, the bolt 353 is tightened with a nut 354 to prevent rotation.

  A support table 361 is disposed on the inner peripheral portion of the conveyance surface at the top of the belt conveyor 340 shown in FIG. 7 so as to bridge the side frame left 23L and the side frame right 23R. The support table 361 supports and assists the belt conveyor 340 from the inner circumferential side so that the object to be compressed K placed on the conveyance surface above the belt conveyor 340 does not sink.

The driving method of the belt conveyor 340 will be described with reference to FIG. The belt conveyor 340 is driven by the motor 310 and is transmitted through a chain.
A first sprocket 312 is inserted into and fixed to the output shaft 311 of the motor 310. A washer with an outer diameter larger than the outer diameter of the output shaft 311 is brought into contact with the end of the output shaft 311, and a bolt is screwed in to prevent the first sprocket 312 from coming off.

  A lower gear 314 and a second sprocket 315 are inserted into and fixed to the shaft portion on the side frame right 23R side of the lower compression roller 313. About the usage method of the said lower gear 314, the compression part 4 mentioned later is operated. A washer with an outer diameter larger than the shaft outer diameter is brought into contact with the shaft end portions at both ends of the lower compression roller 313, and bolts are further screwed in to prevent the lower gear 314 and the second sprocket 315 from coming off. The lower compression roller 313 is axially fixed and can be stably rotated.

  A conveyor drive chain 330 is wound around the first sprocket 312 and the second sprocket 315. The conveyor drive chain 330 drives the belt conveyor 340 by transmitting the rotation generated by the motor 310 to the lower compression roller 313. In the present embodiment, the conveyor drive chain 330 is clockwise in a side view shown in FIGS. 2, 5 and 7. Further, the belt conveyor 340 is also rotated clockwise as the conveyor drive chain 330 is.

  The slack side of the conveyor drive chain 330 is provided with a tensioner 331 for removing the slack of the chain. In the first embodiment, the tensioner 331 is provided on the left side of the outer periphery of the conveyor drive chain 330 shown in FIG.

  The tensioner 331 has a pressing surface having a shape in which the surface of the conveyor drive chain 330 is expanded in an arc shape by a rectangular plate. The pressing surface is positioned to press the conveyor drive chain 330 to the inner peripheral side in the horizontal direction. At the center of the surface of the tensioner 331 opposite to the pressing surface, a guide rod 333 fixed horizontally is provided in the horizontal direction.

  The guide bar 333 is formed of a round bar, and is inserted into the inner diameter portion of the pipe-like holder 335 fixed to the base frame 210 and held movably only in the horizontal direction. Furthermore, an elastic member 334 is disposed between the tensioner 331 and the holder 335, which is inserted into the guide rod 333.

  The elastic member 334 biases the tensioner 331 so as to always press the inner periphery of the conveyor drive chain 330. The conveyor drive chain 330 is pressed by the elastic member 334 to apply tension to the conveyor drive chain 330, and the conveyor drive chain 330 drops out of the first sprocket 312 and the second sprocket 315 due to slack. To prevent.

  By configuring as described above, the belt conveyor 340 is driven by the lower compression roller 313. The lower compression roller 313 and the upper surface portion of the belt conveyor 340 wound around the tension roller 350 can horizontally move from the input side M to the discharge side N. The to-be-compressed object K placed on the upper surface portion on the upstream side of the belt conveyor 340 can move horizontally from the input side M to the discharge side N with the movement of the belt conveyor 340.

The compression unit 4 is located above the belt conveyor 340. The compression unit 4 includes a first paddle 420, a second paddle 430, and an upper compression roller 440.
The to-be-compressed object K conveyed by the belt conveyor 340 is conveyed to the compression unit 4, is primarily compressed by the rotation of the first paddle 420, and is then secondarily compressed by the rotation of the second paddle 430, It is gradually compressed to be finally compressed by the upper compression roller 440.

  The mounting positional relationship of the first paddle 420, the second paddle 430, and the upper compression roller 440 will be described.

  The first paddle 420 is used to primarily compress the object K placed on the upstream side of the belt conveyor 340 and conveyed downstream. The first paddle 420 is positioned on the upstream side above the belt conveyor 340, and is disposed to bridge the side frame left 23L and the side frame right 23R.

  The first paddle 420 includes a first paddle shaft 421 serving as a rotation shaft and a plurality of first projecting plates 422 for compressing the object K, and the rotation shaft is disposed parallel to the lower compression roller 313. Be done. In the present embodiment, the number of the first projecting plates 422 is four, and the rotational direction is counterclockwise as shown in FIG. A driving method of rotating the first paddle 420 will be described later.

Both ends of the first paddle shaft portion 421 are supported by bearings 424 held by holes of a paddle holding portion 423 fixed to the outer surface of the side frame left 23L and the side frame right 23R. Thus, the first paddle 420 is rotatable.
The paddle holding portion 423 is a rectangular member, and a stepped hole having a hole with a slightly smaller diameter on the side of the belt conveyor is provided at the center portion, and the bearing 424 is the side frame left 23L and It is held so as not to move inside the side frame right 23R.
An end of the first paddle shaft portion 421 on the side frame right 23R side protrudes from the bearing 424.

The plurality of first projecting plates 422 are rectangular plates whose width of the first projecting plate 422 is substantially the same as the width of the lower compression roller 313, and the flat portion 426 of the plate is directed in the rotational direction. There is. The tip end portion of the first projecting plate 422 is radially disposed in the outward direction of rotation, and is fixed to the first paddle shaft portion 421.
The tip of the first protruding plate 422 on the rotation outer peripheral side is bent in the rotation direction side, and the compressed object K conveyed by the belt conveyor 340 is struck and compressed, and at the same time, the first paddle 420 There is an effect of efficiently feeding the second paddle 430 located downstream of the belt conveyor 340. Further, a rib 427 is fixed to the rear surface of the first projecting plate 422 in the rotational direction, and the first projecting plate 422 is held firmly.

  The first paddle 420 configured as described above primarily compresses the object K conveyed by the belt conveyor 340 by rotation. Furthermore, the first-compressed object K is conveyed downstream by the belt conveyor 340 and is secondarily compressed by the rotation of the second paddle 430.

The rotation axis of the second paddle 430 is parallel to the first paddle 420 and is located on the downstream side of the belt conveyor 340 from the first paddle 420 below the first paddle 420. The rotation axis of the second paddle 430 may be parallel to the lower compression roller 313 disposed parallel to the first paddle 420.
The second paddle 430 is disposed so as to bridge the side frame left 23L and the side frame right 23R.

  The second paddle 430 has a second paddle shaft portion 431 as a rotation axis and a plurality of second projecting plates 432 for compressing the object K, and the rotational direction is as shown in FIGS. 2, 5 and 7. It is a counterclockwise rotation shown in. The driving method of the second paddle 430 will be described later.

  Both ends of the second paddle shaft portion 431 are held by the stepped holes of the paddle holding portion 423 fixed to the outer surface of the side frame left 23L and the side frame right 23R. And the second paddle 430 is rotatable. The shaft portion on the side frame right 23 </ b> R side of the second paddle shaft portion 431 protrudes from the bearing 424.

The plurality of second projecting plates 432 provided are a rectangular plate whose width is substantially the same as that of the lower compression roller 313, and the flat portion 433 of the plate is directed in the rotational direction. The tip of the second projecting plate 432 is radially disposed in the outward direction of rotation, and is fixed to the second paddle shaft portion 431. In the present embodiment, the number of the second projecting plates 432 is four.
The second projecting plate 432 has a length in the rotation radial direction smaller than that of the first projecting plate 422. Therefore, the rotation outer diameter of the second paddle 430 is smaller than the rotation outer diameter of the first paddle 420.

The rotation outer diameters of the second paddle 430 are smaller than those of the first paddle 420, so that the respective rotation axes can be brought close to each other. When the object K is compressed at the lower part of the adjacent rotation outer circumferences, secondary compression can be performed immediately after the primary compression, and the compression time can be shortened. In addition, since the size of the entire apparatus can be miniaturized, useless materials can be omitted and cost reduction can be achieved.
Furthermore, the outer peripheral diameter of the second paddle 430 is positioned so as not to overlap with the outer peripheral diameter of the adjacent first paddle 420.

The compression object K secondarily compressed by the second paddle 430 is conveyed downstream by the belt conveyor 340 and finally compressed by the upper compression roller 440.
The rotation shaft of the upper compression roller 440 is located below the second paddle 430 and downstream of the belt conveyor 340 with respect to the second paddle 430, and is disposed above the lower compression roller 313. The rotation axis of the upper compression roller 440 is disposed parallel to the rotation axis of the second paddle 430 so as to bridge the side frame left 23L and the side frame right 23R. That is, the rotation axes of the first paddle 420, the second paddle 430, and the upper compression roller 440 that constitute the compression unit 4 are parallel to the lower compression roller 313 of the conveyance unit 3, respectively.

The upper compression roller 440 is fixed so as to cover both ends of the pipe with a circular plate material, and a shaft portion serving as a rotation axis is parallel to the pipe from the central portion of the plate toward the outside direction It has a protruding shape. The pipe constituting the upper compression roller 440 is set shorter than the length between the plate surfaces of the side frame left 23L and the side frame right 23R.
The shaft portion at the end of the upper compression roller 440 is supported by the bearing 322 held by the upper hole of the bearing holding portion 321 provided on the side frame left 23L and the side frame right 23R. As a result, the upper compression roller 440 is rotatably supported. The shaft portion of the upper compression roller 440 is long on the side of the side frame right 23 </ b> R and protrudes from the bearing 322.

The outer peripheral diameter of the upper compression roller 440 is substantially the same as the outer peripheral diameter of the lower compression roller 313, and the outer peripheral diameters do not interfere with each other, leaving a gap. The gap has a gap width such that the compressed object K can pass through.
In the first embodiment, the outer peripheral diameter of the upper compression roller 440 is set smaller than the outer peripheral diameter of the second paddle. Furthermore, the outer peripheral diameter of the upper compression roller 440 does not overlap with the outer peripheral diameter of the adjacent second paddle 430. That is, the lower compression roller 313, the first paddle 420, the second paddle 430, and the upper compression roller 440 that constitute the compression unit 4 can rotate without overlapping of their outer peripheries.

The driving method of the compression unit 4 will be described. The compression unit 4 is driven by the motor 310 as a drive source, and is transmitted in the order of the upper compression roller 440, the second paddle 430, and the first paddle 420 via the lower compression roller 313.
The transmission from the lower compression roller 313 to the upper compression roller 440 is performed by a gear. An upper gear 441 is fixed to a shaft on the side frame right 23R side of the upper compression roller 440 in order to perform gear transmission. The upper gear 441 engages with the lower gear 314 inserted and fixed to the lower compression roller 313 described above.

The lower gear 314 and the upper gear 441 have the same number of teeth and the same outer diameter, respectively, and the outer diameter is larger than the outer diameter of the lower compression roller 313 and the outer diameter of the upper compression roller 440. That is, the lower compression roller 313 and the upper compression roller 440 rotate at the same number of revolutions. Further, by driving the gears, the distance between the rotation shafts of the lower compression roller 313 and the upper compression roller 440 can be made constant. A stable compression space can be maintained.

  The second paddle 430 adjacent to the upper compression roller 440 is transmitted from the upper compression roller 440 by a chain and rotationally driven. A third sprocket 451 is fixed to the shaft portion of the upper compression roller 440 adjacent to the upper gear 441 provided on the upper compression roller 440. Further, a fourth sprocket 452 is inserted and fixed to the side frame right 23R side of the second paddle shaft portion 431 on the driven side.

Furthermore, since the second paddle drive chain 453 is wound around the third sprocket 451 and the fourth sprocket 452, the second paddle 430 can be rotationally driven in conjunction with the upper compression roller 440. . In addition, the fourth sprocket 452 has a larger number of teeth and a larger diameter than the third sprocket 451, so that the second paddle 430 has a lower rotational speed than the upper compression roller 440.
In the case of the first embodiment, the upper compression roller 440 is set to 35 rpm, and the second paddle 430 is set to 18 rpm. Further, since the second paddle 430 is set to be large relative to the upper compression roller 440, the rotational outer peripheral speed is set to be substantially the same as each other. That is, the rotational outer peripheral speed of the second paddle 430 is substantially the same as the transfer speed of the belt conveyor 340. In the case of the first embodiment, the transport speed of the belt conveyor 340 is set to about 15 m / min to 30 m / min.
The coincidence of the rotational outer peripheral speed and the conveying speed does not cause the upper compression roller 440 located on the discharge side N of the second paddle 430 to splash over the object K to be excessively supplied, and the upper compression roller 440 Between the lower compression roller 313 and the lower compression roller 313.

  Further, a washer of an outer diameter larger than the outer diameter of the second paddle shaft portion 431 is brought into contact with both end portions of the second paddle shaft portion 431, and a bolt is further screwed to fix the washer. The second paddle 430 is fixed so as not to move in the axial direction by the washer, and the fourth sprocket 452 can be stably rotated without falling off.

  The rotation of the second paddle 430 causes the first paddle 420 adjacent on the upstream side of the belt conveyor 340 to be transmitted by the chain and rotated. A fifth sprocket 461 is inserted into and fixed to the second paddle shaft portion 431 protruding outward on the side frame right 23R side so as to be adjacent to the fourth sprocket 452. The fifth sprocket 461 has a smaller number of teeth and a smaller diameter than the fourth sprocket 452.

A sixth sprocket 462 is inserted and fixed to the first paddle shaft portion 421 projecting outward on the side frame right 23R side of the first paddle shaft portion 421 which is the driven side.
Furthermore, the first paddle drive chain 463 is wound around the fifth sprocket 461 and the sixth sprocket 462, so that the first paddle 420 can be rotationally driven in conjunction with the second paddle 430. .

The sixth sprocket 462 has the same number of teeth as the fifth sprocket 461. That is, the second paddle 430 and the first paddle rotate at the same rotational speed.
In addition, since the outer peripheral diameter of the first paddle 420 is larger than that of the second paddle 430, the outer peripheral speed of the first paddle 420 is higher than that of the second paddle 430. Therefore, it can be said that the rotational outer peripheral speed of the first paddle 420 is higher than the transport speed of the belt conveyor 340, which is substantially the same as the rotational outer peripheral speed of the second paddle 430. The first projecting plate 422 provided on the rotating first paddle 420 is compressed on the belt conveyor 340 because the rotational outer peripheral speed of the first paddle 420 is higher than the conveying speed of the belt conveyor 340. The object K is struck and the primary compression of the object K is efficiently performed.

  An outer diameter washer larger than the outer diameter of the first paddle shaft 421 is brought into contact with both ends of the first paddle shaft 421 and screwed in to secure the washer. The first paddle 420 is fixed by the washer so as not to move in the axial direction, and the sixth sprocket 462 can be stably rotated without falling off.

  In the first embodiment, the upper compression roller 440, the second paddle 430, and the first paddle 420 of the compression unit 4 are all left-rotated as shown in FIG. 2, FIG. 5 and FIG.

A paddle cover 470 covers the upper side of the second paddle 430 and the first paddle 420 from the vicinity of the discharge side N of the belt conveyor 340 of the upper compression roller 440. The paddle cover 470 is disposed and fixed so as to bridge the side frame left 23L and the side frame right 23R.
Further, a chain cover 471 is attached to the outside of the right side frame 23R so as to cover the transmission member. Furthermore, by attaching the lower cover 472 so as to cover the periphery of the side surface of the base frame 210, it is considered that the worker does not directly touch the transmission members of the transport unit 3 and the compression unit 4.

  As described above, by configuring the compression unit 4, the object K placed on the upstream side of the upper surface portion of the belt conveyor 340 is moved to the downstream side and rotationally driven by the first paddle 420 as a primary. It is compressed. The primary-compressed object K is moved downstream by the belt conveyor 340 and is secondary-compressed by the second paddle 430 that is rotationally driven. The second-compressed object K is moved downstream by the belt conveyor 340, and is located above the lower compression roller 313 located on the rear end side of the belt conveyor 340 and the lower compression roller 313. The final compression is performed by the upper compression roller 440 that rotates in cooperation with the lower compression roller 313 at the same rotation speed as the lower compression roller 313. The finally compressed object K can be discharged from the discharge side N which is the rear end side of the belt conveyor 340 by moving further downstream by the belt conveyor 340.

The loading unit 5 is configured to place the object K on the upstream side of the upper surface of the belt conveyor 340. The input unit 5 mainly includes a table 510 and a door 520 on which the object to be compressed is placed. The table 510 is a member for temporarily placing the object K before being placed on the belt conveyor 340. By temporarily placing the object to be compressed K on the table 510, it has a role of preventing the conveyance of the object to be compressed K which the operator does not intend.
The table 510 is a plate-like member, and is provided in the horizontal direction so that the upper surface portion of the belt conveyor 340 is extended to the input side M. The width of the table 510 is provided to bridge the side frame left 23L and the side frame right 23R, and the end of the input side M of the table 510 is the side frame left 23L and the side. It is provided so as to be positioned substantially the same as the end of the input side M of the part frame right 23R.
That is, a door 520 is provided at the end of the side frame left 23L, the side frame right 23R, the table 510, and the insertion side M of the paddle cover 470 so as to close the space released in a rectangular shape. Be

  The door 520 is formed of a rectangular sheet metal, and the end on the right side shown in FIG. 4 is extended so as to overlap with the rib provided on the right side frame 23R. At the end of the side frame left 23L side of the door 520, a hinge 521 whose rotation axis is directed in the vertical direction is attached. The hinge 521 is fixed to the end of the input side M of the side frame left 23L, and the hinged door 520 can be opened and closed. In the first embodiment, the hinges 521 are provided at three positions in the vertical direction.

A handle 522 is provided on the side frame right 23 </ b> R side of the door 520. The operator can easily open and close the door 520 by grasping the handle 522.
A magnet 523 is attached to the surface of the rib portion of the side frame right 23R in contact with the door 520. When the door 520 is closed, the door 520, which is a metal plate, is fixed by a magnet 523, and the door 520 remains closed unless the operator manipulates the handle 522. The operator pulls the handle 522 to the input side M to open the door 520.

  In the vicinity of the door 520, an operation unit 6 is provided on the side frame right 23R. The operation unit 6 includes a switch box 610 for storing switches, a power switch 620 which is the switches, a forward switch 630, a reverse switch 640, an emergency stop switch 650, and a limit switch 660. In the switch box 610, an electric circuit (not shown) connecting a power supply, the switches, and the motor 310 is formed.

The switch box 610 is in the form of a rectangular parallelepiped having a long side in the vertical direction, and is installed on the outer surface of the input side M of the right side frame 23 R. On the surface of the input side M of the switch box 610, a plurality of holes for accommodating switches are vertically formed in one row. The power switch 620, the forward rotation switch 630, the emergency stop switch 650, and the reverse rotation switch 640 are attached to the plurality of holes from above.
The power switch 620 is a switch serving as the main power of the apparatus, and can be switched so that the main power can be turned on and the main power can be turned off.

  When the button portion of the forward rotation switch 630 is pushed while the main power switch is "on", the forward rotation of the forward rotation switch 630 causes the lower compression roller 313 to move as shown in FIG. 2, FIG. 5 and FIG. Rotate clockwise in side view as shown in. The upper surface portion of the belt conveyor 340 is operated to move from the input side M to the output side N. Also, the upper compression roller 440, the first paddle 420 and the second paddle 430 rotate counterclockwise as shown in FIG. 2, FIG. 5 and FIG. When stopping the operation, pressing the forward rotation switch 630 again stops all driving.

When the reverse rotation switch 640 pushes the button portion of the reverse rotation switch 640 while the main power supply is "on", the output shaft 311 of the motor 310 is reversely driven. Further, in conjunction with this, the lower compression roller 313 is also reversely rotated. In the present embodiment, the rotational direction of the output shaft 311 and the lower compression roller 313 at the time of reverse rotation rotates in the counterclockwise direction shown in FIG. 2, FIG. 5 and FIG. The upper surface portion of the belt conveyor 340 wound around the lower compression roller 313 is operated to move from the discharge side N to the input side M.
The upper compression roller 440, the first paddle 420 and the second paddle 430, which are driven in conjunction with the lower compression roller 313, rotate clockwise as shown in FIGS. It operates to push the object K on the conveyor 340 back to the input side M.

  The reverse operation of the transport unit 3 and the compression unit 4 at the reverse switch 640 operates only when the operator presses the button portion of the reverse switch 640, and when stopping the reverse operation, the operator It is stopped by releasing the reverse switch 640. The reverse rotation operation is used to reverse the drive of the apparatus when removing an abnormality that has occurred in the transport process of the transport unit 3 and the compression process of the compression unit 4.

  The emergency stop switch 650 is used when the driving of the box compression device 1 such as the empty cardboard box is to be emergency stopped, and the electric circuit is cut off by pushing the button portion of the emergency stop switch 650. The driving of the box compacting device 1 such as the empty cardboard box is all stopped. In order to restart the driving of the box-like object compression device 1 such as the empty cardboard box, the connection of the electric circuit is restored by turning the button portion of the emergency stop switch 650, and the box such as the empty cardboard box etc The drive of the object compression device 1 is again possible.

The limit switch 660 is provided in the vicinity of the emergency stop switch 650, and is fixed so that the protrusion 661 protrudes from the switch box 610 and the right side frame 23R. The protruding portion 661 of the limit switch 660 is pushed into the inside of the limit switch 660 when the door 520 is in a closed state, whereby the electric circuit is in a connected state. On the contrary, when the door 520 is in the open state, the projecting portion 661 pushed into the inside of the limit switch 660 protrudes and the electric circuit is in the cut off state.
That is, when the door 520 is opened, the driving of the conveyance unit 3 and the compression unit 4 is stopped by the interruption of the electric circuit, and when the door 520 is closed, the conveyance unit 3 and the compression unit 4 can be driven by the connection of the electric circuit. It becomes a state. In the case where the door 520 is suddenly opened, consideration is given to safety so that the operator is not caught in the transport unit 3 and the compression unit 4.

  Further, in the electric circuit (not shown), a shutoff circuit (not shown) is configured to automatically shut off the electric circuit when the motor 310 is overloaded. The box-like object compression device 1 such as the empty cardboard box is protected from overload when the transport unit 3 and the compression unit 4 are in an abnormal state.

  The box-shaped object compression apparatus 1 such as the empty cardboard box configured as described above inserts the object K from the insertion section 5 and performs the switch operation at the operation section 6 to move the transport section 3 To drive. The object K is conveyed in the downstream direction by the belt conveyor 340 of the conveyance unit 3, and the first paddle 420, the second paddle 430, the upper compression roller 440, and the lower compression roller of the compression unit 4 are conveyed. After being compressed at 313, the belt conveyor 340 is discharged from the end of the discharge side N.

The working method of compressing the object K by the box-like object compacting apparatus 1 such as the empty cardboard box will be described in the first embodiment.
When the operator turns on the power switch 620 of the switch box 610 and presses the forward switch 630, the motor 310 is forward driven, and the transport unit 3 and the compression unit 4 are also forward driven simultaneously. Do. That is, the upper surface portion of the belt conveyor 340 moves from the input side N to the discharge side N, and the first paddle 420, the second paddle 430, and the upper compression roller 440 are as shown in FIGS. Rotate counterclockwise as shown.
In order to load the object to be compressed K from the input unit 5, the door 520 is opened and the object to be compressed K is temporarily placed on the table 510. While the door 520 is opened, the motor 310 stops driving by the blocking operation of the electric circuit of the limit switch 660, and the belt conveyor 340 of the conveyance unit 3 and the first paddle of the compression unit 4 are stopped. The second paddle 430 and the upper compression roller 440 simultaneously stop driving. The operator moves the object K temporarily placed on the table 510 to the upstream side of the upper surface of the belt conveyor 340 whose driving has been stopped.

When the door 520 is closed by the operator and the input unit 5 is closed, an electric circuit is connected by the limit switch 660, and the motor 310 starts the forward rotation drive again. The belt conveyor 340 of the transport unit 3, the first paddle 420 and the second paddle 430 of the compression unit 4, and the upper compression roller 440 simultaneously start forward rotation.
The to-be-compressed object K on the belt conveyor 340 moves to the discharge side N on the downstream side with the movement of the belt conveyor 340, and is primarily compressed by the rotation of the first paddle 420. The primary-compressed object K further moves downstream with the movement of the belt conveyor 340 and is secondary-compressed by the rotation of the second paddle 430. The second-compressed object K is further compressed than at the time of primary compression, and is moved downstream by the belt conveyor 340, and the final compression is performed by the rotation of the upper compression roller 440 and the lower compression roller 313. Be done. The compressed object K finally compressed is pushed out and discharged to the discharge side M by the rotation of the upper compression roller 440 and the lower compression roller 313 and the movement of the belt conveyor 340 to the downstream side, whereby the object K is compressed. The object K compression process is completed.
When the compression operation of the object K is completed, the forward rotation switch 630 is pressed again to stop the driving of the transport unit 3 and the compression unit 4. Further, the power switch 620 is turned off to shut off all the power of the box-like object compressor 1 such as the empty cardboard box, and all the work is completed.

On the other hand, when the worker unexpectedly opens the door 520 during the compression process of the object K, the electric circuit is cut off by the limit switch 660, and the driving of the conveyance unit 3 and the compression unit 4 is stopped. Do.
Also, during the compression process of the object to be compressed K in the box-like object compression apparatus 1 such as the empty cardboard box, if the transport unit 3 and the compression unit 4 are overloaded due to biting of foreign matter, etc. The conveying unit 3 and the compression unit 4 automatically stop driving by a cutoff circuit (not shown) configured in the circuit.

When an abnormality such as a foreign object biting in the conveyance unit 3 or the compression unit 4 occurs, the operator presses the reverse rotation switch 640 to remove the abnormality. The reverse drive is performed, and the foreign matter is pushed back. That is, the upper surface portion of the belt conveyor 340 moves from the discharge side N to the input side N, and the first paddle 420, the second paddle 430, and the upper compression roller 440 are shown in FIGS. Rotate clockwise to push back the foreign matter. After moving to a position where the pushed-back foreign matter can be collected, the operator releases the reverse rotation switch 640 to stop the driving of the transport unit 3 and the compression unit 4 and then collects the foreign matter.
Furthermore, in the case where the box-like object compression apparatus 1 such as the empty cardboard box is to be urgently stopped during the process of compressing the object K, the electric circuit is shut off by pushing the emergency stop switch 650 Stop it.

  In the first embodiment, the box compacting apparatus 1 such as the empty cardboard box configured as described above compresses a box compact compact K such as the empty cardboard box with a simple and low-cost device. The operator can easily compress and reduce the volume of a box-shaped object, such as an empty cardboard box, by compressing the object K by placing the object K on the belt conveyor 340 from the input unit 5 and operating the switch. It can be performed.

Therefore, the invention according to the first embodiment consists of the following.
A belt conveyor for placing and transporting a box-shaped object to be compressed;
A lower compression roller disposed downstream of the belt conveyor, around which the belt conveyor is wound, and disposed parallel to the rotation axis of the lower compression roller above the lower compression roller and cooperated with the lower compression roller An upper compression roller for compressing the object conveyed by the belt conveyor;
A first paddle disposed parallel to the rotation axis of the upper compression roller and disposed upstream of the belt conveyor;
A second paddle provided parallel to the rotation axis of the first paddle, and located downstream of the belt conveyor from the first paddle and upstream of the upper compression roller;
Equipped with
The rotation axis of the first paddle is positioned above the rotation axis of the second paddle, and the rotation axis of the second paddle is positioned above the rotation axis of the upper compression roller, and is conveyed by the belt conveyor The object to be compressed is fed while being gradually compressed by the first paddle and the second paddle, compressed by the lower compression roller and the upper compression roller, and then discharged from the end of the belt conveyor. A box compactor.

Furthermore, in the first embodiment,
In the first paddle and the second paddle, a plurality of projecting plates are provided radially outward from the rotation axis, and a flat portion of the projecting plate is formed of the first paddle and the second paddle. It is a box-like object compacting device characterized in that it is oriented in a rotational direction and compresses the material to be compressed which has been conveyed by the belt conveyor.

Furthermore, in the first embodiment,
The outer peripheral diameter of the second paddle is smaller than the outer peripheral diameter of the first paddle.

Furthermore, in the first embodiment,
The rotation speed of the second paddle is set equal to the rotation speed of the first paddle.

Furthermore, in the first embodiment,
A door is provided upstream of the belt conveyor, and when the door is opened, the belt conveyor, the lower compression roller, the upper compression roller, the first paddle, and the two paddles stop operating. It is a box-like thing compression device characterized by.

Therefore, the invention according to the first embodiment has the following effects.
According to the invention of the first embodiment, the apparatus for compressing and reducing the volume of the box required for the recovery of the box is provided with an inexpensive structure, and the operator can easily compress the box. Can do

A second embodiment which is an embodiment of the present invention will be described on the basis of FIGS.
In the second embodiment, the first installation plate 425 is provided between the adjacent first projecting plates 422. In addition, a second installation board 434 is provided between the adjacent second projection boards 432. The other configuration is the same as that of the first embodiment in the operation and effect.
From the first paddle shaft portion 421 serving as the rotation shaft of the first paddle 420 and the second paddle shaft portion 431 serving as the rotation shaft of the second paddle 430, a plurality of first protrusions provided radially outward A plate 422 and a second projecting plate 432 are provided.

The tips of the plurality of first projecting plates 422 and the second projecting plate 432 on the rotation outer peripheral side are the rear sides of the first projecting plates 422 and the second projecting plates 432 on the front side in the rotational direction. A first construction board 425 and a second construction board 434 are provided so as to bridge the front surfaces of the adjacent first and second projecting boards 422 and 432 in the direction of rotation from the surface.
The diameters of the outer peripheries of the first and second installation plates 425 and 434 are the same as those of the first and second projection plates 422 and 432 to which the first and second installation plates 425 and 434 are attached. It is provided smaller than the rotation outer diameter.

The projecting length of the first projecting plate 422 of the first paddle 420 is longer than the projecting length of the second projecting plate 432 of the second paddle 430.
Therefore, when the object K is compressed by the first construction board 425 and the second construction board 434, empty cardboard etc. compressed by the first construction board 425 and the second construction board 434 being pushed back to the rear (door 520 side) The movement of the object K can be suppressed by the long projecting portion of the first projecting plate 422 of the first paddle 420. Therefore, there is an effect that the compressed material K, which is an empty cardboard box, can be captured reliably and sent to the next process.

The rotational outer peripheral speed of the first paddle 420 is faster than the belt conveyor 340 speed.
Therefore, the upper part of the object to be compressed K which is a box-like object such as an empty cardboard box primarily compressed by the first paddle 420 is caught by the projection of the first projecting plate 422 of the first paddle 420 and is relative In the forward direction from the belt conveyor 340. As a result, since the compressed material K, which is an empty cardboard box, is compressed so as to be crushed or torn, the load required to compress the compressed material K, which is an empty cardboard box that is simply compressed up and down, is required. It can be reduced. By reducing the load, the required power can be kept low, which contributes to the downsizing of the device.
The same applies to the first embodiment illustrated in FIGS. 1 to 7 (see the description of [0064]).

The rotational outer peripheral speed of the second paddle 430 and the projecting length of the second projecting plate 432 will be described.
Unlike the first paddle 420, the cardboard or other compressed object K compressed by the second paddle 430 is compressed to a certain extent. Alternatively, the object to be compressed K, which is an empty cardboard box of a small size that could not be compressed by the first paddle 420, is targeted.
Therefore, in the second paddle 430, it is not necessary to grind it actively, and emphasis is placed on the compression of the object K, which is an empty cardboard box sent by the belt conveyor 340, as it is. Therefore, the projecting length of the second projecting plate 432 is not as necessary as that of the first paddle 420, and aims only at the effect of capturing the object to be compressed K which is a compressed empty cardboard box or a small sized cardboard.

As in the first embodiment, the rotational outer peripheral speed of the second paddle 430 of the second embodiment is substantially the same as the transport speed of the belt conveyor 340 (see the description of [0060]). Also in the case of the second embodiment, the transport speed of the belt conveyor 340 is set to about 15 m / min to 30 m / min.
Due to the coincidence of the rotational outer peripheral speed and the conveyance speed, the upper compression roller 440 and the lower portion are not supplied to the upper compression roller 440 located on the discharge side N of the second paddle 430 by splashing over the compressed object K. The clogging of the object K between the compression rollers 313 is prevented.

A third embodiment which is an embodiment of the present invention will be described based on FIG. 11 to FIG. 15 and FIG.
In the third embodiment, one third paddle 480 is provided. 481 is a third paddle shaft portion. Reference numeral 482 denotes a third projecting plate, and 483 a third mounting plate.
In the third embodiment, as in the second embodiment, the third installation plate 483 is provided between the adjacent third projecting plates 482. Others are similar to the first embodiment and the second embodiment in the operation and effect.
The paddle consists of one third paddle 480, which is an intermediate size of the first paddle 420 and the second paddle 430 of the second embodiment.

In the upper compression roller 440 illustrated in FIGS. 14 and 15, four projections 442 are provided in parallel at regular intervals in the surface axial direction.
The cross-sectional size of the protrusion 442 is a 9 mm square.
Since the projection 442 is provided, the cardboard may slip by the circular roller alone and may not be effectively drawn backward, so it has a role to prevent such a phenomenon.
Further, by strongly compressing locally by the projecting portion 442, a phenomenon that the corrugated portion “Koshi” enters in the compression portion and the cardboard after compression by the upper compression roller 440 tries to expand again is prevented. Simply by narrowing the gap between the upper and lower compression rollers 440 and 313, the load required for compression becomes high, and as a result, the required power is increased and the apparatus itself is prevented from being enlarged.

As illustrated in FIG. 16, when one first paddle 420 without the installation board is provided, the corner A of the object to be compressed K may stand, and therefore it may not be caught by the upper compression roller 440.
On the other hand, as illustrated in FIG. 17, when the third installation plate 483 is provided between the adjacent third projecting plates 482 like the third paddle 480, the third paddle 480 is used. It is possible to crush the corner A of the object K to be compressed. Therefore, in the next step, the object K is reliably attracted to the rotation of the upper compression roller 440.
In the third embodiment, since the projections 442 are provided on the upper compression roller 440 in parallel in the surface axial direction at equal intervals, the object K can be reliably sent backward and compressed reliably.

  The present invention can be applied to a compression apparatus for compressing and reducing a paper package and a paper packaging container in addition to an empty cardboard box.

DESCRIPTION OF SYMBOLS 1 Box-like material compression apparatus 2 Frame part 210 Base frame 23 L Side frame left 23 R Side frame right 3 Conveying part 310 Motor 313 Lower compression roller 340 Belt conveyor 4 Compression part 420 1st paddle 422 1st projecting plate 425 1st Construction plate 430 Second paddle 432 Second projection plate 434 Second construction plate 440 Upper compression roller 480 Third paddle 482 Third projection plate 483 Third construction plate 5 Entry portion 520 Door 6 Operation portion 620 Power switch 630 Forward rotation Switch 640 Reverse switch 650 Emergency stop switch 660 Limit switch K Compressed object

Claims (8)

A belt conveyor for placing and transporting a compacted object such as a box-like material;
A lower compression roller disposed downstream of the belt conveyor and having the belt conveyor wound thereon;
An upper compression roller disposed above the lower compression roller and in parallel with the rotational axis of the lower compression roller, and cooperating with the lower compression roller to compress the object conveyed by the belt conveyor; ,
And one or more paddles provided parallel to the rotational axis of the upper compression roller and disposed upstream of the belt conveyor,
The rotational axis of the paddle is positioned above the rotational axis of the upper compression roller,
The compressed material conveyed by the belt conveyor is fed while being gradually compressed by a paddle, compressed by the lower compression roller and the upper compression roller, and then discharged from the end of the belt conveyor.
A box compactor characterized by The paddle is
A first paddle disposed parallel to the rotation axis of the upper compression roller and disposed upstream of the belt conveyor;
And a second paddle provided parallel to the rotation axis of the first paddle and located downstream of the belt conveyor from the first paddle and upstream of the upper compression roller.
The rotation axis of the first paddle is positioned above the rotation axis of the second paddle,
The box-like object compacting apparatus according to claim 1, wherein the rotation axis of the second paddle is positioned above the rotation axis of the upper compression roller. The paddles are provided with a plurality of projecting plates radially outward from the rotation axis,
The flat portion of the projecting plate is directed in the rotational direction of the paddle,
Compressing the compressed object conveyed by the belt conveyor;
The box-like object compression device according to claim 1 or 2, characterized in that: The tip of each of the plurality of protruding plates provided radially outward from the rotation axis of the paddle is rotated backward from the rear surface of the protruding plate on the front side in the rotation direction A construction board provided to bridge the front surface of the projecting board on the side;
And further
The diameter of the outer periphery of rotation of the installation plate is smaller than the diameter of the outer periphery of the protrusion plate on which the installation plate is mounted.
The box-like object compacting device according to claim 1 and / or claim 2 or claim 3 characterized in that. The outer peripheral diameter of the paddle is set to be larger than the outer peripheral diameter of the upper compression roller.
The box-shaped material compacting device according to any one of claims 1 or 2 or claim 3 characterized in that. The number of revolutions of the paddle is set smaller than the number of revolutions of the upper compression roller.
The box-shaped material compacting device according to any one of claims 1 or 2 or claim 3 or claim 4 or claim 5 characterized in that. A door is provided upstream of the belt conveyor,
When the door is opened, the belt conveyor, the lower compression roller, the upper compression roller, and the paddle stop operating.
The box-shaped material compacting device according to any one of claims 1 or 2 or claim 3 or claim 4 or claim 5 or claim 6, characterized in that: On the outer peripheral portion of the compression roller, a plurality of projections attached with a length substantially the same as the length of the roller portion of the compression roller,
The box compacting device according to any one of claims 1 or 2 or 3 or 4 or 5 or 6 or 7.

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