JP4834127B2 - Transport system - Google Patents

Description

  The present invention relates to a transport system, and in particular, in a factory that assembles and stores an electronic device (for example, a liquid crystal unit or the like) that is assembled in a pachinko gaming machine, The present invention relates to a transport system for transporting and storing.

  Conveyance means for transporting electronic devices etc. in assembly factories, etc. include conveyor systems using roller conveyors and slat conveyors, rail-type conveyor systems that move on rails, unmanned conveyor carts, and carts with caster wheels. Various methods have been put to practical use, such as a method of loading and pushing and conveying by human power, and a method of conveying with a conveying tool that moves along a rail on the ceiling side. For example, turntables installed near the upper surface of the floor are widely used as means for changing the direction of the transported body by 90 degrees, for example.

  As a warehouse system for storing a large number of electronic devices or the like in a storage box, an automatic warehouse system is widely adopted. This automatic warehouse apparatus has a transport rail disposed on the floor, a transport bot that travels on and off the transport rail, a plurality of storage shelves provided on both sides of the travel area of the transport robot, and the like.

  Patent Document 1 discloses a parts transportation and storage system. In this parts transportation and storage system, a plurality of (three in six stages, a total of 18) frame items of gaming machines are stored in a container cart with caster wheels, An automatic warehouse that can store 15 container carts in 8 rows is provided. This automatic warehouse is equipped with 4 transfer rails and 4 sets of automatic transfer devices. A warehousing rail for warehousing is provided, and a warehousing table, a turntable, a transportation rail, a vertical transportation facility, etc. are provided at the warehousing station.

  Patent Document 2 describes a gaming machine manufacturing / shipping system in which a pachinko machine and a slot machine are assembled from parts. The board surface for the pachinko machine is processed, a number of nails are punched, packed and transported, assembled on the game board assembly line, the board surface is inspected, and assembled on the pachinko machine assembly line. The slot machine is assembled on the assembly line and transferred to the packing line via the final assembly inspection line. Various parts are transported by trolley or forklift, but the assembly line is a rail transport system.

Patent Document 3 discloses a towing cart type transfer device that pulls a cart with caster wheels with a chain, a wire, or the like equipped on a floor surface.
Patent Document 4 discloses a transport system including a grip clip suitable for transporting a printed material or the like. In this transport system, a grip clip is suspended from a guide via a plurality of sets of rollers, and the grip clip is moved and driven by a wire cable that moves along the guide.

JP 2002-249207 A JP 2003-81411 A JP-A-10-59519 JP 10-67454 A

  In a transport system having a carry-in stage for carrying a transported object such as a workpiece or product and a storage stage for storing it, in a transport system that always handles only a certain type of transported object, an automatic warehouse device dedicated to the storage stage, etc. There is no particular problem even if equipped. However, if you want to use it as a storage stage at a certain time and use it for another purpose (for example, an assembly stage for another product, etc.) at a certain time, you can use a transport rail or the like on the floor of the storage stage. It is not desirable to equip the equipment and it is desirable to keep the floor surface flat.

  In this case, it is cumbersome for the storage boxes containing articles to be stacked on a cart with caster wheels in multiple stages to be transported, and for the operator to push and pull the cart one by one and transport it to the storage location in the factory. The load is heavy and the space for workers to walk is required, so the space efficiency is reduced, smoothly transporting multiple transported objects from the storage location to the unloading unit, and the appropriate number of transferred objects in front of the unloading unit It is difficult to keep them organized and waiting, which reduces shipping efficiency. In addition, since the transported object stored in the back of the storage location remains without being shipped for a long time, it is difficult to ship the transported object in the assembly order (product number order).

  Therefore, it is conceivable to employ the techniques of Patent Documents 1 to 4 as a transport system for transporting and storing the transported object. However, in factories that assemble electronic devices such as liquid crystal units, the transport system is placed compactly and the floor surface of the storage stage is flat, especially when the internal space is not so large and the ceiling is not so high. However, a transport system that has a storage function equivalent to that of an automatic warehouse and that can be provided for other uses when not in use has not yet been put into practical use.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a transport system capable of automating the transfer of an incoming / outgoing goods to / from a storage stage while adopting a transported body in which a storage box storing articles is placed on a cart with caster wheels, and a plurality of rows A transfer system that can simultaneously transfer all or part of a plurality of transferred objects in units of a row, a transfer system that can automate the sorting by changing the direction of transferred objects transferred from a loading stage to a plurality of rows in a storage stage, etc. Is to provide.

The present invention has the following configuration. Note that the reference numerals show an example of the correspondence with the components shown in the drawings for the purpose of promoting understanding of the present invention, and do not limit the technical scope of the present invention.
The transport system according to claim 1 is a storage stage for storing a transported body (W) loaded with a container (W) mounted on a cart (10) with caster wheels (10b) in a storage box (9) storing articles. (7) a roller conveyor (20) that is mounted on the carry-in stage (5) and can transport the transported object (W), and a storage stage (7) that is mounted on the storage stage (7). A storage and transport device (60M) capable of storing the transport bodies (W) in a state where they are aligned in a plurality of rows and transporting them in the row direction via the caster wheels (10b) of the carriage (10), and the loading stage ( Corresponding to multiple columns in the upstream part of the storage and transport device (60M) by transporting and changing the direction of the transported body (W) installed in the upper space of the downstream part of 5) and discharged from the roller conveyor (20) And a loader device (40) that distributes the parts (62a to 62d).

  According to a second aspect of the present invention, in the first aspect of the present invention, the conveying surface is inclined to ground the caster wheel (10b) of the conveyed object (W) at the downstream portion of the roller conveyor (20). An inclined conveyor (21) and a carriage mechanism (22) for transferring the transported body (W) on the inclined conveyor (21) to the downstream side are provided.

  According to a third aspect of the present invention, there is provided a transport system according to the first or second aspect, wherein the loader device (40) includes an engaging member (42) that can be engaged and disengaged from above at the upper end of the transported body (W). A main body (43), an elevating mechanism (44) for raising and lowering the loader main body (43), and a first transfer mechanism for transferring the loader main body (43) in a first direction parallel to the conveying direction of the roller conveyor (20) (46), a second transfer mechanism (47) for transferring the loader body (43) in a second direction parallel to the row direction of the plurality of rows, and the loader body (43) in the first direction and the second direction. The loader device (40) with the loader body (43) in the lowered state, and the engaging member (42) in the transported body (42). W) is configured to be engaged with the upper end of W) and to move the transported body (W) with the caster wheel (10b) of the transported body (W) in contact with the floor surface. Yes.

  According to a fourth aspect of the present invention, there is provided the transport system according to any one of the first to third aspects, wherein the storage and transport device (60M) includes a plurality of sets of storage and transport mechanisms (60) corresponding to the plurality of rows. Each storage and transport mechanism (60) includes a storage space including a flat floor surface capable of storing a plurality of transported bodies (W), and a plurality of transported bodies ( (W) a plurality of traction bodies (63) each capable of being engaged and disengaged, a plurality of lifting mechanisms (64) each capable of raising and lowering the plurality of traction bodies (63), and a plurality of traction bodies (63). It is characterized by having a common transfer mechanism (65) capable of reciprocating in the row direction by one pitch corresponding to the length in the row direction of the carrier (W).

  According to invention of Claim 1, since the to-be-conveyed body which mounted the container box which accommodated the articles | goods on the trolley | bogie with a caster wheel is conveyed by a roller conveyor, it can convey orderly. A storage and transport device is provided on the storage stage, and a plurality of objects to be transported are stored in a state where they are aligned in a plurality of rows and can be transported in the row direction via the caster wheels of the cart. The load on the operator for moving the transported body is reduced, the space efficiency is improved, and it is possible to carry out in order from the first carried in. In addition, it is possible to ensure versatility when the storage stage is used as a flat floor surface and the storage stage is used for purposes other than the storage stage.

  A loader device is provided in the space above the downstream portion of the carry-in stage so that the transported object carried from the carry-in stage can be transported and changed in direction to be distributed to a plurality of column corresponding portions upstream of the storage and transport device. The direction of the conveyed object can be changed without providing a turntable on the floor surface.

According to invention of Claim 2, a to-be-conveyed object can be switched from roller conveyor conveyance to caster wheel conveyance with an inclination conveyor and a carriage mechanism.
According to the invention of claim 3, the loader main body engageable from above with the upper end of the transported body with the caster wheel grounded is moved up and down by the lifting mechanism, and parallel to the transport direction of the roller conveyor by the first transfer mechanism. Can be transported in the first direction, can be transported in the second direction parallel to the column direction by the second transport mechanism, and can be changed in direction between the first direction and the second direction by the rotation mechanism.

  According to the invention of claim 4, the storage / conveyance device has a plurality of storage / conveyance mechanisms corresponding to a plurality of rows, and each storage / conveyance mechanism is provided with a plurality of traction bodies corresponding to a plurality of objects to be conveyed. By lowering and engaging with the upper ends of a plurality of transported bodies, the transfer mechanism reciprocates the plurality of towed bodies in the row direction by one pitch corresponding to the length in the row direction of the transported bodies. A plurality of transported bodies in the row can be transferred by one pitch.

1 is an overall layout diagram of an assembly storage factory according to an embodiment of the present invention. It is a top view of a to-be-conveyed body. It is a side view of a to-be-conveyed body. It is a front view of a to-be-conveyed body. It is a perspective view of a lifter device. It is a perspective view of an external shape check apparatus. It is a top view of a part of roller conveyor, a loader apparatus, and a storage and conveyance apparatus. FIG. 6 is a cross-sectional view taken along line VI-VI in FIG. 5. It is a top view of the downstream part and roller waiting area of a roller conveyor. It is a front view of the downstream part and loading waiting area of a roller conveyor. It is sectional drawing of a roller conveyor. It is sectional drawing of an inclination conveyor. It is a figure of the carriage of an inclined conveyor, an anti-back member, etc. It is a front view of the carriage and anti-back member of an inclined conveyor. It is the XIII-XIII sectional view taken on the line of FIG. It is a top view of a loader device. It is the XV-XV sectional view taken on the line of FIG. It is a principal part perspective view of a loader device. It is a principal part perspective view of a loader device. It is a schematic side view of a storage / conveyance mechanism (traction body descending state). It is a principal part perspective view which shows the traction body, to-be-conveyed body, dust pan, etc. of a storage and conveyance mechanism. It is a principal part side view which shows the traction body, raising / lowering mechanism, etc. of a storage and conveyance mechanism. It is a principal part rear view of a storage and conveyance apparatus. It is principal part sectional drawing of a storage and conveyance apparatus. It is principal part sectional drawing of a storage and conveyance mechanism. It is principal part sectional drawing of a storage and conveyance mechanism. It is a principal part front view of a storage and conveyance mechanism. It is a principal part perspective view of a storage and conveyance mechanism. It is a block diagram of a control system including a control unit.

  Hereinafter, modes for carrying out the present invention will be described based on examples.

The assembly storage factory F shown in FIG. 1 assembles a liquid crystal unit in which a control board is assembled to a liquid crystal display of a pachinko machine, transports it from the loading stage 5 to the storage stage 7, stores it in the storage stage 7, and then unloads it from the storage stage 7 in the order of loading. It is what you do. In the following description, the front-rear and left-right directions in FIG.
In this assembly and storage factory F, as shown in FIGS. 2-1 to 2-3, five liquid crystal units D are stored in five compartments inside a synthetic resin storage box 9, and this storage box 9 is stored in 3 sections. What is stacked and placed on a cart 10 with caster wheels is a transported object W. The storage box 9 is provided with engagement metal fittings 9a at four corners so that the lower end of the upper storage box can be engaged with the upper end of the lower storage box at the time of stacking. Engagement fittings 10a are also provided at the four corners of the cargo bed.

As shown in FIG. 1, the assembly storage factory F includes assembly stages 1 and 2 for assembling the liquid crystal unit, an inspection stage 3 for inspection, a pre-stage 4 before being loaded into the carry-in stage 5, a carry-in stage 5 and the carry-in stage 5. Prepare a sorting stage 6 provided in the downstream part of the stage 5, a storage stage 7 that receives the transported object W from the sorting stage 6, stores it in four rows, and stores it such as a cart 10 and a storage box 9. It has a preliminary stage 8 or the like.
The carry-in stage 5 is provided with a roller conveyor 20, the sorting stage 6 is provided with a loader device 40, and the storage stage 7 is provided with a storage and transfer device 60 M (which has four sets of storage and transfer mechanisms 60). There is provided a control unit 100 with an operation panel for comprehensively controlling the roller conveyor 20, loader device 40, four sets of storage and transport mechanisms 60, and the like.

  As shown in FIGS. 1 and 3, the front stage 4 is provided with a lifter device 11 for measuring the weight of the transported object W and for easily stacking the second and third storage boxes 9. ing. As shown in FIG. 3, the lifter device 11 includes an elevating table 12 that can move up and down by a height substantially equal to the height of the storage box 9, an actuator (for example, an air cylinder) that can drive the elevating table 12 up and down, A weight measuring device (not shown) for measuring the weight of the transported object W placed on the table 12, and a liquid crystal display (not shown) capable of displaying the weight measured by the weight measuring device, an error message, and the like. The operation panel 13 including

  As shown in FIG. 1, the carry-in stage 5 is provided with a roller conveyor 20 that transports the transport target W from a start point SP to a destination point TP. As shown in FIGS. 1 and 4, the front stage 4 is equipped with an outer shape checking device 14 (outer shape checking means) for checking the outer shape of the transported object W in front view between the lifter device 11 and the start point SP. Has been. The outer shape check device 14 has a gate member 15 through which the transported object W can pass in the transport direction, and an optical sensor 16 (including a light emitting unit 16a and a light receiving unit 16b) provided near the upper end of the gate member 15. The optical sensor 16 is electrically connected to the operation panel 13.

  The outer shape of the conveyed object W viewed from the conveying direction is checked by the outer shape checking device 14 described above. In the case of poor stacking, the transported body W interferes with the gate member 15 and cannot pass. Further, the light from the light emitting unit 16a is received by the light receiving unit 16b, thereby checking that the height of the transport target W is within a specified height. When the height of the transport target W is excessive, it causes a trouble in the storage and transport stage 7.

  Next, the roller conveyor 20 provided in the carry-in stage 5 will be described with reference to FIGS. At the upstream end of the roller conveyor 20, a pair of slopes are formed for slightly raising the caster wheel 10 b in order to transfer the transport target W to the conveyor. In the downstream part of the roller conveyor 20, an inclined conveyor 21 whose conveying surface is inclined to ground the caster wheel 10 b of the conveyed object W, and a conveyed object W provided on the inclined conveyor 21 on the inclined conveyor 21 are arranged. A carriage mechanism 22 is provided to push and transfer to the downstream side. A loading standby area 6 </ b> A included in the sorting stage 6 is provided immediately downstream of the inclined conveyor 21. The transport target W is transported to the loading standby area 6A by the carriage mechanism 22 of the inclined conveyor 21.

  Among the roller conveyors 20, the roller conveyor 20 on the upstream side of the inclined conveyor 21 is provided with a plurality of rollers 25 mounted on support frames 24 on both sides at appropriate intervals, and on both sides of these rollers 25. A plurality of pairs of guide frames 26 having a predetermined length are provided. A plurality of rollers 25 at appropriate intervals among the plurality of rollers 25 are drive rollers with built-in electric motors. At the upstream end of the guide frame 26, a tapered portion 26 a that guides the roller conveyor 20 to the center side when the conveyed object W is displaced laterally is formed. Outside the support frames 24 on both sides, at least one pair of alignment mechanisms 27 that align the caster wheels 10b of the carriage 10 of the transported object W in the transport direction are provided.

  The alignment mechanism 27 is a guide plate 27a with which the caster wheel 10b of the carriage 10 of the transported object W comes into contact, and an inclined plate 27b formed at the upstream end of the guide plate 27a. The inclined plate 27b is formed. When the direction of the caster wheel 10b is not the normal posture with respect to the transport direction, when the caster wheel 10b comes into contact with the inclined plate 27b during the transport of the transported object W, the caster wheel 10b rotates around the vertical support shaft to the normal posture. become. This is because when the caster wheel 10 b is grounded at the end of the inclined conveyor 21, it can be conveyed in the same conveyance direction as the conveyance direction of the roller conveyor 20. A plurality of optical sensors 20A including a light emitting unit 20a and a light receiving unit 20b that detect the presence / absence of the transport target W are provided at a plurality of locations on the roller conveyor 20 (see FIG. 27).

  As shown in FIGS. 7 to 12, in the inclined conveyor 21, the carriage mechanism 22 includes a pair of idler roller rows 28 that move the conveyed object W in the conveying direction, and pushes the conveyed object W downstream. A carriage 29, a guide mechanism for guiding the carriage 29, and an electric cylinder 30 as reciprocating drive means capable of reciprocatingly driving the carriage 29. However, a rodless air cylinder may be applied instead of the electric cylinder 30. The carriage 29 is provided with a pair of vertically swinging anti-back members 32 that are engaged with the upstream end of the transport target W in the transport direction and pushed downstream.

  Each idler roller row 28 has a plurality of idler rollers 28a rotatably attached to a pair of frames that are inclined downward toward the downstream side, and is provided on the upper surface of the pair of idler roller rows 28a. Is formed. The guide mechanism is composed of an electric cylinder 30 disposed in an inclined manner in parallel with the idler roller row 28. The carriage 29 is fixed to the output member of the electric cylinder 30, guided by the electric cylinder 30 in the transport direction, and reciprocated by a predetermined stroke.

  On both sides of the downstream portion of the inclined conveyor 21, a pair of guide plates 33 is provided that rolls caster wheels 10 b approaching the floor surface and smoothly guides them to the floor surface, and this pair of guide plates 33. A pair of alignment mechanisms for aligning the caster wheel 10b is also provided at the upstream end of the pair, and a pair of alignment mechanisms each including an inclined plate 33a inclined in the same manner as the inclined plate 27b is provided. When the transported object W transported by the roller conveyor 20 reaches the inclined conveyor 21, the downstream caster wheel 10b rides on the pair of guide plates 33 and is stopped. An optical sensor 21A including a light emitting unit 21a and a light receiving unit 21b for detecting the transport target W on the inclined conveyor 21 is also provided.

  As shown in FIGS. 11 and 12, the pair of vertically swinging anti-back members 32 is pivotally coupled to the side walls on both sides of the gate-shaped member 31 fixed to the carriage 29. The anti-back member 32 is urged clockwise in FIG. 12 by a tension spring 32a, and a lower end portion is received from below by a receiving plate 31a. When the upstream end of the transported body W is pushed, the transported body W can be pushed because the lower end portion of the anti-back member 32 is received by the receiving plate 31a. When the carriage 29 moves backward in the upstream direction, the anti-back member 32 is in a lying posture in which the anti-back member 32 is laid down in parallel with the transport surface, so that it can pass through the lower surface side of the transport target W. The same applies to the case where the transport target W moves on the carriage 29 in the downstream direction. When the transport target W is transported to the maximum downstream side by the carriage mechanism 22, the transport target W is positioned in the loading standby area 6A.

  The loading standby area 6A is a rectangular area of almost the same size as the transported body W in which the transported body W just fits. A locking mechanism 35 is provided at the downstream end of the loading standby area 6A to receive both ends of the downstream end in the transport direction of the transported object W transferred by the inclined conveyor 21 from the downstream side. The locking mechanism 35 is driven by a pair of locking members 35a, a locking position where the locking members 35a are received by the conveyed object W, and a retracted position where the locking members 35a are retracted sideways. Air cylinder 35b (driving means). An electromagnetic direction switching valve is provided in the air supply system to these air cylinders 35b. By receiving the transport target W with the locking mechanism 35, the transport target W is positioned in the loading standby area 6 </ b> A and can be transported by the loader device 40.

  As shown in FIG. 14, in the space above the loading standby area 6A, when the transported body W moves to the loading standby area 6A, the vicinity of the upper end of the transported body W is guided and aligned with the loading standby area 6A. For this purpose, a pair of front and rear guide members 41 with a tapered portion 41a are provided. The sorting stage 6 provided in the downstream portion of the carry-in stage 5 is an area that includes the loading standby area 6A and in which the loader device 40 operates. An optical sensor 23A including a light emitting unit 23a and a light receiving unit 23b for detecting the transport target W in the loading standby area 6A is also provided, and the optical sensor 23A is electrically connected to the control unit 100.

  Next, the loader device 40 of the sorting stage 6 will be described with reference to FIGS. 1, 5, 6 and 13 to 17. The loader device 40 transfers the transported object W in the loading standby area 6A to the left and changes the direction by 90 degrees to correspond to the four storage / conveyance rows 61a to 61d of the four storage / conveyance rows 60a. It is a device that distributes to 62a to 62d.

  The loader device 40 includes a loader body 43 having a substantially rectangular shape including four engaging members 42 that can be engaged with and disengaged from the upper end of the transported body W, a lifting mechanism 44 that lifts and lowers the loader body 43, and a loader body 43. A rotation mechanism 45 capable of rotating at least 90 degrees around the vertical axis, a first transfer mechanism 46 for transferring the loader body 43 in a first direction orthogonal to the row direction of the storage and transport rows 61a to 61d, and the loader body 43 is configured by a second transfer mechanism 47 that transfers 43 in a second direction parallel to the row direction. The lift mechanism 44, the rotation mechanism 45, and the first and second transfer mechanisms 46 and 47 of the loader device 40 are electrically connected to the control unit 100 and controlled by the control unit 100.

  The building frame in the space above the sorting stage 6 is provided with a pair of front and rear guide rails 46a extending in the left-right direction (first direction) in FIGS. One movable guide rail 47a extending in the direction (second direction) is attached, and driven members at both front and rear ends of the movable guide rail 47a are movably guided by the guide rail 46a. The movable guide rail 47a is configured to be capable of reciprocating along the entire length of the guide rail 46a by being driven to move in the first direction by an electric actuator including, for example, an electric cylinder incorporated in 46a. The above configuration corresponds to the first transfer mechanism 46.

  A movable carriage 47b is provided on the movable guide rail 47a so as to be movable in the front-rear direction. The movable carriage 47b is extended over the entire length of the movable guide rail 47a by an electric actuator including, for example, an electric cylinder incorporated in the movable guide rail 47a. It is configured to be able to reciprocate. The above configuration corresponds to the second transfer mechanism 47. Four engaging members 42 project downward from both ends of the pair of frame members of the loader body 43. Each engaging member 42 is composed of a pin member having an inverted cone portion formed at the lower end portion.

  When the caster wheel 10b is waiting in the loading standby area 6A and transports the transported object W that is in contact with the floor to the left, the loader body 43 of the loader device 40 is moved above the loading standby area 6A. The four engaging members 42 are opposed to the four corners of the upper end portion of the transported body W, and the loader body 43 is lowered by the lifting mechanism 44 so that the four engaging members 42 are moved to the four corners of the upper end portion of the transported body W. The loader body 43 is transferred to the left while maintaining the engaged state, and the conveyed object W is moved to the left via rolling on the floor surface of the caster wheel 10b of the conveyed object W. Transport.

  The elevating mechanism 44 has a standing air cylinder fixed to the movable carriage 47b, and two guide rods 44b on both sides of the piston rod 44a of the air cylinder. A loader body 43 is supported by a rotation mechanism 45 interposed between the lower ends of the piston rod 44a and the two guide rods 44b. The rotation mechanism 45 includes a lifting plate connected to the lower ends of the piston rod 44a and the two guide rods 44b, a shaft member fixed to the lower surface of the lifting plate so as to protrude downward, and a bearing on the shaft member. And a rotating air cylinder 45b in a horizontal posture in which the rotating body 45a can be rotated by 90 degrees in a plan view with respect to the lifting plate. A loader main body 43 is fixed to the lower end of the rotating body 45a.

  The loader device 40 moves the object to be transported W in the loading standby area 6A to the left and then changes the direction by 90 degrees, and then forwards to 4 corresponding to the four storage and transport rows 61a to 61d. This is sequentially distributed to the two column corresponding portions 62a to 62d. The four storage / conveyance columns 61a to 61d are numbered in the order from the right, first column, second column, third column, and fourth column. Four sets of restricting members 48 are provided in the upper space between the four column corresponding portions 62a to 62d, and each set of restricting members 48 is provided with one vertical member, two oblique members, and their lower ends. A fixed horizontal member is formed, and a tapered guide surface 48a is formed in a rear portion of the horizontal member. By means of these regulating members 48, the center of the transport target W is aligned with the center of the column corresponding portions 62a to 62d when the transport target W is transferred to the column corresponding portions 62a to 62d by the loader device 40, and the transport of adjacent rows is performed. A predetermined gap is formed between the bodies W.

  When the loader device 40 sequentially distributes the transport target W to the four column corresponding units 62a to 62d, the first column, the second column, and the third column are shown by a two-dot chain line circular locus in FIG. As shown in the drawing, if the sheet is transferred from the loading standby area 6A to a position corresponding to the center of each column and then changed in direction by 90 degrees and transferred forward, the column can be transferred to the column corresponding units 62a to 62d. However, the fourth row on the most downstream side is performed as follows because the transport target W interferes with the building when the direction is changed by 90 degrees.

  The control unit 100 changes the direction of the transported object W by 90 degrees by the rotation mechanism 45 at a position (for example, the position of the third row) on the carry-in side (right side) a predetermined distance from the row corresponding portion 62d of the fourth row. After that, the first transfer mechanism 46 moves the transport target W to a position corresponding to the fourth column corresponding portion 62d, and then forwards the transferred object W to the fourth column corresponding portion 62d.

  Next, the storage and transfer device 60M provided in the storage stage 7 will be described with reference to FIGS. 1, 5, and 18 to 26. FIG. This storage / conveyance device 60M has four sets of storage / conveyance mechanisms 60 that can store and transport a large number of transported bodies W in four rows and transport them to the carry-out side. The storage / conveyance device 60M is configured to carry out (first-in first-out) in order from the first carried-in and stored under the control of the control unit 100. The priority of control for the four columns by the control unit 100 is set in the order of the first column, the second column, the third column, and the fourth column, and also when carrying into the four column correspondence units 62a to 62d. Also, when carrying out from the four storage / conveyance rows 61a to 61d, the first row, the second row, the third row, and the fourth row are executed in this order.

In a state where the transport target W is fully stored in the storage and transport device 60M, the transport target W is stored in an orderly manner in a matrix of 12 rows × 4 columns. The row numbers are, for example, the first row, the second row,. The loader device 40 also stores the transport target W in the four column corresponding portions 62a to 62d in the uppermost stream portion (first row) of the four columns. When the transported bodies W are also stored on the most downstream side (the 12th row), a maximum of 48 transported bodies W can be stored. The most downstream side (the 12th row) transported object W is manually pushed by an operator and transported to a truck waiting at a factory exit. At this time, the to-be-conveyed body W is carried out in the priority order of the 1st row, the 2nd row, the 3rd row, and the 4th row.
When the transported body W in the 12th row is unloaded, only the towed body 63 corresponding to the transported body W is lowered and engaged with the rear end portion of the transported body W, and only the transported body W is moved. Can be pushed forward by one pitch.

  Each set of storage and transport mechanisms 60 includes a storage space including a flat floor surface in which a plurality of (for example, 12) transported bodies W can be stored with the caster wheel 10b in a grounded state, and a space above the storage space. A plurality of (for example, 11) traction bodies 63 that are disposed and can be respectively engaged with and disengaged from the upper end portions of the plurality of transported bodies W, and a plurality (for example, 11) of evacuation mechanisms 64 that can move the plurality of traction bodies 63 up and down. And a common transfer mechanism 65 capable of reciprocating the plurality of pulling bodies 63 toward the downstream side in the row direction by one pitch substantially corresponding to the length in the row direction of the transport target W.

  The transfer mechanism 65 is a pair of parallel guide rails 66 extending over the entire length of the row and fixed to a building frame 67 of the factory, and a plurality of guide wheels on the guide rails 66. A movable frame 69 movably disposed in the row direction via 68, and an air cylinder 65a capable of reciprocating the movable frame 69 in the row direction with one pitch together with a plurality of pulling bodies 63, a plurality of dust pans 70, and the like. Have The guide rail 66 is formed by arranging H-shaped steels extending over the entire length of the storage / conveyance rows 61a to 61d in the shape of a "work". The movable frame 69 is, for example, a frame in which a pair of square pipe members having a length close to the entire length of the storage / conveyance rows 61a to 61d (the length of 10 transported bodies) are connected by a plurality of transverse connecting members. It is a member.

  On the left and right sides of the movable frame 69, a plurality of guide wheels 68 that roll on the flange of the guide rail 66, a plurality of guide wheels that contact the lower surface of the flange of the guide rail 66, and the flange of the guide rail 66 A plurality of guide wheels that are in contact with the side surfaces are provided at appropriate intervals, and the movable frame 69 is guided along the guide rail 66 so as to be horizontally movable in the front-rear direction.

Next, the traction body 63, the lifting mechanism 64, and the dust pan 70 will be described.
A plurality (11) of dust pans arranged to correspond to a plurality (for example, 11) of the objects to be conveyed W when the plurality of objects to be conveyed W are stored in series and cover the lower surface side of the movable frame 69. 70 is provided in association with a plurality of traction bodies 63. The dust pans 70 are disposed below the movable frame 69 by a predetermined distance, and are fixed to the movable frame 69 via a support member 70a. Between the dust pans 70 adjacent to each other in the row direction, a lifting gap 71 is formed in which the puller 63 can be lifted and lowered. A pair of elongated slits 70a are formed in the front and rear portions of the dust pan 70 in the row direction.

  A plurality of traction bodies 63 corresponding to the plurality of transported bodies W (that is, corresponding to the plurality of dust pans 70) are disposed at positions corresponding to the lifting gaps 71 between the dust pans 70, and each traction body 63 is independent. An elevating mechanism 64 that can be moved up and down is provided. The most upstream traction body 63 is disposed in the vicinity of the upstream side of the most upstream dust pan 70. The elevating mechanism 64 includes an air cylinder 72 attached to the movable frame 69 in a vertical inverted posture, two guide rods 73, and two support arms 74. A traction body 63 is fixed to the lower ends of the piston rod 72 a and the two guide rods 73 of the air cylinder 72. The two guide rods 73 are provided on both sides of the piston rod 72a (both sides perpendicular to the row), and the guide rods 73 are guided through the guide holes of the cylinder body of the air cylinder 72 so as to be movable up and down.

  The puller 63 is configured by an engagement member that can be engaged and disengaged from above at the front end (the downstream end in the transport direction) of the upper end of the uppermost storage box 9 of the transported body W. The pair of support arms 74 is for increasing the support rigidity for supporting the pulling body 63 during towing. The lower ends of these support arms 74 are pin-coupled to brackets 63a at both ends of the puller 63, and slits 74a having a length of about 1/3 of the total length are formed on the upper portions of the support arms 74. A pin member passing through 74 a and crossing is fixed to a support member fixed to the movable frame 69.

  In a state where the pulling body 63 is raised by the elevating mechanism 64, the pulling body 63 and the pair of support arms 74 are also raised above the dust pan 70, and the pair of support arms 74 are folded in a substantially horizontal posture. Therefore, the upper surfaces of the storage / conveyance rows 61 a to 61 d are almost covered with the plurality of dust pans 70. Therefore, when the dust adhering to the building or the ceiling falls, most of the dust is trapped by the dust pan 70 and does not fall downward.

  In a state in which the pulling body 63 is pulled down by the lifting mechanism 64 and pulled, the pair of support arms 74 are inclined at about 45 degrees downwardly through the pair of notch slits 70a in the front portion of the dust pan 70. In order to increase the traction rigidity for supporting the traction body 63 through the frictional force acting between the pin member passing through the notch slit 70a and the support arm 74, the traction body 63 does not rattle in the front-rear direction during traction and is stable. Tow. When the plurality of transported bodies W are transported to the carry-out side by the transfer mechanism 65, the plurality of towed bodies 63 are lowered and engaged with the upper ends of the plurality of transported bodies W, and caster wheels of the plurality of transported bodies W 10b is transported in the downstream direction by one pitch by the transfer mechanism 65 while rolling on the floor surface.

  In order to supply pressurized air to the plurality of air cylinders 72, an air supply pipe is attached to the building frame, and the movable frame 69 is equipped with an air passage manifold 80 and a plurality of air pipes. A plurality of air pipes branched from the air passage manifold 80 are connected to an air cylinder 72 for raising and lowering, respectively, and an electromagnetic direction switching valve is connected to each of the plurality of air pipes. The air cylinder 72 can be individually driven. These electromagnetic direction switching valves are electrically connected to the control unit 100 and controlled by the control unit 100.

  A stock sensor 81 (detection means) for detecting the presence / absence of the conveyed object W below each dust pan 70 is provided in the vicinity of the upper part of the circular hole in the center of the dust pan 70, and corresponds to the four columns in the first row. Similar stock sensors 81 are provided above the parts 62 a to 62 d, and detection signals from the stock sensors 81 are supplied to the control unit 100. The in-stock sensor 81 is composed of, for example, an ultrasonic sensor.

  As shown in FIGS. 25 and 26, an anti-back mechanism 82 is provided at the unloading side portion of each storage and transfer mechanism 60 so as to restrict the transfer target W from moving backward to the loading side. The anti-back mechanism 82 includes a pair of parallel link mechanisms 83 including a pair of horizontal link members 83a disposed in parallel to both sides of the transport target W and horizontally in the row direction, and a pair of horizontal links. The member 83a has at least one pair of swivelable engaging hooks 84 that can be moved in and out. The rotating engagement hook 84 can push the rear end of the transported body W forward, and retracts into the horizontal link member 83a when transporting the transported body W downstream. It is comprised so that the conveyance of the to-be-conveyed body W may not be prevented.

  The horizontal link member 83a is connected to a pair of front and rear standing link members 85, and the upper end portion of the standing link member 85 is pin-coupled to the auxiliary frame 66a fixed to the lower end of the movable frame 69 by a horizontal pin member in the column orthogonal direction. The lower end portion of the standing link member 85 is pin-coupled to a bracket fixed to the horizontal link member 83a by the same pin member as described above. When the storage and transport mechanism 60 is not used, in order to fold and store the parallel link mechanism 83 upward, a pair of strings 86 connected to the center in the front-rear direction of the horizontal link member 83a is a pair on the auxiliary frame 66a side. The string 86 is detachably connected to a hook 86b provided at a middle portion of the front standing link member 85 by a metal fitting 86a. When the anti-back mechanism 82 is folded, if the metal fitting 86a of the string 86 is removed from the hook 86b and the string 86 is pulled and connected to a predetermined fixing portion, the parallel link 83 is positioned higher than the upper end of the transported object W. It is folded to a position higher than the dust pan 70.

  As shown in FIG. 5, a synthetic resin or metal chain member 87 that is set to prohibit carrying-out of the transported object W at the carrying-out side end of a plurality of sets of storage and carrying mechanisms 60, and the left end is The chain member 87 fixed to the building side column member, the plug member 88 provided at the free end side end portion of the chain member 87, and the chain member 87 are set transversely on the front end side of the four rows as shown in the figure. A socket switch 89 for inserting the plug member 88 is provided. The control unit 100 controls the four storage and transport mechanisms 60 to transfer the transport target W on condition that the plug member 88 is not inserted into the socket switch 89.

  Next, a control system for controlling various devices provided in the assembly storage factory F will be briefly described with reference to FIG. The control unit 100 is supplied with signals from a plurality of optical sensors 20A, 21A, 23A, a plurality of stock sensors 81,..., A socket switch 89, a liquid crystal display 90, an operation panel 91, and the like. . By the control unit 100, a plurality of roller drive motors 25a, an electric cylinder 30 for the inclined conveyor 21, electromagnetic direction switching valves 35a, 35a for the locking mechanism 35, electric cylinders 40a, 40a, 40b of the loader device 40, and The electromagnetic direction switching valves 40c, 40d and the electromagnetic direction switching valves 60a, 60b,... The ROM of the control unit 100 stores in advance a control program for comprehensively controlling the roller conveyor 20, the loader device 40, the four sets of storage and transport mechanisms 60, and the like.

  A plurality of optical sensors including the optical sensor 20A detect the conveyed object W on the roller conveyor 20, the optical sensor 21A detects the conveyed object W on the inclined conveyor 21, and the optical sensor 23A detects the object to be loaded in the loading standby area 6A. The carrier W is detected. Presence / absence of the transported bodies W in those rows is detected by twelve in-stock sensors 81 provided in the first to twelfth rows of each column.

  When the roller conveyor 20 is controlled, the transported object W on the roller conveyor 20 is detected by the optical sensor 20A, and if there is a space on the downstream side of the transported object W and can be transported, the corresponding roller drive The to-be-conveyed body W is conveyed by driving the motor 25a. When there is no transport target W on the inclined conveyor 21, the upstream roller conveyor 20 is driven and the transport target W is transported to the tilted conveyor 21. By driving the carriage 29 of the inclined conveyor 21 on condition that there is no transferred object W in the loading standby area 6A of the loader device 40, the transferred object W on the inclined conveyor 21 is transferred to the loading standby area 6A. .

  The loader device 40 applies the transported object W in the loading standby area 6A when the transported object W disappears in any of the column corresponding parts 62a to 62d in the most upstream part (first row) of the 4 columns. It conveys to the column corresponding | compatible part 62a-62d to perform. In any column, for example, when the twelfth row becomes empty, all the transported objects W in the first row to the eleventh row of the column are simultaneously sent by the storage and transport mechanism 60 of the column. 1 pitch forward. At this time, the traction body 63 in the first row to the eleventh row is lowered and conveyed to the downstream side by one pitch while being engaged with the respective conveyance bodies W.

  If for some reason, for example, the seventh row in the middle of the row becomes an empty space, the transported bodies W from the first row to the sixth row are transported forward one pitch at a time to empty space. The transported object W is replenished. At this time, without lowering the traction bodies 63 of the seventh to twelfth lines, only the traction bodies 63 of the first to sixth lines are lowered and engaged with the respective transported bodies W. In this state, the storage and transport mechanism 60 of the row is transported to the downstream side by one pitch. Therefore, the transported bodies W in the seventh to twelfth lines maintain the storage position without being transported, and thus the empty state in the seventh line is eliminated.

Next, the operation and effect of the assembly storage factory F described above will be described.
Since the transported body in which the storage box 9 storing articles is placed on the cart 10 with caster wheels is transported by the roller conveyor 20, it can be transported in an orderly manner.
By the inclined conveyor 21 and the carriage mechanism 22 installed in the downstream portion of the roller conveyor 20, the conveyance target W can be switched from the roller conveyor conveyance to the caster wheel conveyance.

  A lifter mechanism 11 is mounted on the preceding stage 4 at the start point SP, and is a lifting table 12 (which corresponds to a mounting table) on which the transported object W is placed. Since the lifting table 12 that can be moved up and down over the lowered position lowered by a predetermined distance is provided, the storage box 9 can be easily and efficiently loaded on the cart 10 by the operator.

  A roller conveyor 20 that conveys the object to be conveyed W from the start point SP to the destination point TP is provided, and an inclined conveyor 21 is provided in the downstream portion of the roller conveyor 20 to switch the conveyance of the object to be conveyed W from conveyor conveyance to caster wheel conveyance. Since the inclined conveyor 21 is provided with the carriage mechanism 22 that pushes and conveys the transport target W to the downstream side, the transport of the transport target W can be automated and labor saving can be achieved.

  Moreover, it is possible to set the gradient of the inclined conveyor 21 to a small value to make the conveyance surface gentle, and to suppress the impact of the caster wheel 10b on the floor surface. And even if the gradient of the inclined conveyor 21 is set to be small, the carriage W can be surely pushed and transferred to the downstream side by the carriage mechanism 22, and the carriage W can be reliably transferred to the floor surface of the destination point TP. Can be sent out.

  The carriage mechanism 22 allows the vertically swinging anti-back member 32 to be engaged with the upstream end of the transported body W in the transport direction and push the transported body W to the downstream side. It can be sent to the floor of the point. Further, since the anti-back member 32 is of a vertically swinging type, when the carriage 29 is moved backward, the anti-back member 32 swings downward so that it does not interfere with the transported body W on the inclined conveyor 21 and is not subject to interference. The transport body W can be engaged with the upstream end in the transport direction.

  Since the roller conveyor 20 is provided with at least one pair of alignment mechanisms 27, the caster wheels 10B can be aligned in the transport direction on both sides during the transport by the roller conveyor 20, and the transported object after the caster wheels are grounded at the destination point TP. The conveyance direction of W can be made constant. Moreover, since the alignment mechanism 27 is provided on both sides of the roller conveyor 20, the alignment mechanism 27 can be aligned using the conveying force of the roller conveyor 20.

Since the weight measuring device is provided in the lifter device 11, it is possible to check whether or not there is an erroneous stacking on the transported body by measuring the weight of the transported body.
During the conveyance process between the lifter device 11 and the start point, the outer shape check device 14 can check the outer shape of the conveyed object in front view.
Further, since the locking mechanism 35 is provided in the loading standby area 6A, the transported object W can be reliably stopped at a predetermined position at the destination point. Further, since the locking member 35a of the locking mechanism 35 can be driven between the locking position and the retracted position, the locking member 35a is switched to the retracted position, and the transported object W is sent out by the caster wheel transport. it can.

  In a space above the downstream portion of the carry-in stage 5, a transported object W on which a container box 9 containing articles is placed on a cart 10 with a caster wheel is transferred from a predetermined position on the carry-in side and changed in direction to perform a plurality of storage functions. Since the loader device 40 that distributes to the transport rows 61a to 61d is provided, the transport target W that is transported from the transport stage 5 is transported and changed in direction to the plurality of column corresponding portions 62a to 62d upstream of the storage and transport device 60M. Can be sorted out neatly.

  The loader main body 43 is lowered and engaged with the upper end portion of the conveyed object W, the loader main body 43 is transferred by the first transfer mechanism 46, the direction of the loader main body 43 is changed by the rotation mechanism 45, and then the loader main body 43 is moved. By being transferred by the second transfer mechanism 47, the object to be transferred can be distributed from the carry-in side to the plurality of storage and transfer rows 61a to 61d, and the transfer can be automated. The direction of the transport target W can be changed without providing a turntable on the floor surface.

  A loader body 43 that can be engaged with the upper end of the transported object W with the caster wheel 10b grounded is lifted by a lifting mechanism 44, and a first transfer mechanism 46 is parallel to the transport direction of the roller conveyor 20 in a first direction. Can be transported in a direction, can be transported in a second direction parallel to the row direction by the second transport mechanism 47, and can be changed in direction between the first direction and the second direction by the rotation mechanism 45.

  In addition, since the engagement member 42 is engaged with the upper end portion of the transported body W and the transported body W is moved, the transport and transport lines 61a to 61d are transported to the vicinity of the floor surface from the carry-in side. Since it is not necessary to equip equipment for direction change and the floor surface can be maintained on a flat floor surface, versatility for using the factory for other purposes can be ensured.

  Since the control unit 100 controls the elevating mechanism 44, the rotation mechanism 45, and the first and second transfer mechanisms 46 and 47 of the loader device 40, it is possible to automate the conveyance and direction change of the transport target W by the loader device 40. The loader main body 43 is lowered to engage the engaging member 42 with the upper end of the transported body W, and the caster wheel 10b of the transported body W is transported via rolling on the floor surface of the caster wheel 10b. The engaging member 42 can be used for both the transfer of the transport target W and the direction change.

  Even if there is an obstacle such as a wall on the building side of the factory near the storage / conveyance row 61d on the most downstream side farthest from the carry-in side, a rotation mechanism is provided in advance at a position a predetermined distance before the storage / conveyance row 61d. 45, the direction of the transported object W is changed by 90 degrees, and then transported to a position corresponding to the storage and transport row 61d on the most downstream side by the first transfer mechanism 46, whereby interference between the transported object W and the obstacle Can be prevented, and can be reliably distributed to the storage and transport row 61d.

  Since the storage / conveyance device 60M is provided in the storage / conveyance stage 7, the plurality of transported bodies W are stored in a state of being aligned in a plurality of rows and can be conveyed in the row direction via the caster wheels 10b of the carriage 10, A function equivalent to that of an automatic warehouse can be exhibited, the load on the operator for moving the transported object W is reduced, the space efficiency is improved, and it is possible to carry out in order from the first carried in. Moreover, it is possible to ensure versatility when the storage / transfer stage 7 is kept flat and the storage stage 7 is used for purposes other than the storage stage 7.

  The storage / conveyance device 60M has a plurality of storage / conveyance mechanisms 60 corresponding to a plurality of rows, and the storage / conveyance mechanisms 60 lower the plurality of pulling bodies 63 corresponding to the plurality of transported bodies W, By engaging the upper ends of the plurality of transported bodies W and reciprocating in the row direction by one pitch corresponding to the length in the row direction of the transported bodies W by the transfer mechanism 65, A plurality of transported bodies W in the row can be transferred by one pitch.

  A flat floor surface in which the caster wheels 10b of the transported body W are grounded in a state where the transported bodies W in which the storage boxes 9 storing articles are placed on the carriage 10 with the caster wheels 10b are arranged in a plurality of rows. Since it is stored in the storage space, it is not necessary to arrange transfer equipment such as a transfer rail on the floor side, and versatility when the storage space is used for another purpose can be ensured.

  Since there are a plurality of sets of storage and transport mechanisms 60 corresponding to a plurality of rows, and a plurality of pulling bodies 63, a plurality of lifting mechanisms 64 and a transfer mechanism 65 are provided above the storage space in each storage and transport mechanism 60, Since the plurality of pulling bodies 63 are lowered and engaged with the upper ends of the plurality of transported bodies W, the transport mechanism 65 can transport the pitch by one pitch downstream in the row direction. The transfer of loading / unloading of W can be automated. In addition, since each puller 63 can be lifted and lowered individually by the lifting mechanism 64, all or some of the plurality of transported bodies W in each row can be transferred simultaneously, so that the transport efficiency of the transported bodies W is increased. be able to.

  When the plurality of transported bodies W are transported to the carry-out side by the transfer mechanism 65, the caster wheels 10b of the transported bodies W are effectively used to roll the caster wheels 10b of the multiple transported bodies W on the floor surface. Therefore, it is not necessary to arrange transfer equipment such as a transfer rail, and the load on the operator for moving the transfer target W can be reduced.

  The transfer mechanism 65 is a pair of guide rails 66, a movable frame 69 attached to the guide rails 66 so as to be movable in the row direction, and a fluid pressure cylinder 65a capable of reciprocating the movable frame 69 in the row direction for one pitch. Therefore, it is possible to simultaneously transfer all or a part of the plurality of transported bodies W in each row with a simple configuration. Since the elevating mechanism 64 is composed of the elevating air cylinder 72, the pulling body 63 can be engaged with and disengaged from the upper end portion of the conveyed object W from above.

When the traction body 63 is in the lowered state, the pair of support arms 74 can increase the rigidity of the traction body 63 in the row direction, and the stability of transporting the transported body W can be enhanced.
When the dust adhering to the ceiling side of the factory building falls downward, it is trapped by the plurality of dust pans 70, so that it is difficult for the dust to adhere to the conveyed object W.
Since the lifting gap 71 in which the pulling body 63 moves up and down is formed between the dust pans 70, the structure of the dust pan 70 can be simplified. Since the notch slit 70a for introducing the support arm 74 into the dust pan 70 is formed, interference between the dust pan 70 and the support arm 74 can be prevented.

Since the regulating member 48 that aligns the transported bodies W with the rows to be transported is provided, the plurality of transported bodies W can be stored in a state of being aligned in the multiple rows. Since the anti-back mechanism 82 is provided at the unloading side portion of each storage and transfer mechanism 60 so as to prevent the transferred object W from moving backward to the loading side, the transferred object W at the unloading side portion of each row moves upstream. Reverse movement can be prevented.
Since the anti-back mechanism 82 includes a pair of parallel link mechanisms 83 and a rotating engagement hook 84 provided on the horizontal link member 83a of the parallel link mechanism 83, the anti-back mechanism 82 has a simple configuration and is provided from both sides of the transport target W. Engagement is possible, and the reverse movement of the transported object W can be reliably prevented. When the storage and transport mechanism 60 is not used, the anti-back mechanism 82 can be folded at a position higher than the upper end of the transport target W so as not to get in the way.

A modification example in which the embodiment is partially modified will be described.
(1) The positional relationship between the roller conveyor 20 and the loader device 40 is not limited to that of the embodiment, and various positional relationships can be taken.
(2) The number of columns for storing the transport target W in the storage / conveyance device 60M is not limited to the four columns, and the number of rows is not limited to twelve.

(3) The detailed configuration of the loader device 40 and the detailed configuration of the storage and transport device 60M are merely examples, and are not limited to those of the embodiments.
(4) In addition, those skilled in the art can implement the present invention in a form in which various modifications are added without departing from the gist of the present invention, and the present invention also includes them.

  INDUSTRIAL APPLICABILITY The present invention can be used in a factory that transports and stores various articles while handling them.

1, 2 Assembly stage 3 Inspection stage 4 Previous stage 5 Loading stage 6 Sorting stage 6A Loading standby area 7 Storage stage 8 Preliminary stage 9 Storage box 10 Cart 10b Caster wheel W Transported body 11 Lifter device 14 Outline check device 15 Gate member 16 Optical Sensor 20 Roller Conveyor 20A Optical Sensor 21 Inclined Conveyor 21A Optical Sensor 22 Carriage Mechanism 23A Optical Sensor 27 Alignment Mechanism 28 Rolling Roller Row 29 Carriage 30 Electric Cylinder 32 Vertical Swing Anti-Back Member 33 Guide Plate 35 Locking Mechanism 35a Stop member 35b Air cylinder 40 Loader device 41 Guide member 42 Engaging member 43 Loader body 44 Lifting mechanism 45 Rotating mechanism 46 First transfer mechanism 47 Second transfer mechanism 48 Restricting member 60M Storage and transport device 60 Storage and transport Mechanisms 61a to 61d First to fourth storage / conveyance rows 62a to 62d First to fourth row corresponding portions 63 Traction body 64 Lifting mechanism 65 Transfer mechanism 66 Guide rail 69 Movable frame 70 Dust pan 70a Notch slit 71 Lifting gap 74 Support arm 81 Stock sensor 82 Anti-back mechanism 83 Parallel link mechanism 83a Horizontal link member 84 Rotating engagement hook 86 String 87 Chain member 88 Plug member 89 Socket switch 100 Control unit

Claims (4)

In a transport system comprising a carry-in stage for carrying a transported body on which a container box containing articles is placed on a cart with caster wheels, and a storage stage for storage,
A roller conveyor equipped in the carry-in stage and capable of conveying the object to be conveyed;
A storage and transfer device that is mounted on the storage stage and stores a plurality of transfer target bodies arranged in a plurality of rows and can be transferred in a row direction via the caster wheels of the carriage,
A loader device that is mounted in the upper space of the downstream portion of the carry-in stage and that transports the transported body discharged from the roller conveyor and redirects it to a plurality of row corresponding portions upstream of the storage and transport device;
A conveyance system characterized by comprising:   In the downstream part of the roller conveyor, an inclined conveyor having a conveying surface inclined to ground the caster wheel of the conveyed object and a carriage mechanism for transferring the conveyed object on the inclined conveyor to the downstream side are provided. The transport system according to claim 1. The loader device includes a loader body including an engaging member that can be engaged and disengaged from above at an upper end portion of the transported body, an elevating mechanism that lifts and lowers the loader body, and a loader body that is parallel to the transport direction of the roller conveyor. A first transport mechanism for transporting in one direction, a second transport mechanism for transporting the loader body in a second direction parallel to the row direction of the plurality of rows, and the loader body in the first direction and the second direction. A rotation mechanism that rotates 90 degrees,
The loader device lowers the loader body, engages the engaging member with the upper end of the transported body, and moves the transported body with the caster wheel of the transported body grounded to the floor surface. The transport system according to claim 1, wherein the transport system is configured as described above. The storage and transport device has a plurality of sets of storage and transport mechanisms corresponding to the plurality of rows,
Each of the storage / conveyance mechanisms can be attached to and detached from a storage space including a flat floor surface capable of storing a plurality of transported bodies and an upper end portion of the plurality of transported bodies disposed above the storage space. A plurality of pulling bodies, a plurality of lifting mechanisms capable of moving up and down the plurality of pulling bodies, and a plurality of pulling bodies that can reciprocate in the row direction by one pitch corresponding to the length in the row direction of the transported body. The transfer system according to claim 1, further comprising: a transfer mechanism.