JP5115513B2 - Transport vehicle - Google Patents

Description

  The present invention relates to a transport vehicle, and more particularly, to a transport vehicle having a drive wheel unit including a drive wheel and a motor.

  2. Description of the Related Art A transport vehicle for transporting a large glass substrate or a cassette in which a plurality of glass substrates are stored is known. The transport vehicle automatically travels in a clean room in the factory and transports articles between processing devices.

  The track on which the transport vehicle travels is, for example, a rail suspended from the ceiling. In this case, the space in which the rail and the transport vehicle travel is a clean room that is blocked from the outside.

  The conveyance vehicle has wheels on both the left and right sides, one wheel is a driving wheel, and the other wheel is a driven wheel. A motor is connected to the drive wheel.

  The transport vehicle further includes guide rollers that contact the left and right guide rails (see, for example, Patent Document 1).

JP 2002-160628 A

  Since both the driving wheel and the driven wheel are worn, it is necessary to periodically inspect and replace them as necessary. In the conventional wheel mounting structure, in order to replace the driving wheel or the driven wheel, it is necessary to jack up the vehicle body and enter an operator below the vehicle body.

  However, since the jack-up and the work from the lower side of the vehicle body are work in a narrow space, there is a problem that the work becomes complicated. That is, the maintenance of the drive wheels of the transport vehicle is not easy.

  An object of the present invention is to facilitate maintenance of a drive wheel unit of a transport vehicle.

The transport vehicle according to the present invention includes a vehicle body frame and a drive wheel unit. The drive wheel unit is detachably attached to the left and right sides of the body frame. The drive wheel unit has a mounting plate, a motor, and a drive wheel. The mounting plate has a first portion disposed on the body frame and a second portion extending downward from the end of the first portion, and is detachably mounted on the body frame. The motor is fixed to the second part. The drive wheel is driven by a motor.
In this transport vehicle, when the mounting plate is removed from the vehicle body frame, the drive wheel unit can be removed from the vehicle body frame by lifting the entire drive wheel unit upward. Therefore, the maintenance work of the drive wheel unit is facilitated.

The transport vehicle may further include a second vehicle body frame and a driven wheel unit. The driven wheel unit is detachably attached to the left and right sides of the second body frame. The driven wheel unit has a second mounting plate, a shaft, and a driven wheel. The second mounting plate has a third portion disposed on the second body frame and a fourth portion extending downward from the end of the third portion, and is detachably attached to the second body frame. The shaft is fixed to the fourth portion. The driven wheel is rotatably attached to the shaft.
In this transport vehicle, when the second mounting plate is removed from the vehicle body frame, the driven wheel unit can be removed from the vehicle body frame by lifting the entire driven wheel unit upward. Therefore, the maintenance work of the driven wheel unit is facilitated.

The transport vehicle may further include a vehicle body. The vehicle body has a pair of placement members that extend in the left-right direction of the vehicle body and on which articles are placed, and a plurality of connecting members that extend in the longitudinal direction of the vehicle body and connect the pair of placement members. The vehicle body frame is attached to the vehicle body. The drive wheel unit has a pair of drive wheel units that are detachably attached to the left and right sides of the body frame. The driven wheel unit has a pair of driven wheel units that are detachably attached to the left and right sides of the second body frame.
In this transport vehicle, only a plurality of connecting members extend in the longitudinal direction of the vehicle body, and a large space can be secured above the drive wheel unit. Therefore, when removing the drive wheel unit, the drive wheel unit can be taken out from the gaps between the plurality of connecting members.
The body frame has left and right end portions formed with openings opened on both the left and right sides, the motor is disposed on the inner side of the opening of the body frame, and the driving wheel is disposed on the opening of the body frame. It may be arranged outside.
The first portion of the mounting plate is placed and fixed on the upper surface of both side end portions of the body frame, and the second portion of the mounting plate extends downward from the end portion of the first portion and is outside the opening of the body frame. And the drive wheels may be supported.

  In the transport vehicle according to the present invention, the maintenance work of the drive wheel unit is facilitated.

The schematic plan view of the conveyance vehicle in one Embodiment of this invention. The schematic plan view of a conveyance vehicle. The schematic plan view of a conveyance vehicle. The schematic side view of a conveyance vehicle. The top view of a drive travel part. The top view of a driven traveling part. The schematic plan view of the branch part and curved part of the carrier system as one embodiment of the present invention. The block diagram which shows the control structure of the conveyance vehicle system as one Embodiment of this invention. The flowchart which shows the control operation of the conveyance vehicle in a branch part. The flowchart which shows the control operation of the conveyance vehicle in a curve part. The schematic front view which shows the 1st state of a branch guide roller. The schematic front view which shows the 2nd state of a branch guide roller. The schematic front view which shows the 3rd state of a branch guide roller. The schematic plan view of a 1st drive wheel unit. The schematic longitudinal cross-sectional view of a 2nd drive wheel unit.

(1) Carrier Vehicle System A carrier vehicle system as an embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a schematic plan view of a transport vehicle 3 according to an embodiment of the present invention. FIG. 2 is a schematic plan view of the transport vehicle 3. FIG. 3 is a schematic plan view of the transport vehicle 3. FIG. 4 is a schematic side view of the transport vehicle 3.

  The transport vehicle system 1 includes a track 2 and a transport vehicle 3 that travels on the track 2. In this embodiment, the track 2 is suspended from the ceiling, and the periphery of the track 2 is a clean room.

The track 2 includes a traveling rail 4 and a guide rail 6 as shown in FIG.
The traveling rail 4 includes a pair of left and right first traveling rails 4a and a second traveling rail 4b. The first traveling rail 4a and the second traveling rail 4b have flat traveling surfaces.

  The guide rail 6 has a first guide rail 6a and a second guide rail 6b. The first guide rail 6a and the second guide rail 6b are provided at the outer ends of the first travel rail 4a and the second travel rail 4b, respectively. The first guide rail 6a and the second guide rail 6b extend upward.

  Further, as shown in FIG. 1, a pair of first power supply line 10a and second power supply line 10b are provided along the first travel rail 4a and the second travel rail 4b. A power supply device (not shown) is provided at one end of the first power supply line 10a and the second power supply line 10b. The power supply device supplies high-frequency power to the first power supply line 10a and the second power supply line 10b.

  As shown in FIG. 7, the track 2 has a straight portion 7, a curved portion 8, a branch portion 9, and a merging portion (not shown).

  A plurality of types of detected parts provided along the traveling rail 4 will be described with reference to FIG. The detected portion includes a reflective tape 104, an iron plate 105, and a barcode 106. The reflective tape 104 is a member for detecting the position of the transport vehicle 3 at the curved portion 8, and is disposed inside the first traveling rail 4 a at the curved portion 8 in the drawing. The iron plate 105 is a member for detecting the conveyance vehicle stop position 118, the start position of the curved portion 8, the branch point 9a, and the like. In the drawing, the iron plate 105 is disposed inside the first traveling rail 4a before the branching point 9a of the branching section 9, and further disposed inside the first traveling rail 4a before the transport vehicle stop position 118. Yes. The bar code 106 functions as an origin mark and a plurality of reference marks of the traveling rail 4, and in the figure, a plurality of barcodes 106 are arranged inside the second traveling rail 4b.

Transport vehicle 3 includes a mount 11, and a traveling section 12.
The placement unit 11 has a structure for placing the article 17. Mount 11 includes a pair of mounting member 13 extending in the left and right sides in the traveling direction front and rear ends, and a plurality of connecting members 14 extending in the longitudinal running direction in order to couple the pair of mounting members 13 . Mounting member 13 includes a mounting portion 13a that extends in the lateral direction, and the bar portion 13b extending downward from the right and left end of the mounting portion, the connecting portion extending horizontally to connect the lower ends of the column portion 13b 13c. The connecting member 14 connects the connecting portions 13 c of the mounting member 13. The connecting member 14 includes four members, which include a pair of left and right outer members 14a and a pair of left and right inner members 14b. A first attachment portion 15 and a second attachment portion 16 to which the traveling portion 12 is attached are provided between the front and rear ends of the left and right inner member 14b. In the mounting portion 11, the first attachment portion 15 is disposed on the front side in the traveling direction, and the second attachment portion 16 is disposed on the rear side in the traveling direction.

  The traveling unit 12 includes a driving traveling unit 18 and a driven traveling unit 19. The drive traveling unit 18 and the driven traveling unit 19 are bogies that are rotatably attached to the first attachment unit 15 and the second attachment unit 16, respectively.

(2) Drive travel unit The drive travel unit 18 will be described with reference to FIG. FIG. 5 is a plan view of the drive travel unit 18.

  The drive travel unit 18 mainly includes a main body frame 20, a first drive wheel unit 21, a second drive wheel unit 22, a fixed guide roller mechanism 23, and a branch guide roller mechanism 24.

(2-1) Main body frame The main body frame 20 is a thin plate-like member for supporting each member. The main body frame 20 is elongated in the left-right direction, the bearing 35 for supporting the shaft (not shown) extending the first mounting portion 15 or we are provided in the central portion.

(2-2) First Drive Wheel Unit The first drive wheel unit 21 is attached to the right end portion of the main body frame 20, and includes a first drive wheel 25, a first motor 26, and a first speed reducer 27. And a first encoder 96. The first drive wheels 25 are placed on the travel surface of the first travel rail 4a. The first motor 26 is connected to the first drive wheel 25 via a first speed reducer 27. The first encoder 96 measures the rotation of the first motor 26 and transmits a pulse signal. Thereby, the rotation speed and the number of rotations of the first motor 26 can be obtained.

(2-3) Second Drive Wheel Unit The second drive wheel unit 22 is attached to the left end portion of the main body frame 20, and includes a second drive wheel 28, a second motor 29, and a second speed reducer 30. And a second encoder 97. The second drive wheels 28 are placed on the travel surface of the second travel rail 4b. The second motor 29 is connected to the second drive wheel 28 via the second reduction gear 30. The second encoder 97 measures the rotation of the second motor 29 and transmits a pulse signal. Thereby, the rotation speed and the number of rotations of the second motor 29 can be obtained.

(2-4) Fixed Guide Roller Mechanism The fixed guide roller mechanism 23 includes a first fixed guide roller 31, a second fixed guide roller 32, a third fixed guide roller 33, and a fourth fixed guide roller 34. ing.

  The first fixed guide roller 31 and the second fixed guide roller 32 are disposed at the right end portion of the main body frame 20 so as to be separated in the traveling direction. More specifically, the first fixed guide roller 31 and the second fixed guide roller 32 are disposed apart from each other on both the front and rear sides in the traveling direction of the first drive wheel 25, and always contact or approach the inner side of the first guide rail 6a. is doing. The third fixed guide roller 33 and the fourth fixed guide roller 34 are arranged at the left end portion of the main body frame 20 so as to be separated in the front-rear direction. More specifically, the third fixed guide roller 33 and the fourth fixed guide roller 34 are disposed apart from each other on both the front and rear sides in the traveling direction of the second drive wheel 28, and always contact or approach the inner side of the second guide rail 6b. is doing.

(2-5) Branching guide roller mechanism The branching guide roller mechanism 24 is a mechanism for performing a branching operation in the branching section 9, and includes a first branching guide roller 36, a second branching guide roller 37, and a third branching guide. A roller 38, a fourth branch guide roller 39, and a branch guide roller driving mechanism 40 are provided.

  The first branch guide roller 36 and the second branch guide roller 37 are disposed corresponding to the first fixed guide roller 31 and the second fixed guide roller 32. The branch guide roller mechanism 24 further includes a first member 101 (described later) to which a first branch guide roller 36 and a second branch guide roller 37 are rotatably connected.

  The third branch guide roller 38 and the fourth branch guide roller 39 are disposed corresponding to the third fixed guide roller 33 and the fourth fixed guide roller 34. The branch guide roller mechanism 24 further includes a second member 103 (described later) to which a third branch guide roller 38 and a fourth branch guide roller 39 are rotatably connected.

  The branch guide roller drive mechanism 40 is a mechanism for changing the positions of the first branch guide roller 36, the second branch guide roller 37, the third branch guide roller 38, and the fourth branch guide roller 39. The branch guide roller drive mechanism 40 includes a first cylinder 42, a first shaft 43, a second shaft 44, and a connecting shaft 45.

  The first cylinder 42 is an electric cylinder and is arranged to generate a propulsive force in the left-right direction. The first cylinder 42 is supported by a trunnion method.

  The first shaft 43 is provided on the first branch guide roller 36 and the second branch guide roller 37 side. The first shaft 43 extends in the front-rear direction and is rotatably supported by the main body frame 20. Further, the first shaft 43 is movable in the left-right direction by the rod of the first cylinder 42.

  The first member 101 includes a first portion 47 extending in the front-rear direction, a pair of second portions 48 extending inward in the left-right direction from both ends of the first portion 47, and a pair of first portions extending upward from the ends of the second portion 48. And three portions 49. As described above, the first branch guide roller 36 and the second branch guide roller 37 are rotatably connected to both ends of the first portion 47 in the front-rear direction.

  A connecting portion between the second portion 48 and the third portion 49 is a rotation center portion 51. The rotation center portion 51 is rotatably supported by an axis center extending in the front-rear direction with respect to the main body frame 20. The tip of the third portion 49 is rotatably connected to the first shaft 43. Therefore, when the first shaft 43 is driven in the left-right direction by the first cylinder 42, the first shaft 43 rotates about the rotation center portion 51.

  With the above structure, when the first shaft 43 moves in the left-right direction, the first member 101 rotates about the rotation center portion 51. At this time, the first branch guide roller 36 and the second branch guide roller 37 move between a guide position that is in contact with or close to the outside of the first guide rail 6a and a non-guide position away from the first guide rail 6a. To do.

  The second shaft 44 is provided on the third branch guide roller 38 and the fourth branch guide roller 39 side. The second shaft 44 extends in the front-rear direction and is rotatably supported by the main body frame 20. The second shaft 44 is movable in the left-right direction.

  The connecting shaft 45 extends in the left-right direction, and connects the first shaft 43 and the second shaft 44. More specifically, the end of the connecting shaft 45 is rotatably connected to the first shaft 43 and the second shaft 44.

  The second member 103 includes a fourth portion 52 extending in the front-rear direction, a pair of fifth portions 53 extending inward in the left-right direction from both ends of the fourth portion 52, and a pair of first portions extending upward from the ends of the fifth portion 53. 6 portions 54. As described above, the third branch guide roller 38 and the fourth branch guide roller 39 are rotatably connected to both ends of the fourth portion 52 in the front-rear direction.

  A connecting portion between the fourth portion 52 and the fifth portion 53 is a rotation center portion 55. The rotation center portion 55 is rotatably supported on an axis center extending in the front-rear direction with respect to the main body frame 20. The tip of the fifth portion 53 is rotatably connected to the second shaft 44. Accordingly, when the second shaft 44 is driven in the left-right direction by the connecting shaft 45, the second shaft 44 rotates about the rotation center portion 55.

  With the above structure, when the second shaft 44 moves in the left-right direction, the second member 103 rotates about the rotation center portion 55. At this time, the third branch guide roller 38 and the fourth branch guide roller 39 move between a guide position that is in contact with or close to the outside of the second guide rail 6b and a non-guide position that is away from the second guide rail 6b. To do.

  At this time, the positions of the first branch guide roller 36, the second branch guide roller 37, the third branch guide roller 38, and the fourth branch guide roller 39 change symmetrically. The positional relationship among the first branch guide roller 36 and the second branch guide roller 37, the third branch guide roller 38, and the fourth branch guide roller 39 changed by the branch guide roller driving mechanism 40 is as follows.

In the first state, as shown in FIG. 11, the first branch guide roller 36 and the second branch guide roller 37 are separated from the first guide rail 6a (in the first non-guide position), and the third branch guide roller 38 and the fourth branch guide roller 39 are separated from the second guide rail 6b (in the first non-guide position).
In the second state, as shown in FIG. 12, the first branch guide roller 36 and the second branch guide roller 37 are in contact with or close to the first guide rail 6a (in the guide position), and the third branch guide. The roller 38 and the fourth branch guide roller 39 are separated from the second guide rail 6b (in the second non-guide position).
In the third state, as shown in FIG. 13, the first branch guide roller 36 and the second branch guide roller 37 are separated from the first guide rail 6a (in the second non-guide position), and the third branch guide roller 38 and the fourth branch guide roller 39 are in contact with or close to the second guide rail 6b (in the guide position).

The driving traveling unit 18 is provided with a first pickup unit 79a and a second pickup unit 79b for obtaining high-frequency power from the first feeder line 10a and the second feeder line 10b.
(3) Driven traveling unit The driven traveling unit 19 will be described with reference to FIG. FIG. 6 is a plan view of the driven traveling unit 19.

  The driven section 19 mainly has a main body frame 57, a first driven wheel unit 58, a second driven wheel unit 59, a fixed guide roller mechanism 60, and a branch guide roller mechanism 61.

(3-1) Main body frame The main body frame 57 is a thin plate-like member for supporting each member. The main body frame 57 extends in the left-right direction, and a bearing 74 that supports a shaft (not shown) extending from the second mounting portion 16 is provided in an intermediate portion.

(3-2) First driven wheel unit The first driven wheel unit 58 is attached to the right end portion of the main body frame 57 and has a first driven wheel 62. The first driven wheel 62 is placed on the traveling surface of the traveling rail 4. The first driven wheel 62 is rotatably supported by a shaft 98 fixed to the main body frame 57.

(3-3) Second Follower Wheel Unit The second follower wheel unit 59 is attached to the left end portion of the main body frame 57 and has a second follower wheel 63. The second driven wheel 63 is placed on the traveling surface of the traveling rail 4. The second driven wheel 63 is rotatably supported by a shaft 99 fixed to the main body frame 57.

(3-4) Fixed Guide Roller Mechanism The fixed guide roller mechanism 60 includes a first fixed guide roller 65, a second fixed guide roller 66, a third fixed guide roller 67, and a fourth fixed guide roller 68. ing.
Since the fixed guide roller mechanism 60 is the same as the fixed guide roller mechanism 23, the description thereof is omitted below.

(3-5) Branching guide roller mechanism The branching guide roller mechanism 61 is a mechanism for performing a branching operation in the branching section 9, and includes a first branching guide roller 69, a second branching guide roller 70, and a third branching guide. A roller 71, a fourth branch guide roller 72, and a branch guide roller driving mechanism 73 are provided.

The branch guide roller drive mechanism 73 is a mechanism for changing the positions of the first branch guide roller 69, the second branch guide roller 70, the third branch guide roller 71, and the fourth branch guide roller 72. The branch guide roller drive mechanism 73 includes a second cylinder 91, a third shaft 92, a fourth shaft 93, and a second connection shaft 94.
Since the branch guide roller mechanism 61 is the same as the branch guide roller mechanism 24, the description thereof is omitted below.

(4) Branch part The branch part 9 is demonstrated using FIG. FIG. 7 is a schematic plan view of the branch portion 9 and the curved portion 8 of the transport vehicle system 1 as one embodiment of the present invention.

  The track 2 includes a straight portion 7, a branch portion 9, a curved portion 8 that turns to the right from the branch portion 9, and a second portion 7 a that extends straight from the branch portion 9.

  The first traveling rail 4a and the second traveling rail 4b extend separately in both a curved portion 8 and a branch portion 9.

In the curved portion 8, the first guide rail 6a is formed continuously, but the second guide rail 6b is partially interrupted. A plurality of reflective tapes 104 are installed on the curved portion 8 along the first traveling rail 4a.
In the second portion 7a, the second guide rail 6b is formed continuously, but a part of the first guide rail 6a is interrupted.

In this embodiment, it refers to the entire part component containing a portion of the straight portion 7 and the curved portion 8 and the branching section 9, a point where the branch is started among them that branch point 9a.

(5) Sensor and to-be-detected part The driving | running | working driving | running | working part 18 has the 1st photoelectric sensor 75 and the 2nd photoelectric sensor 76 further. The first photoelectric sensor 75 is for detecting the reflective tape 104 stretched on the first traveling rail 4a, and in particular for detecting the reflective tape 104 while traveling on the right curved portion. The second photoelectric sensor 76 is for detecting a reflective tape (not shown) stretched on the second traveling rail 4b, and in particular, detects the reflective tape (not shown) while traveling on the left curved portion. Is to do.

  The driven traveling unit 19 further includes a linear scale 77 and a barcode reader 78. The linear scale 77 is for detecting the iron plate 105 stretched on the first traveling rail 4a. The barcode reader 78 is for detecting the barcode 106 stretched on the second traveling rail 4b.

(6) Control Configuration FIG. 8 is a block diagram showing a control configuration of the transport vehicle system 1 as one embodiment of the present invention.

  The transport vehicle system 1 includes a transport vehicle controller 80 and a CAD system 81.

The transport vehicle controller 80 is a controller for managing the traveling of the plurality of transport vehicles 3. The transport vehicle controller 80 and the transport vehicle 3 can communicate with each other. The transport vehicle controller 80 includes a controller main body 82 and a first memory 83. The controller main body 82 is a computer that includes a CPU, a RAM, a ROM, and the like and executes a program. A route map is stored in the first memory 83.
The route map is a map that describes the arrangement of the travel route, the position of the origin, the reference position based on the origin, and the coordinates of the transfer position. The coordinates are obtained by converting the travel distance from the origin into the number of output pulses of the encoder of the transport vehicle.
The transport vehicle 3 continues traveling while comparing the coordinates described in the route map with the internal coordinates of the own machine (coordinates obtained by the encoder).

  The CAD system 81 is a system for designing and storing a travel route. The CAD system 81 has a system main body 84 and a second memory 85. The system main body 84 is a computer that includes a CPU, a RAM, a ROM, and the like and executes a program. The system main body 84 designs a travel route and stores data at that time in the second memory 85 as a layout map. The function of the CAD system 81 may be realized by the transport vehicle controller 80.

  The transport vehicle 3 includes a control unit 87 and a third memory 90. The control unit 87 is a computer that includes a CPU, a RAM, a ROM, and the like and executes a program. The control unit 87 is connected to the travel control unit 88. The traveling control unit 88 can transmit a signal for driving the first motor 26 and the second motor 29 based on a command from the control unit 87. The control unit 87 is further connected to the branch control unit 89. The branch control unit 89 can transmit a signal for driving the first cylinder 42 and the second cylinder 91 based on a command from the control unit 87.

  Further, a first encoder 96, a second encoder 97, a first photoelectric sensor 75, a second photoelectric sensor 76, a linear scale 77 and a barcode reader 78 are connected to the control unit 87.

  A route map is stored in the third memory 90. The transport vehicle 3 calculates a travel distance from the difference between the coordinates of the current position on the route map and the coordinates of the target position, thereby generating a travel speed pattern. In addition, the transport vehicle 3 obtains internal coordinates by the first encoder 96 and the second encoder 97, calculates the remaining travel distance to the destination, and when this value becomes a predetermined value or less, the travel control unit 88 performs a deceleration process. Do. The values of the first encoder 96 and the second encoder 97 are reset to the coordinates of the origin when the origin mark is detected, and are changed to the coordinates of the reference when the reference mark is detected.

(7) Branching operation FIG. 9 is a flowchart showing the control operation of the transport vehicle 3 in the branching section 9. Here, the control operation by the transport vehicle controller 80 will be mainly described.

  In step S <b> 1, the process waits for the transport vehicle 3 to reach a point before the branching section 9. For this determination, the transport vehicle controller 80 uses the detection results from the linear scale 77 and the detection results from the first encoder 96 and the second encoder 97. During normal running, as shown in FIG. 11, the branch guide rollers (36 to 39 and 69 to 72) are arranged at the non-guide positions.

  In step S2, it is determined whether the information of the first encoder 96 and the second encoder 97 is normal. If normal, the process proceeds to step S3, where the detection result from the linear scale 77 and the detection results from the first encoder 96 and the second encoder 97 are collated to confirm the current position. In this case, the values of the first encoder 96 and the second encoder 97 may be corrected based on the detection result from the linear scale 77. If it is abnormal, the process proceeds to step S4, where the current position is confirmed based only on the detection result from the linear scale 77. At this time, when moving to the curved portion 8 next time, the conveyance vehicle 3 starts to decelerate.

  In step S5, it waits for the conveyance vehicle 3 to reach the branch point 9a. If not, the process returns to step S2. When it reaches, the process proceeds to step S6.

  In step S6, when branching to the right side, as shown in FIG. 12, the first cylinder 42 is driven to lower the first branch guide roller 36 and the second branch guide roller 37, and the second cylinder 91 is further moved. Driven to lower the first branch guide roller 69 and the second branch guide roller 70. When branching to the left, as shown in FIG. 13, the first cylinder 42 is driven to lower the third branch guide roller 38 and the fourth branch guide roller 39, and the second cylinder 91 is further driven to The third branch guide roller 71 and the fourth branch guide roller 72 are lowered.

In step S7, it waits for the conveyance vehicle 3 to pass the branch point 9a. After passing through the branch point 9a, the first cylinder 42 and the second cylinder 91 are driven, and the branch guide rollers (36 to 39 and 69 to 72) that have been lowered are separated from the guide rail 6 as shown in FIG. .

If the branch destination is a straight line portion, the process proceeds to step S9 to execute straight line control.
When the branch destination is a curved portion, the process proceeds to step S10, and curve control is executed.

(8) Curve Control FIG. 10 is a flowchart showing the control operation of the transport vehicle in the curved portion. Here, the control operation by the transport vehicle controller 80 will be mainly described.

  In step S11, it is determined whether the information of the first encoder 96 and the second encoder 97 is normal. If normal, the process proceeds to step S12, and the current position is confirmed by collating the detection results from the first photoelectric sensor 75 or the second photoelectric sensor 76 and the detection results from the first encoder 96 and the second encoder 97. In this case, for example, by interpolating with the position information of the first encoder 96 and the second encoder 97 between the reflective tapes 104, the position of the transport vehicle at the curved portion can be continuously confirmed. If abnormal, the process proceeds to step S4, and the current position is confirmed based only on the detection result from the first photoelectric sensor 75 or the second photoelectric sensor 76.

  In step S14, based on the current position information, the first motor 26 and the second motor 29 are driven via the travel control unit 88 so that an appropriate left-right speed difference is generated.

  In step S15, it waits for the conveyance vehicle 3 to reach the end point of the curved portion. If not, the process returns to step S11.

(9) Attachment / detachment structure and attachment / detachment operation of the drive wheel unit and driven wheel unit The attachment / detachment structure and attachment / detachment operation of the first drive wheel unit 21 and the second drive wheel unit 22 will be described. FIG. 14 is a schematic plan view of the first drive wheel unit 21. FIG. 15 is a schematic longitudinal sectional view of the first drive wheel unit 21. Since the structures of the first drive wheel unit 21 and the second drive wheel unit 22 are the same, only the first drive wheel unit 21 will be described below.

  As described above, the first drive wheel unit 21 includes the first drive wheel 25, the first motor 26, and the first speed reducer 27, and further includes the first mounting plate 110. .

  The first attachment plate 110 is a member for detachably attaching other members of the first drive wheel unit 21 to the main body frame 20. The first attachment plate 110 is attached to the right end portion of the main body frame 20.

  Openings that are open to the left and right sides are formed at the left and right ends of the main body frame 20. As is clear from FIG. 14, the first motor 26 and the first speed reducer 27 are disposed on the inner side of the end portion of the main body frame 20, but the first driving wheel 25 is disposed on the outer side from the opening of the main body frame 20. ing.

  The first mounting plate 110 has a first portion 111 and a second portion 112. The first portion 111 is a flat plate placed on the upper surface of the right end portion of the main body frame 20. The first portion 111 has fixing portions 111a on both front and rear sides, and a connecting portion 111b. A plurality of bolt through holes 111c are formed in the fixing portion 111a. A bolt 119 passes through the bolt through hole 111 c and is screwed into a screw hole 20 a formed in the main body frame 20.

  The second portion 112 is a plate-like portion that extends downward from the end 111 d of the fixing portion 111 a of the first portion 111. The second part 112 is fixed to the first part 111 by welding. A portion that supports the first drive wheel 25 (for example, the first speed reducer 27) is fixed to the second portion 112.

  As is apparent from the above, the first drive wheel unit 21 is fixed to the main body frame 20 by the first mounting plate 110, and the first mounting plate 110 can be removed upward from the main body frame 20. Thus, when the first drive wheel unit 21 is slightly jacked up and the bolt 119 is further removed, the first drive wheel unit 21 is removed from the main body frame 20 so as to be pulled upward (in the direction of arrow R in FIG. 15). Can do.

  Moreover, in the conveyance vehicle 3, since the mounting part 11 has only a mounting member 13 and a plurality of connecting members 14, the first drive wheel unit 21 can be easily removed. Specifically, as shown in FIG. 3, the first drive wheel unit 21 can be pulled upward from between the left and right direction outer member 14a and the left and right direction inner member 14b.

  As described above, the first driven wheel unit 58 includes the first driven wheel 62 and the shaft 98, and further includes the second mounting plate 115. Since the first driven wheel unit 58 and the second driven wheel unit 59 have the same structure, only the first driven wheel unit 58 will be described below.

  The second attachment plate 115 is a member for detachably attaching other members of the first driven wheel unit 58 to the main body frame 57. The second attachment plate 115 is attached to the right end portion of the main body frame 57. Openings that are open to the left and right sides are formed at the left and right ends of the main body frame 57.

The second mounting plate 115 has a third portion 116 and a fourth portion 117 . The third portion 116 is a flat plate placed on the upper surface of the right end portion of the main body frame 57. The third portion 116 has fixing portions 116a on both the front and rear sides, and a connecting portion 116b . A plurality of bolt through holes 116c are formed in the fixing portion 116a . Bolts (not shown) pass through the bolt through holes 116 c and are screwed into screw holes (not shown) formed in the main body frame 57.

The fourth portion 117 is a plate-like portion extending downwardly from the end portion 116d of the fixing portion 116a of the third portion 116. The fourth portion 117 is fixed to the third portion 116 by welding. A shaft 98 is fixed to the fourth portion 117 .

  Since the removal operation of the first driven wheel unit 58 is the same as the removal operation of the first drive wheel unit 21, the description thereof will be omitted below.

(10) Features The transport vehicle 3 includes a main body frame 20 and a first drive wheel unit 21. The first drive wheel unit 21 is detachably attached to the left and right sides of the main body frame 20. The first drive wheel unit 21 has a first mounting plate 110, a first motor 26, and a first drive wheel 25. The first mounting plate 110 includes a first portion 111 disposed on the main body frame 20 and a second portion 112 extending downward from the end portion 111d of the first portion 111, and is detachably attached to the main body frame 20. ing. The first motor 26 is fixed to the second portion 112. The first drive wheel 25 is driven by the first motor 26.
In the transport vehicle 3, when the first mounting plate 110 is removed from the main body frame 20, the first driving wheel unit 21 can be removed from the main body frame 20 by lifting the entire first driving wheel unit 21 upward. Therefore, maintenance work of the first drive wheel unit 21 is facilitated.

The transport vehicle 3 further includes a main body frame 57, a first driven wheel unit 58 and a second driven wheel unit 59. The first driven wheel unit 58 is detachably attached to the left and right sides of the main body frame 57. The first driven wheel unit 58 includes a second mounting plate 115, a shaft 98, and a first driven wheel 62. The second mounting plate 115 has a third portion 116 disposed on the main body frame 57 and a fourth portion 117 extending downward from the end of the third portion 116, and is detachably attached to the main body frame 57. Yes. The shaft 98 is fixed to the fourth portion 117. The first driven wheel 62 is rotatably attached to the shaft 98.
In the transport vehicle 3, when the second mounting plate 115 is removed from the main body frame 57, the first driven wheel unit 58 can be detached from the main body frame 57 by lifting the entire first driven wheel unit 58 upward. Therefore, maintenance work of the first driven wheel unit 58 is facilitated.

The transport vehicle 3 further includes a vehicle body. The vehicle body has a pair of mounting members 13 that extend in the left-right direction of the vehicle body and on which the article 17 is mounted, and a plurality of connecting members 14 that extend in the vehicle front-rear direction and connect the pair of mounting members 13. The main body frame 20 is attached to the vehicle body. The first drive wheel unit 21 and the second drive wheel unit 22 are detachably attached to the left and right sides of the main body frame 20. The first driven wheel unit 58 and the second driven wheel unit 59 are detachably attached to the left and right sides of the main body frame 57.
In the transport vehicle 3, only a plurality of connecting members 14 extend in the longitudinal direction of the vehicle body, and a large space can be secured above the first drive wheel unit 21. Therefore, when removing the first drive wheel unit 21, the first drive wheel unit 21 can be taken out from the gaps between the plurality of connecting members 14.

(11) Other Embodiments Although one embodiment of the present invention has been described above, the present invention is not limited to the above embodiment, and various modifications can be made without departing from the scope of the invention.

  In the embodiment described above, the transport vehicle travels on a track suspended from the ceiling, but the present invention is not limited to this. The track may be provided on the ground, or the transport vehicle may be suspended from the track.

  In the embodiment, the encoder measures the rotation of the motor, but the present invention is not limited to this. The encoder may measure the rotation of the driving wheel or the driven wheel.

The types of detection target and sensor combinations and the detection purposes are not limited to the above-described embodiment.
The installation position and number of the detection target parts are not limited to the above embodiment.

  The present invention is applicable to a transport vehicle having a drive wheel unit including a drive wheel and a motor.

DESCRIPTION OF SYMBOLS 1 Transfer vehicle system 2 Track 3 Transfer vehicle 4 Travel rail 4a 1st travel rail 4b 2nd travel rail 6 Guide rail 6a 1st guide rail 6b 2nd guide rail 7 Straight line part 7a 2nd part 8 Curved part 9 Branch part 9a Branch Point 10a First power supply line 10b Second power supply line 11 Placement part (vehicle body)
DESCRIPTION OF SYMBOLS 12 Traveling part 13 Mounting member 13a Mounting part 13b Pillar part 13c Connecting part 14 Connecting member 14a Left-right direction outer side member 14b Left-right direction inner side member 15 1st attaching part 16 2nd attaching part 17 Article 18 Drive traveling part 19 20 Body frame (body frame)
20a Screw hole 21 First drive wheel unit 22 Second drive wheel unit 23 Fixed guide roller mechanism 24 Branch guide roller mechanism 25 First drive wheel 26 First motor 27 First speed reducer 28 Second drive wheel 29 Second motor 30 First 2 reduction gear 31 first fixed guide roller 32 second fixed guide roller 33 third fixed guide roller 34 fourth fixed guide roller 35 bearing 36 first branch guide roller 37 second branch guide roller 38 third branch guide roller 39 fourth Branch guide roller 40 Branch guide roller drive mechanism (moving mechanism)
42 1st cylinder 43 1st shaft 44 2nd shaft 45 Connection shaft 47 1st part 48 2nd part 49 3rd part 51 Rotation center part 52 4th part 53 5th part 54 6th part 55 Rotation center part 57 Body frame (second body frame)
58 First driven wheel unit 59 Second driven wheel unit 60 Fixed guide roller mechanism 61 Branch guide roller mechanism 62 First driven wheel 63 Second driven wheel 65 First fixed guide roller 66 Second fixed guide roller 67 Third fixed guide roller 68 Fourth fixed guide roller 69 First branch guide roller 70 Second branch guide roller 71 Third branch guide roller 72 Fourth branch guide roller 73 Branch guide roller drive mechanism 74 Bearing 75 First photoelectric sensor 76 Second photoelectric sensor 77 Linear Scale 78 Bar code reader 79a First pick-up unit 79b Second pick-up unit 80 Transport vehicle controller 81 CAD system 82 Controller main body 83 First memory 84 System main body 85 Second memory 87 Control unit 88 Travel control unit 89 Branch control unit 90 Memory 91 Second Second shaft 92 Third shaft 93 Fourth shaft 94 Second connecting shaft 96 First encoder 97 Second encoder 98 Shaft 99 Shaft 101 First member 103 Second member 104 Reflective tape 105 Iron plate 106 Bar code 110 First mounting plate 111 First Part 111a Fixing part 111b Connection part 111c Bolt through-hole 111d End part 112 Second part 115 Second attachment plate 116 Third part 117 Fourth part 118 Conveyor stop position 119 Bolt

Claims (3)

Body frame,
And a pair of driving wheels unit which is removably attached to the right and left sides of the vehicle body frame,
The drive wheel unit is
A mounting plate having a first portion disposed on the body frame and a second portion extending downward from an end portion of the first portion and removably attached to the body frame, and fixed to the second portion a motor that is, has a drive wheel driven by the motor,
A second body frame;
A pair of driven wheel units removably attached to the left and right sides of the second body frame;
The driven wheel unit is
A second attachment plate removably attached to the second vehicle body frame, having a third portion disposed on the second vehicle body frame and a fourth portion extending downward from an end of the third portion; A shaft fixed to the fourth portion; and a driven wheel rotatably attached to the shaft;
A vehicle body body having a pair of mounting members that extend in the left-right direction of the vehicle body and on which articles are mounted; and a plurality of connecting members that extend in the vehicle longitudinal direction and connect the pair of mounting members;
The body frame and the second body frame are attached to the body body;
Transport vehicle.   The vehicle body frame has left and right side end portions formed with openings opened on the left and right sides,
  The motor is disposed inside the opening of the body frame,
  The transport vehicle according to claim 1, wherein the driving wheel is disposed outside the opening of the body frame.   The first portion of the mounting plate is placed and fixed on the upper surface of the both end portions of the body frame,
  3. The transport vehicle according to claim 2, wherein the second portion of the mounting plate extends downward from an end portion of the first portion, is disposed outside the opening of the body frame, and supports the driving wheel.

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