JP2013086918A - Conveyance device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a conveyance device that can not only simplify the processes required for expansion and extension of a line but also reduce the manufacture cost.SOLUTION: The conveyance device equips a drive mechanism 40 and a follower mechanism 60 that push out slats 30 positioned on the further downstream side than slats 30A and 30D by not only folding back the slats 30 one by one without inverting the up and down faces of the slats 30 but also by giving the drive power to the slat 30A positioned at the back end part of a conveyance part 2 and th slat 30D positioned at the front end part of a backward feeding part 3 via respective inside link plates 52 and 72.

Description

  The present invention relates to a transport device, and more particularly to a transport device using a slat conveyor.

  2. Description of the Related Art Conventionally, for example, in an automobile assembly facility or a distribution facility, a transport device using a so-called slat conveyor in which a plurality of slats (transport plates) are spanned between a pair of chains is used (for example, Patent Document 1). See). In the transport device, the workpiece is transported by driving the chain with the workpiece placed on the upper side of the slat, or the worker is moved by driving the chain with the worker standing on the upper side of the slat. Or let it be.

  The conveyance device described in Patent Document 1 fixes a slat to a chain via an attachment plate. For this reason, as shown in FIG. 24, it is necessary to wind the chain around the sprockets 243 disposed at the upstream end and the downstream end in the conveying direction of the slat 230 (the chain trajectory shown in FIG. 24). 244T). That is, in the transport device described in Patent Document 1, it is necessary to dispose the chain over the entire circumference of the transport trajectory of the slat 230.

For this reason, when expanding or extending the line, it is necessary to separate the chain from the sprocket 243 and perform extension or shortening. That is, the process required for widening and extending the line is complicated.
In addition, a special chain having a length corresponding to the number of slats 230 is required, which increases the manufacturing cost.

JP 2009-286545 A

  The present invention has been made in view of the circumstances as described above, and provides a transport apparatus that can simplify the steps required to widen or extend a line and reduce manufacturing costs.

  In Claim 1, while moving the several slat in which an engaging part is formed continuously in a conveyance direction along a conveyance part, the distance longer than the thickness of the said slat is separated with respect to the said conveyance part. A transfer device that continuously moves in a direction opposite to the transfer direction along a reverse feed portion that is arranged in an upstream end portion in the transfer direction of the transfer portion, and engages with the slats An slat from the downstream end in the transport direction of the reverse feed section to the upstream end in the transport direction of the transport section. And an engaged portion that engages with the engaging portion of the slat is formed at an upstream drive mechanism that engages the upstream engaging member and a downstream end portion in the conveying direction of the conveying portion. A downstream engagement member is provided and transported by the transport unit A downstream drive mechanism that engages the slat with the downstream engagement member from a downstream end in the direction to an upstream end in the transport direction of the reverse feed portion, the slat being transported The upstream drive mechanism is disposed in the transport unit and the reverse feeding unit in a state adjacent to each other in the direction, and the upstream drive mechanism is configured to reverse the upper and lower surfaces of the slats one by one, the reverse feeding unit one by one. The driving force is applied to the slat located at the upstream end in the transport direction of the transport unit via the upstream engagement member. The slats located on the downstream side in the transport direction of the transport unit are pushed out from the slats, and the downstream drive mechanism moves the slats one by one without inverting the upper and lower surfaces of the slats. By moving the recording unit from the conveying unit to the reverse feeding unit and applying a driving force to the slat located at the upstream end in the conveying direction of the reverse feeding unit via the downstream engaging member, The slat located on the downstream side in the transport direction of the reverse feeding unit is pushed out from the slat to which a driving force is applied.

  According to a second aspect of the present invention, each drive mechanism is disposed at an inner end member disposed at an inner end portion in the transport direction of each drive mechanism, and at an outer end portion in the transport direction of each drive mechanism. An outer end member that is wound around each end member so as to be rotatable in the transport direction at a side portion orthogonal to the transport direction of the slats, and for each width in the transport direction of the slats. And an annular chain that supports the engaging member.

  According to a third aspect of the present invention, at least one of the end members of each driving mechanism is constituted by a sprocket to which a driving force is applied by a predetermined driving source.

  In Claim 4, the said slat forms the engaging pin extended from the side part of the direction orthogonal to a conveyance direction as said engaging part, and each engaging member of each said drive mechanism is one side part. Extends toward the engagement pin, and a recess that is recessed at the extension portion so as to be engageable with the engagement pin is formed as the engaged portion.

  According to a fifth aspect of the present invention, the engaged portion of each engaging member of each driving mechanism is formed on the non-contact side of each end member.

  According to a sixth aspect of the present invention, each engagement member of each drive mechanism is supported so as to be rotatable relative to the chain, with a direction orthogonal to the transport direction as a rotation axis direction.

  According to a seventh aspect of the present invention, each chain of each drive mechanism is configured as an annular chain by connecting a plurality of chopped chains having a length corresponding to the width in the conveying direction of the slats by a plurality of joint links. The joint link includes a plate located at an upstream end in the conveying direction of one of the two chopped chains, and a downstream end in the conveying direction of the other chopped chain. The plate located between the two is separated by a link plate and supported by a connecting pin, thereby connecting the two different chains. The engagement members of the drive mechanisms are members supported by the connecting pin. It is comprised by forming the said to-be-engaged part.

  In claim 8, each engagement member of each drive mechanism has a reference hole through which a connecting pin for supporting a plate located at a downstream end in the conveying direction of the chopped chain is inserted, and the chopped piece A connecting pin that supports a plate located at an upstream end in the transport direction of the chain is inserted, and a long-hole-like sub-reference hole that allows the connecting pin to slide along the vertical direction is formed, It rotates relative to the chain around a connecting pin inserted through the reference hole.

  According to a ninth aspect of the present invention, each chain of each of the driving mechanisms extends from a side portion in a direction orthogonal to the transport direction for each width in the transport direction of the slats, and extends to support the engagement members. A pin is attached.

  According to a tenth aspect of the present invention, each engaging member of each driving mechanism rotates relative to the chain around the extension pin.

  In claim 11, a sliding pin is attached to each engaging member of each driving mechanism on the side opposite to the side on which the concave portion is formed with respect to the extension pin. A cam guide that slides the sliding pin and varies a distance of the sliding pin with respect to the extension pin at an inner end in a conveying direction of each chain; When engaging with a member and when detaching the slat from the engagement member, the engagement member is rotated in a direction to release the recess of the engagement member from the engagement pin of the slat. , That is.

  According to a twelfth aspect of the present invention, the circular trajectory of each chain of each drive mechanism converges toward the upper and lower central portions of the circular trajectory of each chain as it goes inward in the transport direction.

  According to a thirteenth aspect of the present invention, each of the drive mechanisms sets the outer diameter of the inner end member to be smaller than the outer diameter of the outer end member, and the center of each of the end members is the same height. Set the position.

  In Claim 14, in the circumference track of each chain of each drive mechanism, it is formed in the shape of a straight line along the conveyance direction at the outer end in the conveyance direction, and the distance more than the width in the conveyance direction of the slats And a curved portion that swells in a curved shape on the outer side in the vertical direction is formed on the inner side in the transport direction than the linear portion.

  16. The drive mechanism according to claim 15, further comprising a chain guide disposed on the inside of each chain and formed with upper and lower surfaces each having a shape corresponding to a circular trajectory of each chain. Each of the chains draws a predetermined trajectory by sliding on the upper and lower surfaces of each chain guide.

  According to a sixteenth aspect of the present invention, any one of the drive mechanisms circulates the chain by a predetermined drive source to apply a driving force to the slats, and the other of the drive mechanisms is connected to the drive mechanism. A driving force is applied to the slat by rotating the chain with a driving force from one side.

  The drive mechanism includes a plurality of chains arranged on a side portion in a direction orthogonal to the conveying direction of the slats, and at least one of the drive mechanisms includes the inner end member. A drive shaft that is configured by a sprocket and rotatably supports the inner end member is rotated to rotate each chain of each drive mechanism.

  In the present invention, since a general chain is disposed only at the upstream end and the downstream end in the slat conveyance locus, the process required for widening and extending the line can be simplified and the manufacturing cost can be reduced. , Has the effect.

The figure which shows a conveying apparatus typically. (A) Perspective view. (B) Left side view. The figure which shows a drive mechanism typically. (A) Left side view. (B) Front view. The figure which shows a coupling link. (A) Exploded perspective view. (B) Left side view. The figure which shows the shape of a chain guide, and the circling locus | trajectory of a chain. The left view which shows the state which provides a driving force to a slat. (A) The figure which shows a drive mechanism. (B) The figure which shows a driven mechanism. The left view which shows the motion of a slat. (A) The figure which shows the state at the time of a drive. (B) The figure after the drive. Explanatory drawing which shows operation | movement of the slat when moving to a reverse feed part from a conveyance part. (A) The figure which a rear-end part falls to a reverse feed part. (B) The front end moves in the vicinity of the transport section. (C) The figure which a front-end part moves in the reverse feed part vicinity. Explanatory drawing which shows the flow until the inner side link plate of a driven mechanism engages with a slat. (A) The figure which moves the winding part of an inner side sprocket. (B) The figure which moves a curve part. (C) The figure when engaged (d) The figure after engaging. (E) The figure rotated by being pressed by the slat. (F) The figure which moves a straight part. Explanatory drawing which shows the operation | movement which the inner side link plate of a driven mechanism rotates. Explanatory drawing which shows the rotational moment which acts on a chain. The left view which shows operation | movement of a conveying apparatus when a drive mechanism is not provided with a chain guide. (A) The figure which shows the state at the time of a drive. (B) The figure which an inner side link plate rotates. (C) The figure which the engagement pin dropped. Explanatory drawing which shows a state when the slat which provides a driving force to the chain of a driven mechanism transfers, when a linear part is not formed. (A) Schematic side view. (B) Enlarged view. The figure which shows a state when the slat which provides a driving force to the chain of a driven mechanism transfers. (A) Schematic left side view. (B) Enlarged view. The figure which shows the relationship between the sub reference | standard hole of the inner side link plate of a driven mechanism, and a connection pin when a curve part is not formed. (A) The figure which shows the position of an inner side link plate. (B) Enlarged view. The figure which shows the relationship between the sub reference | standard hole of the inner side link plate of a driven mechanism, and a connection pin. (A) The figure which shows the position of an inner side link plate. (B) Enlarged view. The disassembled perspective view which shows the 1st modification of a joint link. The disassembled perspective view which shows the 2nd modification of a joint link. The left view which shows the drive mechanism of 2nd embodiment. The front view of a drive mechanism. The figure which shows the shape of the chain guide of 2nd embodiment, and the circulation locus | trajectory of a chain. The exploded perspective view of a heart cam. Sectional drawing which shows the shape of a cam groove. Explanatory drawing which shows operation | movement when the heart cam of a driven mechanism engages with a slat. The figure which shows the conventional conveying apparatus.

  Below, the conveying apparatus 1 of 1st embodiment is demonstrated.

As shown in FIG. 1, the transport apparatus 1 drives a plurality of slats 30 on which a transported object is placed in an endless manner to transport the transported object (for example, a person, a product, a vehicle, or the like). This is a so-called slat conveyor.
The transport apparatus 1 includes a base plate 10, a transport frame 20, a plurality of slats 30, a drive mechanism 40, a driven mechanism 60, and the like.

  In the following, for convenience of explanation, the “front-rear direction of the transport device 1” is defined with the arrow F direction shown in FIG. Further, the “up and down direction of the transfer device 1” is defined with the arrow U direction shown in FIG. And the "left-right direction of the conveying apparatus 1" is prescribed | regulated by making the arrow L direction shown to Fig.1 (a) into the left direction.

  The base plate 10 is a member that is the basis of the transport apparatus 1. A frame or the like (not shown) for supporting the drive mechanism 40, the driven mechanism 60, and the like is fixed to the base plate 10.

  The transport frame 20 receives a load applied when the transported object is placed on the slat 30. A gap larger than the thickness of the slat 30 (the vertical dimension of the slat 30) is formed between the base plate 10 and the transport frame 20, and the slat 30 positioned on the upper surface of the base plate 10 passes through the gap. .

  As shown in FIGS. 1 and 2, the slat 30 is a substantially plate-like member made of plastic, iron, aluminum, or the like, and is disposed in the left and right central portion of the transport apparatus 1 with the plate surface facing the vertical direction. The An engagement pin 31 is attached to the slat 30.

The engagement pin 31 is formed in a substantially cylindrical shape and protrudes in the left-right direction from the left and right side portions on the front side of the slat 30.
In addition, the structure of the slat 30 is not limited to 1st embodiment, The structure which forms the axial part corresponding to the engaging pin 31 in the slat 30 may be sufficient.

  The slats 30 are disposed on the upper surfaces of the base plate 10 and the conveyance frame 20 in a state adjacent to each other in the front-rear direction.

The conveyance device 1 continuously moves the slats 30 positioned on the upper surface of the conveyance frame 20 in the forward direction, and continuously moves the slats 30 positioned on the upper surface of the base plate 10 in the rearward direction.
At this time, the transport device 1 moves the slats 30 that have moved forward from the front end of the transport frame 20 to the base plate 10. Further, the transport device 1 moves the slats 30 that have moved rearward from the rear end portion of the transport frame 20 to the transport frame 20.
Hereinafter, the operation of moving from the transport frame 20 to the base plate 10 and the operation of moving from the base plate 10 to the transport frame 20 are referred to as “folding operation”.

In the transport device 1, the upper surface of the transport frame 20 is formed as the transport unit 2, and the upper surface of the base plate 10 is formed as the reverse feed unit 3 that is spaced apart by a distance longer than the thickness of the slat 30.
Such a conveyance part 2 and the reverse feed part 3 are comprised by the smooth plane with a low friction coefficient so that the slat 30 can move smoothly.

The object to be transported is placed on a slat 30 located in the transport unit 2. That is, in the first embodiment, the front direction is the transport direction, and the rear direction is the direction opposite to the transport direction.
In the first embodiment, in the transport unit 2, the rear side is the upstream side in the transport direction, and in the reverse feed unit 3, the front side is the upstream side in the transport direction.

  The drive mechanism 40 performs a folding operation of the slats 30 and applies a driving force in the forward direction to the slats 30 located at the rear end of the transport unit 2. The drive mechanism 40 is disposed at the rear end (upstream end in the transport direction) of the transport unit 2. As shown in FIG. 2, the drive mechanism 40 includes a drive shaft 41, an inner sprocket 42, an outer sprocket 43, a chain 44, a chain guide 45, an outer frame 46, and the like.

The sprockets 42, 43, the chain 44, the chain guide 45, and the outer frame 46 are arranged symmetrically with respect to each other on the left and right sides of the transport device 1.
Therefore, only the sprockets 42 and 43, the chain 44, the chain guide 45, and the outer frame 46 arranged on the left side will be described below.

  The drive shaft 41 supports the inner sprocket 42 at both left and right ends with the left-right direction as the axial direction. The driving shaft 41 is given a driving force from a motor (not shown) and rotates the inner sprocket 42. Note that the drive source for rotating the drive shaft 41 may not be a motor.

  The inner sprocket 42 is disposed in front of the rear end portion of the transport frame 20 and is disposed below the engagement pin 31 of the slat 30. The outer diameter of the inner sprocket 42 is set to be smaller than the outer diameter of the outer sprocket 43.

  The outer sprocket 43 is disposed behind the inner sprocket 42 by a predetermined distance. The centers of the sprockets 42 and 43 are set at the same height position.

  The chain 44 is wound around the sprockets 42 and 43. A roller 44 a that can slide on the upper and lower surfaces of the chain guide 45 is attached to the chain 44. That is, the chain 44 is wound around the slat 30 in the left-right direction (direction perpendicular to the transport direction) so as to be rotatable in the transport direction.

That is, the inner sprocket 42 of the first embodiment functions as an inner end member disposed at the inner end in the transport direction of the drive mechanism 40.
Further, the outer sprocket 43 of the first embodiment functions as an outer end member disposed at an outer end in the transport direction of the drive mechanism 40.

As shown in FIGS. 2 and 3, the chain 44 is configured as an annular chain 44 by connecting a plurality of chopped chains having a length corresponding to the width in the conveying direction by a plurality of joint links 50. .
That is, in FIG. 3B, the plate 44 b shown on the front side and the plate 44 b shown on the rear side are plates of different chopped chains and are connected by the joint link 50.

  The joint link 50 includes an outer link plate 51, an inner link plate 52, two connecting pins 53 and 54, and a clip 55.

  The outer link plate 51 is formed in substantially the same shape as the plate 44b of the chain 44, and the left end portions of the connecting pins 53 and 54 are attached and fixed. The outer link plate 51 is disposed on the left side of the plate 44b of the chain 44.

The upper portion of the inner link plate 52 extends upward from the outer link plate 51. In other words, the inner link plate 52 has one side extending toward the engagement pin 31 of the slat 30. The inner link plate 52 is disposed on the right side of the plate 44 b of the chain 44.
The inner link plate 52 is formed with a recess 52a, a reference hole 52b, and a sub reference hole 52c.

  The recessed portion 52a as the engaged portion is formed at the front and rear central portions of the extending portion. The concave portion 52a is formed in a substantially tapered shape that gradually converges at the front and rear central portions of the inner link plate 52 as it goes downward. The bottom surface of the recess 52a is formed in substantially the same shape as the lower portion of the engaging pin 31 of the slat 30 (the lower semicircular portion of the engaging pin 31 of the slat 30 divided into two vertically).

  That is, the recessed part 52a of the inner link plate 52 is formed to be able to engage with the engaging pin 31 of the slat 30 extending from the left side (the side in the direction orthogonal to the conveying direction) at the extending part. It is a depression.

  The reference hole 52b is a substantially circular hole that penetrates the inner link plate 52 in the left-right direction and has an inner diameter dimension substantially the same as the outer diameter dimension of each of the connecting pins 53 and 54. The reference hole 52b is formed on the downstream side (front side in FIG. 3) of the inner link plate 52.

The sub-reference hole 52c is formed on the upstream side (rear side in FIG. 3) of the inner link plate 52 and penetrates the inner link plate 52 in the left-right direction. The upper surface and the bottom surface of the sub reference hole 52c are formed in substantially the same shape as the upper surface and the bottom surface of the reference hole 52b (a semicircular portion on both the upper and lower sides of the reference hole 52b divided into two vertically).
The upper and bottom surfaces of the sub-reference hole 52c are linearly connected along the vertical direction, and the upstream connection pin 54 is formed in a long hole shape that can slide along the vertical direction.

The centers of the reference hole 52b and the sub-reference hole 52c are located at the same height. That is, the auxiliary reference hole 52c protrudes in the vertical direction from the reference hole 52b.
The inner link plate 52 secures rigidity by extending the downstream side of the sub-reference hole 52c downward with respect to the reference hole 52b in the downward direction from the upstream side.

The downstream connection pin 53 is inserted into the reference hole 52b and supports the plate 44b (the front plate 44b shown in FIG. 3B) located at the downstream end of the chopped chain.
The upstream connection pin 54 is inserted into the sub-reference hole 52c and supports the plate 44b (the rear plate 44b shown in FIG. 3B) located at the upstream end of the chopped chain.

  Here, since the upstream connecting pin 54 can slide along the sub-reference hole 52c in the vertical direction, the inner link plate 52 is centered on the downstream connecting pin 53 (the connecting pin inserted into the reference hole 52b). Further, it is configured to be rotatable relative to the chain 44.

  The clip 55 is formed in a shape that can be engaged with the connection pins 53 and 54, and is inserted into the connection pins 53 and 54 to function as a detachment stopper for the connection pins 53 and 54.

In this way, the joint link 50 is located at the upstream end of one of the two chopped chains and the downstream end of the other chopped chain. The plate 44 b is sandwiched between the link plates 51 and 52 from the left and right directions and supported by the connecting pins 53 and 54. As a result, the joint link 50 connects two different chopped chains.
The chain 44 thus supports the inner link plate 52 for each width in the transport direction of the slats 30.

  In this way, by using the chain 44 wound around each sprocket 42 and 43 (each end member), the transport device 1 has a simple configuration and the inner link plate 52 for each width in the transport direction of the slat 30. I can support it.

  In addition, the conveying apparatus 1 does not necessarily need to be the structure which winds the chain 44 to each sprocket 42 * 43, For example, you may use a belt, a pulley, etc.

  As shown in FIGS. 2 and 4, the chain guide 45 supports the chain 44. The chain guide 45 is a substantially plate-like member disposed inside the chain 44. The front and rear end portions of the chain guide 45 extend to the vicinity of the sprockets 42 and 43, and are formed in an arc shape that does not interfere with the rotation of the sprockets 42 and 43.

The chain 44 draws a predetermined trajectory as the roller 44 a slides on the upper and lower surfaces of the chain guide 45. That is, the upper and lower surfaces of the chain guide 45 are formed in a shape corresponding to the circular trajectory 44T of the chain 44.
A linear portion 44Ta and a curved portion 44Tb are formed on the circular trajectory 44T of the chain 44.

  The straight portion 44Ta is a portion that is formed linearly along the transport direction at the rear end portion (outer end portion in the transport direction) of the circular trajectory 44T of the chain 44. The straight portion 44Ta extends in the forward direction from the wound portion of the outer sprocket 43. The height position of the straight portion 44Ta corresponds to the height positions of the upper and lower ends of the wound portion of the outer sprocket 43.

The chain 44 goes around the straight portion 44Ta before and after going around the wound portion of the outer sprocket 43. The height position of the chain 44 does not fluctuate before and after turning around the wound portion of the outer sprocket 43.
Such a straight portion 44Ta is set to have a distance that is equal to or greater than the width in the conveying direction of the slats 30 (see symbols L1 and L2 shown in FIG. 13).

  The concave portion 52a of the inner link plate 52 is located at the same height as the engagement pin 31 of the slat 30 located in the transport unit 2 and the reverse feed unit 3 when moving the linear portion 44Ta. At this time, the slat 30 is engaged with the inner link plate 52.

The curved portion 44Tb is a portion formed in a curved shape on the front side (inner side in the transport direction) of the straight portion 44Ta. The curved portion 44Tb swells in a curved shape outward in the vertical direction from the front end of the straight portion 44Ta to the wound portion of the inner sprocket 42.
That is, the curved portion 44Tb gently swells with respect to a straight line connecting the front end portion of the straight portion 44Ta to the wound portion of the inner sprocket 42 (see the circular trajectories 64T and 64TB shown in FIG. 15).

  As shown in FIG. 2, the outer frame 46 is disposed apart from the rear and right sides of the outer sprocket 43, and is disposed below the engaging pin 31 of the slat 30. The front end surface of the outer frame 46 is recessed in a substantially arc shape, and the engagement pin 31 of the slat 30 can be sandwiched between the outer frame 46 and the recess 52a of the inner link plate 52.

As shown in FIG. 5, the driven mechanism 60 is configured symmetrically with respect to the drive mechanism 40 except that a driven shaft 61 is provided instead of the drive shaft 41. That is, the driven mechanism 60 is disposed at the downstream end in the transport direction of the transport unit 2.
Further, the rear end portion of the transport frame 20 is positioned in front of the upper end portion of the outer sprocket 63 by an interval corresponding to the width in the front-rear direction from the rear end portion of the slat 30 to the engagement pin 31.

  As described above, the transport apparatus 1 has a configuration in which the chains 44 and 64 are disposed only at the front and rear ends (see the circular trajectories 44T and 64T of the chains 44 and 64 shown in FIG. 1).

Next, the operation of the transport device 1 will be described.
In addition, the conveying apparatus 1 shall start the drive of the slat 30 from the state shown in FIG. 5 and FIG.

Hereinafter, among the slats 30 positioned in the transport unit 2, the slat 30 positioned at the upstream end is “slat 30A”, the slat 30 positioned at the downstream end is “slat 30C”, and between the slats 30A and 30C. The slat 30 located at is denoted as “slat 30B”.
In addition, among the slats 30 positioned in the reverse feed unit 3, the slat 30 positioned at the upstream end is referred to as “slat 30D”, and the slat 30 positioned downstream of the slat 30D is referred to as “slat 30E”.
The folded slat 30 is expressed as “slat 30R”.

  As shown in FIG. 5A, the transport device 1 applies a driving force to the drive shaft 41 to rotate the inner sprocket 42. Then, the outer sprocket 43 is rotated through the chain 44 to rotate the chain 44 (see the arrows shown in the sprockets 42 and 43 in FIG. 5A).

At this time, as shown in FIGS. 5 (a) and 6 (a), the slat 30A located at the upstream end of the transport section 2 has an inner link plate 52 whose engaging pin 31 engages with the recess 52a. Is moved forward. That is, the drive mechanism 40 applies a driving force to the slat 30A located at the upstream end of the transport unit 2 via the inner link plate 52 (see the force F1 shown in FIG. 5A).
In the state shown in FIG. 5A, the slat 30B located on the downstream side of the slat 30A located on the upstream end of the transport unit 2 is also engaged with the inner link plate 52. For this reason, the conveyance apparatus 1 will provide a driving force with respect to the total two sheets of slats 30A and 30B.

The slats 30 are arranged in the transport unit 2 in a state adjacent to the transport direction. For this reason, the drive mechanism 40 will push out the slats 30B and 30C located downstream from the slats 30A to which the drive force is applied (see arrow M1 shown in FIG. 6A).
As shown in FIG. 6B, the transport device 1 moves the slats 30 </ b> A, 30 </ b> B, and 30 </ b> C positioned in the transport unit 2 in the forward direction in this way.

As shown in FIGS. 5B and 6A, the slat 30 </ b> C located at the downstream end of the transport unit 2 is engaged with the inner link plate 72 of the driven mechanism 60. Accordingly, a driving force is applied to the chain 64 of the driven mechanism 60 via the inner link plate 72 that engages with the slat 30C (see force F2 shown in FIG. 5A).
As a result, the driven shaft 61 and the sprockets 62 and 63 rotate, and the chain 64 revolves (see the arrows shown for the sprockets 62 and 63 in FIG. 5B).

Due to the circulation of the chain 64, the driven mechanism 60 applies a driving force to the slat 30D located at the upstream end portion via the inner link plate 72 as in the case of the driving mechanism 40 (FIG. 5A). See force F3 shown).
And as shown in FIG. 6, the slat 30E located in the downstream of the reverse feed part 3 rather than the slat 30D to which a driving force is given is pushed out (see the arrow M2 shown in FIGS. 6 (a) and 6 (b)). ).

  At this time, the conveying device 1 performs the folding operation by moving the wound portions of the outer sprockets 43 and 63 with the folded slats 30R engaged with the inner link plates 52 and 72, respectively. Details of the folding operation will be described later.

  In this way, the drive mechanism 40 (one of the drive mechanism 40 and the driven mechanism 60) rotates the chain 44 by a predetermined drive source and applies a drive force to the slats 30. The driven mechanism 60 (the other of the driving mechanism 40 and the driven mechanism 60) rotates the chain 64 by the driving force from the driving mechanism 40 and applies the driving force to the slat 30.

  With this configuration, the slat 30 can be driven only by driving the drive shaft 41 of the drive mechanism 40 with a predetermined drive source. That is, it is not necessary to drive the driven shaft 61 of the driven mechanism 60 with a predetermined drive source. For this reason, while being able to reduce the cost of the conveying apparatus 1, the structure of the conveying apparatus 1 can be simplified.

  Note that the driven shaft 61 is not necessarily provided in the driven mechanism 60. However, it is preferable to dispose the driven shaft 61 from the viewpoint that the phase of the chain 64 of the driven mechanism 60 can be reliably matched.

As shown in FIG. 5 and FIG. 6, until the slat 30 </ b> A located at the upstream end of the transport unit 2 is separated from the inner link plate 52, the transport device 1 has the slats 30 </ b> B and 30 </ b> C positioned in the transport unit 2. Extrude
The slat 30A located at the upstream end of the transport unit 2 is detached from the inner link plate 52 when the inner link plate 52 circulates the curved portion 44Tb of the circular trajectory 44T of the chain 44 (see FIG. 4).

  As a result, the drive mechanism 40 moves the slats 30A, 30B, and 30C located in the transport unit 2 by one slat along the transport direction. The same applies to the driven mechanism 60.

When moved by one slat, the slat 30E located at the downstream end of the reverse feed unit 3 shown in FIG. 6 (a) is located at the upstream end of the transport unit 2 shown in FIG. 6 (a). It moves to the position of the slat 30A.
That is, the slat 30A located at the upstream end of the transport unit 2 shifts to the slat (slat 30E) located on the upstream side.

At this time, the slat 30C located at the downstream end of the transport unit 2 moves to the slat (slat 30B) located upstream. That is, the inner link plate 72 of the driven mechanism 60 is engaged with the slat 30 </ b> B located in the transport unit 2. Further, the inner link plate 52 of the drive mechanism 40 is engaged with the slat 30E located in the reverse feed portion 3.
And the slat 30D located in the upstream edge part of the reverse feed part 3 also transfers to the slat (slat 30C) located in the upstream.

  In this way, the transport device 1 engages the slats 30 with the respective inner link plates 52 and 72 at the downstream ends of the transport unit 2 and the reverse feed unit 3, and the transport unit 2 and the reverse feed unit 3. The slats 30 are detached from the inner link plates 52 and 72 at the upstream end.

That is, the drive mechanism 40 is an upstream drive mechanism that engages the slat 30 with the inner link plate 52 from the downstream end in the transport direction of the reverse feed unit 3 to the upstream end in the transport direction of the transport unit 2. Function. The inner link plate 52 functions as an upstream engagement member.
The driven mechanism 60 functions as a downstream drive mechanism that engages the slat 30 with the inner link plate 72 from the downstream end in the transport direction of the transport unit 2 to the upstream end in the transport direction of the reverse feed unit 3. . The inner link plate 72 functions as a downstream engagement member.

  The conveyance device 1 repeats the engagement and disengagement between the slat 30 and the inner link plates 52 and 72, thereby driving the slat 30 in an endless manner to convey the object to be conveyed.

  According to this, the conveying apparatus 1 can move the slat 30 only by disposing the chains 44 and 64 at both front and rear end portions (the upstream end portion and the downstream end portion in the conveying locus of the slat 30). Therefore, it is not necessary to provide a chain around the entire circumference of the transport locus of the slat 30 (see FIG. 24).

For this reason, it is not necessary to separate the chains 44 and 64 from the sprockets 42, 43, 62, and 62 for extending or extending the line. Further, it is not necessary to shorten the chains 44 and 64 in reducing the line.
That is, in the transfer apparatus 1, the line can be widened, extended, reduced, or the like simply by replacing the transfer frame 20 or the like. For this reason, it is possible to simplify a process required for widening, extending, or reducing the line.

  Further, the transport device 1 has a configuration in which the inner link plates 52 and 72 are engaged with the slat 30, in other words, a configuration in which the chains 44 and 64 are not directly engaged with the slat 30. For this reason, a general chain (for example, a commercially available roller chain) can be used as each of the chains 44 and 64.

That is, the transport device 1 has a configuration in which a general chain is disposed only at both front and rear ends of the transport device 1, so that the manufacturing cost of the transport device 1 can be reduced. Further, even when the number of slats 30 increases due to line extension or the like, the lengths of the chains 44 and 64 do not vary. That is, it is possible to reduce the cost required for work in extending the line.
Furthermore, it is possible to shorten the time required for manufacturing the transport device 1, and when the transport device 1 is used in an automobile assembly facility or the like, it is not necessary to have a spare stock of the chains 44 and 64.

  The slats 30 move in a state where they are separated from the inner link plates 52 and 72 in the work area (the slats 30B located in the middle part of the transport unit 2). For this reason, the conveying apparatus 1 can move the slat 30 without a gap in the work area.

According to this, the conveying apparatus 1 can prevent a gap from being generated between the slats 30 in the work area even when the chains 44 and 64 are extended. Accordingly, the transport device 1 can prevent the occurrence of a situation in which parts of the transported object fall and are sandwiched between the slats 30.
That is, the transport device 1 can prevent deterioration of workability due to the elongation of the chains 44 and 64. That is, the transport device 1 can improve workability.

Next, the folding operation of the slat 30R by the driven mechanism 60 (operation for moving from the transport unit 2 to the reverse feeding unit 3) will be described.
In FIG. 7, the chain guide 65 is not shown for easy viewing of the drawing.

As shown in FIG. 7A, the outer sprocket 63 is disposed in front of the transport frame 20. For this reason, when the slat 30 </ b> R moves to the upper end portion of the outer sprocket 63, the rear end portion falls from the transport unit 2 due to its own weight.
That is, the slat 30R rotates in the clockwise direction in FIG. 7A around the axis of the engagement pin 31.

When the inner link plate 72 moves around the wound portion of the outer sprocket 63, the slat 30R is supported by the inner link plate 72 and the outer frame 66 as shown in FIGS. 7B and 7C. Moving.
That is, the slat 30 </ b> R is folded back by the outer frame 66 without the engagement pin 31 falling from the recess 72 a of the inner link plate 72.

  Accordingly, the driven mechanism 60 moves the slats 30 one by one from the transport unit 2 to the reverse feeding unit 3 without reversing the upper and lower surfaces of the slats 30 (see the upper surface 30a of the slats 30R shown in FIG. 7).

  Further, the folding operation of the slat 30 by the drive mechanism 40 (the operation of moving the slat 30 from the reverse feeding unit 3 to the transport unit 2) is the same as that of the driven mechanism 60.

That is, the drive mechanism 40 rotates the front end portion of the slat 30 so as to follow the shape of the outer sprocket 43 when the inner link plate 52 moves through the wound portion of the outer sprocket 43, and transports it from the reverse feed portion 3. It inclines toward the part 2 (refer slat 30R shown in FIG.6 (b)).
Thereafter, the drive mechanism 40 further moves the inner link plate 52 to move the rear end portion of the slat 30 to the height of the transport unit 2 to complete the folding operation (see the slat 30A shown in FIG. 6A). ).

Thereby, the drive mechanism 40 moves the slats 30 from the reverse feed unit 3 to the transport unit 2 one by one without inverting the upper and lower surfaces of the slats 30.
That is, the transport device 1 is configured to move the slats 30 with the upper surface 30a of the slats 30 always facing up.

  Thus, by setting it as the structure which does not reverse the upper and lower surfaces of the slat 30, the outer-diameter dimension of each outer side sprocket 43 * 63 can be set to a dimension shorter than the width | variety in the conveyance direction of the slat 30 (refer FIG. 24). Accordingly, the width in the vertical direction of the transport device 1 can be reduced. That is, the transport device 1 can be made compact.

The chains 44 and 64 only need to be configured to be rotatable in the transport direction, and do not necessarily have to be wound around the four sprockets 42, 43, 62, and 63.
For example, in the drive mechanism 40 and the driven mechanism 60, instead of the inner sprocket 62 and the outer sprockets 43 and 63, predetermined rollers or the like that support the respective chains 44 and 64 so as to be able to go around are arranged, and the chain 44 is The chain 64 may be wound around the roller by winding around the roller and the inner sprocket 42. In this case, the drive shaft 41 supports the inner sprocket 42 and rotates the inner sprocket 42 by a predetermined drive source.

  That is, at least one of the members (each end member) around which each of the chains 44 and 64 is wound may be a sprocket to which a driving force is applied by a predetermined driving source.

  Thereby, since the number of each sprocket 42 * 43 * 62 * 63 can be reduced, the manufacturing cost of the conveying apparatus 1 can be reduced more.

  Here, if the driven shaft 61 is attached to the outer sprocket 63, the driven shaft 61 interferes with the folding operation of the slat 30.

In other words, in the configuration in which the chain is disposed on the entire circumference of the transport trajectory of the slat 30 as shown in FIG. 24, the sprocket around which the chain is wound is disposed at a position corresponding to each of the outer sprockets 43 and 63. Is done. Therefore, if the upper and lower surfaces of the slat 30 are folded without being inverted, the drive shaft cannot be disposed on the sprocket around which the chain is wound.
In this case, in addition to the sprocket on which the chain is wound, it is necessary to separately provide a driving sprocket, a chain, or the like, and apply the driving force to the sprocket.

On the other hand, the conveying device 1 can prevent the driven shaft 61 from interfering with the folding operation of the slat 30 only by arranging the driven shaft 61 of the inner sprocket 62.
From the above, among the members (each end member) around which the chains 44 and 64 are wound, the members constituted by the sprockets are disposed at the inner ends in the transport direction of the drive mechanism 40 and the driven mechanism 60. It is preferable that it is a member (inner side end member). Further, it is more preferable that the member is disposed at an inner end portion in the transport direction of the drive mechanism 40.

As described above, the drive mechanism 40 and the driven mechanism 60 are each provided with a plurality of chains 44 and 64 on the side portions in the left-right direction (direction orthogonal to the transport direction).
Further, in the drive mechanism 40 (at least one of the drive mechanism 40 and the driven mechanism 60), a member (inner end member) around which the chain 44 is wound at the inner end in the transport direction is configured by a sprocket, The drive shaft 41 that rotatably supports the sprocket (inner sprocket 42) is rotated to rotate the chains 44 and 64.

  According to this, it is not necessary for the transport apparatus 1 to dispose a driving sprocket or the like separately in order to drive the slat 30. For this reason, the conveyance apparatus 1 can make the structure simpler.

  In the first embodiment, the recesses 52a and 72a of the inner link plates 52 and 72 are formed on the non-contact side of the sprocket (each end member) around which the chains 44 and 64 are wound.

Here, the “non-contact side” means that when the inner link plates 52, 72 move in the winding portions of the sprockets 42, 43, 62, 63, the recesses 52 a, 72 a correspond to the sprockets 42, 43, 62.・ Points away from 63.
That is, when the inner link plates 52, 72 move around the wound portions of the sprockets 42, 43, 62, 63, the recesses 52a, 72a are formed on the radially outer side (outer peripheral side) of the sprockets 42, 43, 62, 63. Is located (see, for example, the inner link plate 72 shown in FIG. 7A).

  Thereby, it can prevent that the engaging pin 31 grade | etc., Of the slat 30 interferes with each sprocket 42 * 43 * 62 * 63.

Next, an operation when the slat 30B located in the transport unit 2 is engaged with the inner link plate 72 of the driven mechanism 60 will be described.
In addition, regarding the operation at the time of engagement, the same applies to the operation when the slat 30E located in the reverse feeding portion 3 is engaged with the inner link plate 52 of the drive mechanism 40.

  As shown in FIG. 8A, when the slat 30 </ b> B is moved to the rear of the inner sprocket 62, the inner link plate 72 moves in the winding portion of the inner sprocket 62.

When the slat 30B is further moved, the inner link plate 72 moves on the curved portion 64Tb of the circling locus 64T of the chain 64 as shown in FIG. 8B and FIG. At this time, the height position of the recess 72a is gradually adjusted to the height position of the engagement pin 31 of the slat 30B (see the inner link plate 72 shown at the rear end of FIG. 9).
Further, the inner link plate 72 rotates in the clockwise direction in FIGS. 8B and 9 until the sub-reference hole 72c and the downstream connection pin 74 abut on each other due to its own weight.

Here, since the slat 30B is pushed out by the inner link plate 72, the slat 30B and the inner link plate 72 move at the same speed.
For this reason, the slat 30B approaches the inner link plate 72 when the inner link plate 72 moves along the curved portion 64Tb of the circling locus 64T of the chain 64.

  As shown in FIGS. 8C and 9, the slat 30B catches up with the inner link plate 72 at the midway portion of the curved portion 64Tb of the circling locus 64T of the chain 64, and the engagement pin 31 and the recess 72a (Refer to the inner link plate 72 shown second from the rear in FIG. 9). That is, the slat 30B and the inner link plate 72 are engaged.

When the slat 30B is further moved from this state, as shown in FIGS. 8D and 9, the slat 30B tries to overtake the inner link plate 72 (the inner link plate shown in the front and rear center of FIG. 9). 72).
That is, the inner link plate 72 is pressed when the engagement pin 31 of the slat 30B comes into contact with the recess 72a.

  By this pressing, torque in the counterclockwise direction in FIGS. 8D and 9 is applied to the inner link plate 72. That is, the inner link plate 72 rotates (see arrow R shown in FIG. 9).

  Thereby, the inner side link plate 72 absorbs the forward pressing from the slat 30B.

As shown in FIGS. 8 (f), 8 (e), and 9, the concave portion 72a of the inner link plate 72 is engaged with the slat 30B when the chain 64 moves to the straight portion 64Ta of the circular locus 64T. The front and rear and vertical positions of the mating pin 31 are aligned (see the inner link plate 72 and the transport trajectory 30T of the slat 30B shown at the front end and the second from the front in FIG. 9).
Thereafter, the inner link plate 72 moves in the forward direction at the same speed as the slat 30B.

  That is, the driven mechanism 60 is configured such that the inner link plate 72 is rotatable relative to the chain 64 with the left-right direction (direction orthogonal to the transport direction) as the rotation axis direction. The contact between the recess 72a and the engaging pin 31 of the slat 30B is buffered.

  In other words, the transport device 1 uses the inner link plate 72 that is rotatable relative to the chain 64 as a downstream engaging member that engages with the slat 30 at the downstream end in the transport direction, thereby enabling engagement. Wear at the time can be reduced.

  As for the operation when the slat 30 is detached from the inner link plates 52 and 72, the conveying device 1 rotates the inner link plates 52 and 72 as in the case of the engagement, 52/72 wear is reduced.

The configuration for engaging the slat 30 is not limited to the first embodiment. For example, the inner link plate 52 may be attached to the slat 30 and a pin having substantially the same shape as the engagement pin 31 of the slat 30 may be attached to each of the chains 44 and 64.
However, from the viewpoint that the slat 30 can be engaged with the inner link plates 52 and 72 with a simple configuration, the transport device 1 forms the engagement pin 31 on the slat 30 and the recesses on the inner link plates 52 and 72. It is preferable that 52a and 72a be formed.

  Here, as shown in FIGS. 10 and 11, when driving of the slat 30 is started, the inner link plate 52 engaged with the slat 30 </ b> A located at the front end of the transport unit 2 is aligned along the transport direction. A couple acts (see the arrow to the left shown in FIG. 10). Due to this couple, a rotational moment along the counterclockwise direction in FIG. 10 acts on the chain 44 (see reference numeral M shown in FIG. 10).

  If the chain guide 45 is not provided as shown in FIG. 11A, the transport device 1 absorbs the rotational moment by the tension force of the chain 44.

In this case, as shown in FIGS. 10 and 11B, when the rotational moment exceeds the tension force of the chain 44, the inner link plate 52 rotates counterclockwise in FIGS. (Refer to the arrow in the counterclockwise direction shown in FIG. 10).
Then, as shown in FIGS. 10 and 11C, the slat 30A escapes from the inner link plate 52 (the engaging pin 31 drops from the recess 52a of the inner link plate 52), and drives the slat 30. Can not.

  Therefore, in the transport device 1, the rotational moment is supported by the chain guide 45 by disposing the chain guide 45 inside the chain 44. The same applies to the driven mechanism 60.

  Thereby, the slat 30 can be reliably driven without dropping from the inner link plates 52 and 72 during driving.

  It is not always necessary to form the straight portions 44Ta and 64Ta and the curved portions 44Tb and 44Tb on the circular trajectories 44T and 64T of the chains 44 and 64, respectively. For example, as shown in FIG. 12, it may have a shape like a circular locus 64TA that linearly connects the wound portions of the sprockets 62 and 63.

In this case, when the slat located at the downstream end of the transport unit 2 moves from the slat 30R to the slat 30C, there is a clearance between the engagement pin 31 of the slat 30C and the recess 72a of the inner link plate 72. C may be formed.
That is, the timing at which the slat 30C is engaged with the inner link plate 72 may be delayed.

When the clearance C is formed, it becomes impossible to apply a driving force to the chain 64 by the slat 30C. That is, the transport device 1 needs to push out the slats 30 in a state where the number of slats 30 to which the driving force is applied is reduced by one.
That is, a large load is applied to each of the inner link plates 52 and 72 for pushing out the slat 30 (for example, the inner link plate 52 engaged with the slat 30A located at the upstream end of the transport unit 2).

  In such a case, the chains 44 and 64 cannot withstand the large load, and the slats 30 engaged with the link plates 52 and 72 escape (separate). In this case, since the chains 44 and 64 are idle, the transport device 1 cannot drive the slat 30.

  Even if the chains 44 and 64 can withstand the large load, the engagement timing between the slat 30C and the inner link plate 72 is delayed, and the slat 30 pulsates.

On the other hand, as shown in FIG. 13, when the straight portion 64Ta is formed on the circular trajectory 64T of the chain 64, the position where the slat 30C and the inner link plate 72 are engaged can be shifted to the upstream side and the engagement timing can be advanced. it can.
Accordingly, the transport device 1 can engage the slat 30B positioned on the upstream side with the inner link plate 72 before the slat 30C positioned on the downstream end of the transport unit 2 moves.
Thereby, the conveying apparatus 1 prevents the clearance C from occurring. The same applies to the case where the straight portion 44Ta is not formed in the circular locus 44T of the chain 44 of the drive mechanism 40.

As described above, from the viewpoint that the idle rotation of the chains 44 and 64 and the pulsation of the slat 30 can be prevented, it is preferable that the straight portions 44Ta and 64Ta are formed in the circular trajectories 44T and 64T of the chains 44 and 64.
The straight portions 44Ta and 64Ta are preferably longer than the width in the conveying direction of the slats 30 (see symbols L1 and L2 shown in FIG. 13). As a result, the idle rotation of the chains 44 and 64 and the pulsation of the slats 30 can be prevented more reliably.

  For example, as shown in FIG. 14, the circular trajectories 44T and 64T of the chains 44 and 64 have a shape like a circular trajectory 64TB that linearly connects the wound portion of the inner sprocket 62 to the rear end portion of the straight portion 64Ta. It does not matter.

  In this case, the inner link plate 72 is pressed further forward by the slats 30B located in the transport unit 2 as compared with the case where the curved portion 64Tb is moved.

Therefore, as shown in FIGS. 14 and 15, the inner link plate 72 rotates more greatly. That is, there is a possibility that the downstream connection pin 74 may come into contact with the bottom surface of the sub-reference hole 72 c of the inner link plate 72.
For this reason, it is necessary to increase the vertical dimension of the auxiliary reference hole 72c of the inner link plate 72 to such an extent that the downstream connection pin 74 does not come into contact therewith.

That is, the strength of the inner link plate 72 may be reduced as compared with the case where the curved portion 64Tb is formed.
Further, when the inner link plate 72 is largely rotated at the time of engagement, the mechanical friction is increased, so that the life of the inner link plate 72 may be shortened.

That is, it is preferable to form the curved portion 64Tb in the circular trajectory 64T of the chain 64 from the viewpoint that the strength of the inner link plate 72 can be prevented from decreasing and the life of the inner link plate 72 can be extended.
The same applies to the drive mechanism 40. The same applies to the case where the slat 30 is detached from the inner link plates 52 and 72.

  The circular trajectories 44T and 64T of the chains 44 and 64 each have a track shape (see the circular trajectory 144T shown in FIG. 20) in which the chain is wound around a sprocket having the same diameter and the wound portions of the sprockets are linearly connected. It doesn't matter.

In this case, the inner link plates 52 and 72 are configured to engage with the slats 30 while moving the wound portions of the inner sprockets 42 and 62.
Accordingly, the inner link plates 52 and 72 are engaged with the slats as compared with the case where they move on the circular trajectory 64TB that linearly connects the inner sprocket 62 to the rear end of the straight portion 64Ta as shown in FIG. 30 will be pushed further forward.

  In other words, the inner link plates 52 and 72 rotate more greatly than the case where they move along the circular trajectory 64TB as shown in FIG. That is, it is necessary to increase the vertical dimension of the sub-reference holes 52c and 72c of the inner link plates 52 and 72 in the vertical direction. For this reason, mechanical friction will become larger.

  From the above, it is preferable that the circular trajectories 44T and 64T of the chains 44 and 64 converge toward the upper and lower central portions of the circular trajectories 44T and 64T of the chains 44 and 64 as they go inward in the transport direction.

  By comprising in this way, the fall of the intensity | strength of each inner side link plate 52 * 72 can be prevented, and lifetime can be extended.

  In the drive mechanism 40 and the driven mechanism 60 of the first embodiment, the outer diameter of each of the inner sprockets 42 and 62 (inner end member) is made larger than the outer diameter of each of the outer sprockets 43 and 63 (outer end member). While setting it short, the center of each sprocket 42 * 43 * 62 * 63 is set to the same height position.

  As a result, the circular trajectories 44T and 64T of the converging chains 44 and 64 can be drawn with a simple configuration.

  The outer diameter of each inner sprocket 42, 62 does not necessarily need to be shorter than the outer diameter of each outer sprocket 43, 63. That is, the outer diameter dimensions of the sprockets 42, 43, 62, and 63 are set to the same dimension, and the circular trajectories 44T and 64T of the converging chains 44 and 64 are drawn by the chain guides 45 and 65, respectively. It doesn't matter.

Although the transport apparatus 1 is configured to move the slats 30 with the front direction as the transport direction, the sprockets 42, 43, 62, and 63 may be rotated in the reverse direction to move the slats 30 in the direction opposite to the transport direction. I do not care.
In this case, when the inner link plates 52 and 72 are engaged with the slats 30, the recesses 52 a and 72 a of the inner link plates 52 and 72 and the engagement pins 31 of the slats 30 are caused by the slack of the chains 44 and 64. Buffer contact.
In such a case, the drive mechanism 40 functions as a downstream drive mechanism, and the driven mechanism 60 functions as an upstream drive mechanism.

  That is, it is not always necessary to form the elongated reference holes 52c and 72c in the inner link plates 52 and 72. If the substantially circular sub-reference holes 52c and 72c are formed, the inner link plates 52 and 72 are recessed by the slack of the chains 44 and 64 regardless of the conveying direction. Buffer the contact between 72a and the engaging pin 31 of the slat 30.

  In addition, the structure of the joint link 50 is not limited to 1st embodiment.

  That is, as in the first modification of the joint link 50 shown in FIG. 16, the plate 44b of the chain 44 may be sandwiched from the left and right sides by the inner link plate 52 and the plate 56. In such a plate 56, a recess 52a and reference holes 56b and 56c having substantially the same shape as the recess 52a and the reference holes 52b and 52c of the inner link plate 52 are formed.

  Further, as in the second modification of the joint link 50 shown in FIG. 17, a configuration using a plate 57 that continuously forms the upper portions of the plates 52 and 56 shown in FIG. Absent. In such a plate 57, a recess 57a and reference holes 57b and 57c having substantially the same shape as the recess 52a and the reference holes 52b and 52c of the inner link plate 52 are formed in a side view.

  By applying the joint links of the first and second modified examples to the conveying device 1, the strength of the engaging members (upstream engaging member and downstream engaging member) that engage with the slat 30 is increased. be able to.

That is, the engaging member only needs to have the recesses 52a and 72a formed on the members supported by the connecting pins 53, 54, 73, and 74 of the joint links 50 and 70, respectively.
Thereby, the said engaging member can be easily attached to each chain 44 * 64.

Next, the conveyance apparatus 101 of 2nd embodiment is demonstrated.
The transport device 101 of the second embodiment is different from the transport device 101 of the first embodiment in the configuration of the drive mechanism 140 and the driven mechanism 160. For this reason, in 2nd embodiment, the same code | symbol as the conveying apparatus 1 of 1st embodiment is attached | subjected and demonstrated regarding the member (for example, baseplate 10 etc.) of the same structure as the conveying apparatus 1 of 1st embodiment.

  As shown in FIGS. 18 and 19, the drive mechanism 140 includes a drive shaft 141, an inner sprocket 142, an outer sprocket 143, a chain 144, a chain guide 145, an outer frame 146, a plurality of heart cams 150, a cam guide 151, and the like. .

The sprockets 142 and 143, the chain 144, the chain guide 145, the outer frame 146, the heart cam 150, and the cam guide 151 are arranged symmetrically with respect to each other on the left and right sides of the transport device 1.
Therefore, only the sprockets 142 and 143, the chain 144, the chain guide 145, the outer frame 146, the heart cam 150, and the cam guide 151 arranged on the left side will be described below.

  The drive shaft 141, the outer sprocket 143, and the outer frame 146 are configured similarly to the drive shaft 41, the outer sprocket 43, and the outer frame 46 of the first embodiment (see FIG. 2).

  The inner sprocket 142 is set to have the same outer diameter as that of the outer sprocket 143.

The chain 144 is configured as an annular chain 144 by connecting chopped chains of a predetermined length by joint links.
An extension pin 144c extending from the right side (the side in the direction orthogonal to the transport direction) is attached to the chain 144 for each width in the transport direction of the slats 30.

Unlike the chain 44 of the first embodiment, the chain 144 does not necessarily have to be connected to a chopped chain having a length corresponding to the width of the slat 30 in the conveying direction.
A commercially available joint link is used as the joint link for connecting the chopped chains. That is, the chain 144 does not support the inner link plate 52 as in the first embodiment (see FIG. 3).

As shown in FIG. 20, the circular trajectory 144T of the chain 144 is formed in a track shape in which the wound portions of the sprockets 142 and 143 having the same diameter are linearly connected in the front-rear direction.
That is, the upper and lower surfaces of the chain guide 145 are formed in a straight line along the circular trajectory 144T of the chain 144.

  As shown in FIG. 21, the heart cam 150 has a generally heart shape (a shape in which both front and rear end portions extend upward and a front and rear midway portion extends downward so as to converge to the front and rear central portion) in a side view. It is a member to be formed.

A hole penetrating in the left-right direction is formed in a substantially central portion of the heart cam 150 in the front-rear direction and the up-down direction. By inserting the extension pin 144c into the hole and inserting the E-ring 155 into the extension pin 144c, the heart cam 150 is supported by the extension pin 144c and is relative to the chain 144 around the extension pin 144c. Rotate.
That is, the chain 144 supports the heart cam 150 for each width in the transport direction of the slat 30 (see FIG. 18).

  As described above, the heart cam 150 can be easily attached to the chain 144 by supporting the heart cam 150 with the extension pin 144c.

  The heart cam 150 is formed with a recess 150a, and two rollers 150b and a sliding pin 150c are attached.

  The recess 150 a is formed in a shape that can be engaged with the engagement pin 31 of the slat 30, and is formed in the front and rear center portion of the upper portion of the heart cam 150.

  Each roller 150b is attached to both front and rear ends of the upper portion of the heart cam 150.

  The sliding pin 150 c is attached to the lower part of the heart cam 150 and protrudes to the right side from the heart cam 150.

As shown in FIGS. 19 and 22, the cam guide 151 is for guiding the sliding pin 150 c of the heart cam 150. The cam guide 151 is disposed on the right side of the heart cam 150 and is disposed below the engagement pin 31 of the slat 30.
A guide groove 151 a is formed on the left side surface of the cam guide 151 (side surface facing the heart cam 150).

The guide groove 151a has a shape along the circular locus 144T of the chain 144 (a shape obtained by reducing the circular locus 144T of the chain 144) except for the shape of the front end.
The front end portion of the guide groove 151a extends from the upper side toward the front lower direction more gently than the circular trajectory 144T of the chain 144, and linearly extends rearward and downward at the upper and lower middle portions. And it extends linearly in the front downward direction, and extends in the rear downward direction more gently than the circular trajectory 144T.

  The sliding pin 150c of the heart cam 150 is disposed in the guide groove 151a. Therefore, the sliding pin 150c slides in the guide groove 151a of the cam guide 151 when the heart cam 150 moves.

  That is, the cam guide 151 varies the distance of the sliding pin 150c with respect to the extension pin 144c at the front end (the inner end in the conveying direction of the chain 144).

  The driven mechanism 160 is configured symmetrically with respect to the drive mechanism 140 except that a driven shaft is provided instead of the drive shaft 141.

Below, operation | movement of the conveying apparatus 101 of 2nd embodiment is demonstrated centering on a different point from the conveying apparatus 1 of 1st embodiment.
In addition, the conveyance apparatus 1 shall start a drive from the state shown in FIG.

The conveying device 101 applies a driving force to the driving shaft 141 of the driving mechanism 140 to rotate the inner sprocket 142 and rotate the chain 144.
That is, in the second embodiment, a driving force is applied to the slat 30 </ b> A located at the upstream end of the transport unit 2 via the heart cam 150.

  Since the heart cam 150 is rotatable relative to the chain 144, the heart cam 150 rotates clockwise in FIG. 18 when a driving force is applied to the slat 30A.

  Therefore, in the second embodiment, a guide that comes into contact with each roller 150b when the heart cam 150 is rotated by a predetermined angle is disposed above the heart cam 150.

Accordingly, the rotation of the heart cam 150 is allowed to a predetermined angle, and when the heart cam 150 is rotated to a predetermined angle, each roller 150b is brought into contact with the guide to reduce the friction loss. The same applies to the driven mechanism 160.
Accordingly, the heart cam 150 applies a driving force to the slat 30A located at the upstream end of the transport unit 2 while being rotated by a predetermined angle.

By extruding the slat 30A located at the upstream end of the transport unit 2, the transport device 101 is located at the downstream end of the transport unit 2 as in the case of the transport device 1 of the first embodiment. To drive the chain of the driven mechanism 160 (see FIG. 6).
Thereby, the conveying apparatus 101 pushes out the slat 30D located in the upstream edge part of the reverse feed part 3, and drives the slat 30 (refer FIG. 6).

  Next, an operation when the slat 30B positioned in the transport unit 2 is engaged with the heart cam 170 of the driven mechanism 160 will be described.

  As shown in FIG. 23, the heart cam 170 engages with the slat 30B while moving the wound portion of the inner sprocket.

At this time, the sliding pin 170c of the heart cam 170 of the driven mechanism 160 slides on the rear end portion of the guide groove 171a as the heart cam 170 moves, as shown in FIG.
Since the rear end portion of the guide groove 171a is not formed in a shape along the circular locus 164T, torque is applied to the heart cam 170 according to the shape of the guide groove 171a.

That is, the heart cam 170 starts rotating before engaging the slat 30B. At this time, the heart cam 170 rotates so that the concave portion 170a faces upward.
That is, when the driven mechanism 160 engages the slat 30B with the heart cam 170, the driven cam 160 rotates the heart cam 170 in a direction in which the recess 170a of the heart cam 170 is released from the engagement pin 31 of the slat 30B.

As described above, the driven mechanism 160 is configured such that the sliding pin 170c of the heart cam 170 slides in the guide groove 171a, so that the heart cam 170 is rotated before engaging with the slat 30B. The operation of the heart cam 170 is moderated.
Thereby, since mechanical wear of the heart cam 170 can be reduced, the life of the heart cam 170 can be extended.

In the driven mechanism 160, the slat 30B tries to overtake the heart cam 170 after the slat 30B is engaged with the heart cam 170 until the wound portion of the inner sprocket is moved. At this time, the heart cam 170 rotates.
Thereby, the conveying apparatus 101 buffers the contact between the recess 170a of the heart cam 170 and the engaging pin 31 of the slat 30B.
That is, the conveying device 101 can reduce wear during engagement by using the heart cam 170 as a downstream engaging member that engages with the slat 30 at the downstream end in the conveying direction.

  Even when the slat 30 is moved in the direction opposite to the conveyance direction, the heart cam 170 rotates when engaged with the slat 30 and can buffer the contact between the recess 170a and the engagement pin 31 of the slat 30B.

  The same applies to the drive mechanism 140. The same applies when the slat 30 is detached from the heart cams 150 and 170.

As described above, the heart cam 150 of the drive mechanism 140 functions as an upstream engaging member to which the sliding pin 150c is attached on the side opposite to the side where the concave portion 150a is formed with respect to the extension pin 144c.
Further, the heart cam 170 of the driven mechanism 160 functions as a downstream engaging member to which the sliding pin 170c is attached on the side opposite to the side where the concave portion 170a is formed with respect to the extension pin 164c.

  In addition, the shape of the guide grooves 151a and 171a of the cam guides 151 and 171 is not limited to the second embodiment. In other words, the heart cams 150 and 170 may be rotated so that the recesses 150a and 170a of the heart cams 150 and 170 are released in accordance with the movement of the engagement pin 31 of the slat 30.

  Moreover, you may form the linear part 44Ta and the curve part 44Tb which are in the circumference locus | trajectory 44T of 1st embodiment in each circumference locus | trajectory 144T * 164T (refer FIG. 4). In this case, the drive mechanism 140 and the driven mechanism 160 need not include the cam guides 151 and 171 and the slide pins 150c and 170c.

DESCRIPTION OF SYMBOLS 1 Conveyance apparatus 2 Conveyance part 3 Reverse feed part 30 Slat 31 Engagement pin 40 Drive mechanism (upstream drive mechanism)
52 Inner link plate (upstream engagement member)
52a Recess (engaged part)
60 Follower mechanism (downstream drive mechanism)
72 Inner link plate (downstream engagement member)
72a Concave part (engaged part)
150 Heart cam (upstream engagement member)
150a recess (engaged part)
170 Heart cam (downstream engagement member)
170a Concave part (engaged part)

Claims (17)

A plurality of slats in which the engaging portions are formed are continuously moved in the transport direction along the transport portion, and are reversely arranged at a distance longer than the thickness of the slats with respect to the transport portion. A transport device that continuously moves along a feeding unit in a direction opposite to the transport direction,
An upstream engagement member is provided at an upstream end in the transport direction of the transport unit and formed with an engaged portion that engages with the engagement portion of the slat, and downstream of the reverse feed unit in the transport direction An upstream drive mechanism that engages the slat with the upstream engagement member from a side end to an upstream end in the transport direction of the transport unit;
A downstream engaging member disposed at a downstream end of the transport unit in the transport direction and having an engaged portion that engages with the engaging portion of the slat; and downstream of the transport unit in the transport direction A downstream drive mechanism that engages the slat with the downstream engagement member from an end to an upstream end in the transport direction of the reverse feed unit;
Comprising
The slat is
In a state of being adjacent along the transport direction, disposed in the transport unit and the reverse feed unit,
The upstream drive mechanism is
Without reversing the upper and lower surfaces of the slats, the slats are moved one by one from the reverse feed unit to the transport unit, and the slats located at the upstream end in the transport direction of the transport unit are moved to the upstream side. By applying a driving force via the side engaging member, the slat located downstream in the transport direction of the transport unit is pushed out from the slat to which the driving force is applied,
The downstream drive mechanism is
Without inverting the upper and lower surfaces of the slats, the slats are moved one by one from the transport unit to the reverse feed unit, and the slats located at the upstream end in the transport direction of the reverse feed unit are By applying a driving force via the downstream engaging member, the slat located on the downstream side in the transport direction of the reverse feed unit is pushed out from the slat to which the driving force is applied,
Conveying device. Each drive mechanism is
An inner end member disposed at an inner end in the conveying direction of each drive mechanism;
An outer end member disposed at an outer end in the conveying direction of each drive mechanism;
Annulus that is wound around the end members so as to be rotatable in the transport direction at a side portion orthogonal to the transport direction of the slats, and supports the engagement members for each width in the transport direction of the slats. Chain,
Further comprising
The transport apparatus according to claim 1. Each end member of each drive mechanism is
At least one of them is constituted by a sprocket to which a driving force is applied by a predetermined driving source,
The transport apparatus according to claim 2. The slat is
An engagement pin extending from a side portion in a direction orthogonal to the transport direction is formed as the engagement portion,
Each engagement member of each drive mechanism is
One side portion extends toward the engagement pin, and a concave portion that is recessed to be engageable with the engagement pin at the extension portion is formed as the engaged portion.
The conveyance apparatus of Claim 2 or Claim 3. The engaged portion of each engaging member of each driving mechanism is
Formed on the non-contact side of each end member,
The transport apparatus according to claim 4. Each engagement member of each drive mechanism is
The direction orthogonal to the transport direction is the rotation axis direction, and is supported so as to be rotatable relative to the chain.
The conveyance apparatus as described in any one of Claim 2-5. Each chain of each drive mechanism is
A plurality of chopped chains of a length corresponding to the width in the conveying direction of the slats are configured as an annular chain by connecting with a plurality of joint links,
The joint link is
Of two different chopped chains, a plate located at an upstream end in the conveying direction of one of the chopped chains and a plate located at a downstream end in the conveying direction of the other chopped chain By sandwiching between the link plates and supporting them with the connecting pins, the two differently cut chains are connected,
Each engagement member of each drive mechanism is
It is configured by forming the engaged portion on a member supported by the connecting pin.
The transport apparatus according to any one of claims 2 to 6. In each engagement member of each drive mechanism,
A reference hole through which a connecting pin supporting a plate located at the downstream end in the conveying direction of the chain is inserted;
A connecting pin that supports a plate positioned at the upstream end in the conveying direction of the chain is inserted, and a long hole-shaped sub-reference hole in which the connecting pin is slidable in the vertical direction;
Formed,
Centering on a connecting pin inserted through the reference hole, it rotates relative to the chain.
The transport apparatus according to claim 7. In each chain of each drive mechanism,
For each width in the transport direction of the slats, an extension pin that extends from a side portion in a direction orthogonal to the transport direction and supports the engaging members is attached.
The transport apparatus according to any one of claims 2 to 6. Each engagement member of each drive mechanism is
Pivoting relative to the chain around the extension pin;
The transport apparatus according to claim 9. In each engagement member of each drive mechanism,
With the extension pin as a reference, a slide pin is attached to the side opposite to the side where the recess is formed,
Each drive mechanism is
And further comprising a cam guide that slides the sliding pin and varies the distance of the sliding pin relative to the extension pin at an inner end in the conveying direction of each chain.
When engaging the slats with the engaging members, and when detaching the slats from the engaging members, the respective slats are configured to release the recesses of the engaging members from the engaging pins of the slats. Rotate the engaging member,
The transport apparatus according to claim 9 or 10. The circular trajectory of each chain of each drive mechanism is
As it goes inward in the transport direction, it converges to the upper and lower central part side of the circular trajectory of each chain.
The conveyance apparatus as described in any one of Claim 2-10. Each drive mechanism is
The outer diameter dimension of the inner end member is set smaller than the outer diameter dimension of the outer end member, and the center of each end member is set at the same height position.
The transport apparatus according to claim 12. In the circular trajectory of each chain of each drive mechanism,
A linear portion that is formed in a straight line along the conveying direction at the outer end in the conveying direction, and a distance equal to or greater than the width in the conveying direction of the slats;
A curved part that swells in a curved shape is formed on the inner side in the conveying direction than the linear part, on the outer side in the vertical direction.
The transport apparatus according to claim 12 or claim 13. Each drive mechanism is
A chain guide disposed on the inner side of each chain, the upper and lower surfaces of the shape corresponding to the circular trajectory of each chain are formed;
Further comprising
Each chain of each drive mechanism is
By sliding the upper and lower surfaces of each chain guide, a predetermined circular trajectory is drawn,
The conveyance apparatus as described in any one of Claim 2-14. Either one of the drive mechanisms is
With a predetermined drive source, the chain is circulated to apply a driving force to the slats,
The other of the drive mechanisms is
By the driving force from one of the driving mechanisms, the chain is circulated to apply the driving force to the slats.
The conveying apparatus as described in any one of Claim 2-15. Each drive mechanism is
A plurality of the chains are arranged on a side portion in a direction orthogonal to the conveying direction of the slats,
At least one of the drive mechanisms is
The inner end member is constituted by a sprocket, and a drive shaft that rotatably supports the inner end member is rotated to circulate each chain of each drive mechanism;
The conveying apparatus as described in any one of Claim 2-16.

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