JP2015147519A - Tracked dolly - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a tracked dolly capable of collecting garbage on a track with a simple structure.SOLUTION: In a tracked dolly system, a tracked dolly for transportation runs along a rail laid on a ceiling in a semiconductor manufacturing factory etc. The tracked dolly 100 running along the rail 70 includes: a rotation brush 46 which contacts with at least a bottom part 71 of the rail 70 and rotates in conjunction with a running wheel; a guide brush 48 which guides garbage from the lateral side of the track to the rotation brush; and a collection part 47 which collects the garbage sent to the rear side in a travel direction by the rotation brush 46.

Description

  The present invention relates to a tracked carriage.

  In a semiconductor manufacturing factory or the like, for example, a tracked carriage for transporting a tracked carriage for carriage along a rail laid on the ceiling in order to transfer articles such as a semiconductor wafer transfer container (FOUP) and a reticle transfer vehicle. The system is used. In such a tracked bogie system, if garbage accumulates on the rail, it may interfere with the travel of the tracked bogie. For this reason, it is necessary to periodically remove dust on the rail. For example, Patent Document 1 describes a technique for removing dust on a current collecting rail using a rotating brush.

JP 2012-148838 A

  However, in the configuration described in Patent Document 1, there is a risk that the removed dust will scatter around and stain the periphery of the rail. For this reason, a mechanism for collecting the removed dust is required.

  In view of the circumstances as described above, it is an object of the present invention to provide a tracked carriage that can collect track dust with a simple configuration.

  In this invention, it is a tracked trolley | bogie which travels along a track | truck, Comprising: The brush contact | abutted to at least one part of a track | orbit, and the collection | recovery part which collect | recovers the dust sent with the brush are provided.

  In addition, a rotating brush may be used as the brush, and the collection unit may be disposed so as to collect the dust sent to the rear in the traveling direction by the rotating brush. Further, the rotating brush may rotate in conjunction with the traveling wheel. Moreover, you may provide the guide brush which guides garbage to the rotating brush from the side of a track | orbit. A plurality of guide brushes may be arranged in the traveling direction. Further, among the plurality of guide brushes, the front guide brush in the traveling direction has a shorter guide length from the side of the track than the rear guide brush, and a guide angle with respect to the traveling direction with respect to the rear guide brush. It may be small. Further, the brush and the collection unit may be provided in a second carriage connected to the first carriage including the travel drive unit. Further, the second carriage may be coupled to the front side in the traveling direction with respect to the first carriage.

  According to the present invention, since the dust sent by the brush that abuts at least a part of the track can be collected, the track dust can be collected with a simple configuration.

  In addition, if the rotating brush is used as the brush and the collecting unit is arranged so as to collect the dust sent to the rear in the traveling direction by the rotating brush, the dust can be collected efficiently. In addition, when the rotating brush rotates in conjunction with the traveling wheel, the rotating brush can be reliably rotated during traveling, so that dust can be reliably collected. In addition, with a guide brush that guides dust to the rotating brush from the side of the track, dust can be collected more reliably. In addition, when a plurality of guide brushes are arranged in the traveling direction, dust can be reliably collected by the plurality of guide brushes. Of the plurality of guide brushes, the front guide brush in the traveling direction has a shorter guide length from the side of the track than the rear guide brush, and the guide angle with respect to the traveling direction is smaller than the rear guide brush. Since it is small, the front guide brush can apply a strong sliding force for a short time to the track or dust as compared to the rear guide brush. For this reason, for example, dust caught on a screw or the like on the track can be easily swept away by the strong sliding force of the front guide brush and then guided to the rotating brush with the rear guide brush. it can. Thereby, it is possible to reliably collect garbage. Further, in the case where the brush and the collection unit are provided in the second carriage connected to the first carriage provided with the traveling drive unit, the second carriage is connected to the first carriage as necessary to remove dust. It can be recovered. Further, in the case where the second carriage is connected to the front side in the traveling direction with respect to the first carriage, since the first carriage travels on the track where the dust is collected, smooth running is possible. .

It is a side view showing an example of a tracked truck according to an embodiment. It is a figure which shows an example when the cleaning trolley is seen from the bottom side. It is a figure which shows an example when the cleaning trolley is seen from the side part side. It is a figure which shows an example when the cleaning trolley is seen from the front of the running direction. (A)-(c) is a figure which shows an example of the operation | movement which collect | recovers garbage of a bottom part using a cleaning trolley | bogie. It is a figure which shows an example of a tracked bogie which concerns on a modification. It is sectional drawing which shows an example of the collection | recovery part which concerns on a modification.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the present invention is not limited to this. Further, in the drawings, in order to describe the embodiment, the scale is appropriately changed and expressed by partially enlarging or emphasizing the description. In the following drawings, directions in the drawings will be described using an XYZ coordinate system. In this XYZ coordinate system, a plane parallel to the horizontal plane is defined as an XY plane. In this XY plane, the traveling direction of the tracked carriage 100 and one linear direction is expressed as a Y direction for convenience, and a direction orthogonal to the Y direction is expressed as an X direction. The traveling direction of the tracked carriage 100 can be changed from the state shown in the following figure to another direction, and for example, it may travel in a curved direction. A direction perpendicular to the XY plane is expressed as a Z direction. In each of the X direction, the Y direction, and the Z direction, the direction of the arrow in the figure is the + direction, and the direction opposite to the arrow direction is the − direction. Further, the rotation direction around the X axis is denoted as θX direction, and the rotation direction around the Z axis is denoted as θZ direction.

FIG. 1 is a side view showing an example of a tracked carriage 100 according to the embodiment.
As shown in FIG. 1, the tracked carriage 100 includes a main body 10, a front carriage 20, a rear carriage 30, a cleaning carriage 40, and a control unit 50. The tracked vehicle 100 travels along the rail 70 provided in the ceiling space of the clean room. In this clean room, for example, various processing apparatuses such as a semiconductor processing apparatus and a glass substrate processing apparatus are arranged. The tracked carriage 100 accommodates, for example, a hoop (FOUP) for accommodating a silicon wafer for manufacturing a semiconductor device and a glass substrate for manufacturing a liquid crystal device between processes such as a film forming process and a cleaning process. It is used when an article 80 such as a container or a reticle pod that accommodates a reticle for performing an exposure process is conveyed.

  As shown in FIG. 1, the main body portion 10 includes a base portion 11, a front shaft portion 12, and a rear shaft portion 13. The base 11 is formed in the longitudinal direction in the traveling direction (Y direction) of the tracked carriage 100. The upper surface 11a of the base 11 is formed along a horizontal plane (XY plane), and for example, an article 80 or the like can be placed thereon.

  The front shaft portion 12 and the rear shaft portion 13 are formed in a columnar shape or a cylindrical shape, for example, and are disposed along the Z direction. The front shaft portion 12 and the rear shaft portion 13 are arranged with a space in the Y direction. The front shaft portion 12 and the rear shaft portion 13 are fixed to the −Z side surface of the base portion 11 and are provided integrally with the base portion 11.

  The front carriage 20 is a bogie that can turn in the θZ direction with respect to the main body 10. The front cart 20 is disposed inside the rail 70 and travels along the rail 70. The front cart 20 includes a traveling unit 21 and a power receiving unit 22. The front cart 20 is integrally provided with a traveling unit 21 and a power receiving unit 22.

  The traveling unit 21 includes a traveling unit frame 23, traveling wheels 24, and guide wheels 25. The traveling unit frame 23 is formed in a plate shape, for example. The traveling part frame 23 is connected to the front shaft part 12 via a bearing (not shown). A traveling drive unit 28 is provided in the traveling unit frame 23. The travel drive unit 28 includes, for example, a coil (not shown) and constitutes a linear motor mechanism with a magnet disposed on the rail 70 side. The travel drive unit 28 may be provided in the rear cart 30 or may be provided in both the front cart 20 and the rear cart 30.

  The traveling wheels 24 are provided at two places in total, one at the + X side end and one at the −X side end of the traveling portion frame 23. The traveling wheel 24 is disposed so as to roll on the bottom 71 of the rail 70. As the traveling wheel 24 rolls on the bottom 71, the traveling unit 21 travels in the traveling direction.

  The guide wheels 25 are provided at a total of four locations, two on the + X side and two on the −X side in the traveling unit frame 23. The guide wheel 25 can rotate in the θZ direction around a shaft parallel to the Z direction. Each guide wheel 25 is in contact with the side portion 72 of the rail 70 and guides the traveling portion 21 to travel along the rail 70.

The power receiving unit 22 receives power supply from the power supply lines 61 and 62. The power reception unit 22 includes a power reception unit frame 26 and a core 27.
The power receiving unit frame 26 is provided integrally with the traveling unit frame 23. The power receiving unit frame core 27 is disposed at the + X side end and the −X side end of the power receiving unit frame 26, respectively. The core 27 is formed using, for example, ferrite or the like, and includes a base portion 27a, a first protruding portion 27b, a second protruding portion 27c, and a third protruding portion 27d. A coil (not shown) is wound around the second protrusion 27c. In the space between the first projecting portion 37b and the second projecting portion 37c, the power supply line 61 is disposed in a non-contact manner. In addition, the power supply line 62 is disposed in a non-contact manner in the space between the second projecting portion 37c and the third projecting portion 37d.

  When power is supplied from the power supply lines 61 and 62 to the power receiving unit 22, a magnetic field is generated by flowing a high-frequency current through the power supply lines 61 and 62, and this magnetic field is applied to the coil of the second projecting portion 27c. Inductive current is generated. In this way, electric power is supplied from the power supply lines 61 and 62 to the power receiving unit 22 in a contactless manner. The supplied electric power drives the traveling drive unit 28 or supplies it to various devices. The power supply lines 61 and 62 are supported by a support member (not shown).

  On the other hand, the rear carriage 30 is a bogie that can turn in the θZ direction with respect to the main body portion 10, as with the front carriage 20. The rear cart 30 is provided behind the front cart 20 in the traveling direction. The rear carriage 30 is disposed inside the rail 70 and travels along the rail 70. The rear cart 30 includes a traveling unit 31 and a power receiving unit 32.

  The traveling unit 31 includes a traveling unit frame 33, traveling wheels 34, and guide wheels 35. The traveling part frame 33 is connected to the rear shaft part 13 via a bearing (not shown). The traveling wheels 34 are provided at a total of two locations, one at the + X side end and one at the −X side end of the traveling frame 33. The traveling wheel 34 is arranged so as to roll on the bottom 71 of the rail 70. As the traveling wheel 34 rolls on the bottom 71, the traveling unit 31 travels in the traveling direction.

  The guide wheels 35 are provided at a total of four locations, two on the + X side and two on the −X side in the traveling unit frame 33. The guide wheel 35 can rotate in the θZ direction around a shaft parallel to the Z direction. Each guide wheel 35 is brought into contact with the side portion 72 of the rail 70 and guides the traveling portion 31 to travel along the rail 70.

  Similarly to the power reception unit 22, the power reception unit 32 receives power from the power supply lines 61 and 62 that configure the power supply unit 60. The power reception unit 32 includes a power reception unit frame 36 and a core 37. The power receiving unit frame 36 is provided integrally with the traveling unit frame 33. The power receiving unit frame 36 is disposed at the center in the X direction. The cores 37 are respectively disposed at the + X side end and the −X side end of the power reception unit frame 36.

  The core 37 has the same configuration as the core 27 on the front cart 20 side. That is, the core 37 is formed using, for example, ferrite or the like, and includes a base portion 37a, a first protruding portion 37b, a second protruding portion 37c, and a third protruding portion 37d. A coil is wound around the second protrusion 37c. In the space between the first projecting portion 37b and the second projecting portion 37c, the power supply line 61 is disposed in a non-contact manner. In addition, the power supply line 62 is disposed in a non-contact manner in the space between the second projecting portion 37c and the third projecting portion 37d.

  When power is supplied from the power supply lines 61 and 62 to the power receiving unit 32, similarly to the power supply to the power receiving unit 22, a magnetic field is generated by flowing a high-frequency current through the power supply lines 61 and 62. An induced current is generated in this coil by acting on the coil of the protrusion 37c. The power supplied to the power receiving unit 32 can be supplied to various devices.

  Subsequently, the cleaning carriage 40 is coupled to the front carriage 20 in the traveling direction. The cleaning cart 40 travels with the driving of the front cart 20. The cleaning carriage 40 is disposed inside the rail 70 and travels along the rail 70. The cleaning carriage 40 has a traveling part 41 and a connecting part 42.

FIG. 2 is a diagram illustrating an example when the cleaning carriage 40 is viewed from the bottom 71 side. FIG. 3 is a diagram illustrating an example when the cleaning carriage 40 is viewed from the side 72 side (in the + X direction). FIG. 4 is a diagram illustrating an example when the cleaning carriage 40 is viewed from the front in the traveling direction (in the −Y direction).
As shown in FIGS. 2 to 4, the traveling unit 41 includes a traveling unit frame 43, traveling wheels (traveling wheels) 44, guide wheels 45, a rotating brush 46, a collection unit 47, and a guide brush 48. Have.

  The traveling unit frame 43 is formed in a plate shape, for example. The traveling unit frame 43 is coupled to the traveling unit frame 23 of the front carriage 20 via the coupling unit 42. The connection part 42 has the 1st axial part 42a, the plate-shaped member 42b, and the 2nd axial part 42c. The first shaft portion 42a, the plate-like member 42b, and the second shaft portion 42c are integrally formed. The traveling unit frame 43 is provided to be rotatable in the θZ direction with respect to the first shaft portion 42a. Further, the traveling unit frame 23 of the front carriage 20 is provided so as to be rotatable in the θZ direction with respect to the second shaft portion 42c. Thus, since the connecting portion 42 that connects the cleaning carriage 40 and the front carriage 20 can rotate in the θZ direction at two locations, the cleaning carriage 40 is independent of the front carriage 20 in the θZ direction. It can be rotated.

  The traveling wheels 44 are provided in a total of two locations, one on the + X side and one on the −X side in the traveling unit frame 43. In order to prevent the difference between the inner wheels during curve traveling, the traveling wheel 44 disposed on the + X side and the traveling wheel 44 disposed on the −X side are provided to be independently rotatable. The traveling wheels 44 are arranged so as to roll on the bottom 71 of the rail 70. As the traveling wheel 44 rolls on the bottom 71, the traveling unit 41 travels in the traveling direction.

  The guide wheels 45 are provided in a total of four locations, two on the + X side and two on the −Z side in the traveling unit frame 43. The guide wheel 45 can rotate in the θZ direction around a shaft parallel to the Z direction. Each guide wheel 45 is in contact with the side portion 72 of the rail 70 and guides the traveling portion 41 to travel along the rail 70.

  The rotating brush 46 is provided on the lower surface (surface on the −Z side) 43 a of the traveling unit frame 43. The rotating brush 46 has a shaft portion 46a and a brush bristle portion 46b. The shaft portion 46a is formed in a cylindrical shape and is disposed in parallel with the X direction. The shaft portion 46a is provided to be rotatable around the X axis (θX direction).

  The shaft portion 46 a is provided so as to rotate in conjunction with one of the two traveling wheels 44. The shaft portion 46 a rotates in the same direction as the traveling wheel 44. For example, the shaft portion 46a may be common with the rotating shaft of the traveling wheel 44, or the shaft portion 46a and the rotating shaft of the traveling wheel 44 may be provided separately, and these may be provided by a rotation transmission mechanism (not shown) or the like. You may connect so that it may rotate in the same direction.

  The brush bristle part 46b extends linearly from the peripheral surface of the shaft part 46a in the radial direction. The brush bristles 46b are formed with a uniform density over the entire peripheral surface of the shaft 46a. Further, the brush bristle portion 46b has a substantially uniform length (dimension in the radial direction of the shaft portion 46a). The brush bristle portion 46b is provided integrally with the shaft portion 46a. Therefore, when the shaft portion 46a rotates, the brush bristle portion 46b rotates integrally with the shaft portion 46a. The brush bristle portion 46 b is disposed so that at least the tip thereof is in contact with the bottom portion 71 of the rail 70. In addition, when the brush bristle part 46b contacts the bottom part 71, the brush bristle part 46b may be in a curved state so as to have an elastic force. In addition, in the example shown in FIG.1 and FIG.2 (a), although a part of brush bristle part 46b has entered the inside of the collection | recovery part 47, it is not limited to this, Brush bristle part 46b May be provided outside the collection unit 47.

  The collection unit 47 is detachably provided on the lower surface 43a of the traveling unit frame 43 by a fixing member (not shown). The collection unit 47 is formed in a box shape and collects dust sent by the rotating brush 46. The collection unit 47 has an opening 47a. The opening 47a is formed in front of the cleaning carriage 40 in the traveling direction, and is directed to the rotating brush 46 side.

  The collection unit 47 is formed with a storage chamber 47k for storing garbage. The storage chamber 47k communicates with the outside through the opening 47a. The collection unit 47 collects the dust that enters from the opening 47a in the storage chamber 47k. In addition, the structure which arrange | positions the bag body etc. which accommodate refuse in the storage chamber 47k, and replaces | exchanges only a bag body may be sufficient.

  The lower part of the storage chamber 47k may be formed so as to be inclined downward toward the opening 47a side. In this case, the lower side of the opening 47 a of the collection unit 47 acts like a dust ring on the rotating brush 46. Thereby, the dust sent by the rotating brush 46 can be efficiently collected.

  In addition, you may make it regulate the fall of the garbage collect | recovered in the storage chamber 47 by providing a cover etc. in a part of opening part 47a. Moreover, the structure connected to the storage chamber 47k may be sufficient as the suction mechanism for making the storage chamber 47k into a negative pressure. In this case, by setting the storage chamber 47k to a negative pressure, dust can be sucked and collected from the opening 47a.

The guide brush 48 collects dust on the side of the rail 70 in the center. The guide brush 48 includes a front guide brush 48a and a rear guide brush 48b.
The front guide brush 48 a is detachably provided on the lower surface 43 a of the traveling unit frame 43. The front guide brush 48a is disposed at the front end in the traveling direction of the lower surface 43a. The front guide brush 48a is provided in total, two on each side in the X direction. The front guide brush 48a is disposed at a position that passes over a screw 73 (see FIG. 2) provided on the side of the bottom 71.

  The front guide brush 48a has a flat outer shape. The front guide brush 48a is disposed to be inclined by a predetermined angle (guide angle) α with respect to the traveling direction (Y direction) of the cleaning carriage 40. The front guide brush 48a is disposed so as to be inclined so that the front in the traveling direction opens outward. The front guide brush 48a has a predetermined dimension (guide length) d1 in the longitudinal direction.

  The front guide brush 48a has a brush bristle portion 48c. The front guide brush 48 a is disposed such that the hair tip of the brush bristle portion 48 c faces the bottom portion 71. The bristles of the brush bristle part 48 c are aligned in one direction parallel to the bottom part 71. The length of the hair of the brush bristle part 48c is gradually increased toward the front end part of the front guide brush 48a. The tip of the brush bristle portion 48 c is in contact with the bottom portion 71.

  The rear guide brush 48b is detachably provided on the lower surface 43a of the traveling unit frame 43 in the same manner as the front guide brush 48a. The front guide brush 48a is disposed at the front end in the traveling direction of the lower surface 43a. The front guide brush 48a is provided in total, two on each side in the X direction. The front guide brush 48a is disposed at a position that passes over a screw 73 (see FIG. 2) provided on the side of the bottom 71.

  The rear guide brush 48b has a flat outer shape. The rear guide brush 48b is disposed to be inclined by a predetermined angle (guide angle) β with respect to the traveling direction (Y direction) of the cleaning carriage 40. Note that the rear guide brush 48b is inclined and arranged so that the front in the traveling direction opens outward, like the front guide brush 48a. The rear guide brush 48b has a predetermined dimension (guide length) d2 in the longitudinal direction.

  The rear guide brush 48b has a brush bristle portion 48d. The rear guide brush 48d is disposed such that the hair tip of the brush bristle portion 48d faces the bottom portion 71. The bristles of the brush bristle part 48 d are aligned in one direction parallel to the bottom part 71. The length of the hair of the brush bristle part 48d is gradually increased toward the front end part of the rear guide brush 48d. Further, the front end portion of the rear guide brush 48 b extends to a position close to the outer end portion of the guide wheel 45. As a result, dust can be swept across the bottom 71 by the rear guide brush 48b. The tip of the brush bristle portion 48d is in contact with the bottom portion 71.

  Here, the guide length d1 of the front guide brush 48a is smaller than the guide length d2 of the rear guide brush 48b. Further, the guide angle α of the front guide brush 48a is smaller than the guide angle β of the rear guide brush 48b. For this reason, the bristle portion 48c of the front guide brush 48a can apply a strong sliding force to the bottom portion 71 for a short time compared to the brush bristle portion 48d of the rear guide brush 48b. On the other hand, the rear guide brush 48b can collect dust in a wider range than the front guide brush 48a.

  For example, as shown in FIG. 4, when the cleaning carriage 40 is viewed from the front in the traveling direction, the lower side of the traveling unit frame 43 is between one side 72 and the other side 72 of the rail 70. Is covered by a rotating brush 46, a front guide brush 48a, and a rear guide brush 48b. For this reason, with these brushes, dust is collected across the bottom 71 of the rail 70.

  In addition, the control unit 50 comprehensively controls each part of the main body unit 10, the front cart 20, the rear cart 30, and the cleaning cart 40. The control unit 50 includes, for example, a CPU (Central Processing Unit), various storage devices, and the like, and these are connected by a data bus or the like. The control unit 50 may be connected to an external central control device or the like wirelessly or by wire. In addition, the control part 50 controls the speed at the time of driving | running | working, a stop position, etc. corresponding to the structure by which the cleaning trolley | bogie 40 was connected ahead of the front side trolley | bogie 20. FIG.

Next, an operation when collecting dust on the bottom 71 using the cleaning carriage 40 will be described.
When the front cart 20 travels, the cleaning cart 40 travels so as to be pushed by the front cart 20. When the cleaning carriage 40 travels, the two traveling wheels 44 rotate. By this rotation, the shaft portion 46 a connected to one rotation roller 44 rotates in the same direction as the rotation roller 44. By the rotation of the shaft portion 46a, the brush bristle portion 46b rotates and sweeps the bottom portion 71 in the -Y direction. By the sweeping operation of the brush bristles 46b, the dust on the bottom 71 is sent to the rear of the cleaning carriage 40 in the traveling direction (-Y direction). The garbage sent to the rear is collected by the collection unit 47. The collection unit 47 is detached, and the collected unit 47 is fixed to the lower surface 43 a of the traveling unit frame 43 again in a state where the collected garbage is discarded and the accommodation chamber 47 k is emptied. Thereafter, the above operation is repeated.

  Further, when the cleaning carriage 40 advances, the bottom 71 is swept by the front guide brush 48a and the rear guide brush 48b, and the dust collected on the side of the bottom 71 is collected in the center. In this case, since the rotating brush 46 sends the dust collected by the front guide brush 48a and the rear guide brush 48b to the rear, the dust is efficiently sent to the collection unit 47.

FIGS. 5A to 5C are diagrams illustrating an example of an operation of collecting dust on the bottom portion 71 using the cleaning carriage 40.
For example, as shown in FIG. 5A, when a screw 73 is provided on the side of the bottom portion 71, dust 74 may be caught on the screw 73. For such dust 74, even if a sliding force of the brush is applied once in the traveling direction, the dust 74 may not be removed while being caught by the screw 73.

  On the other hand, in the cleaning carriage 40, the front guide brush 48a and the rear guide brush 48b are disposed at positions where the screws 73 pass. For this reason, when the cleaning carriage 40 is caused to travel, first, the front guide brush 48a slides on the screw 73 as shown in FIG. At this time, a strong sliding force for a short time acts on the screw 73 and the dust 74. By this action, the direction of the dust 74 changes with the screw 73 as the center, and the degree of catching is reduced.

  Thereafter, when the cleaning carriage 40 is advanced, the rear guide brush 48b slides on the screw 73 as shown in FIG. Since the degree of catching of the dust 74 is reduced, the dust 74 is detached from the screw 73 by the sliding of the rear guide brush 48b and is collected on the rotating brush 46 side by the rear guide brush 48b. In this manner, the dust 74 caught on the screw 73 can be collected by sliding the screw 73 in the two-stage configuration of the front guide brush 48a and the rear guide brush 48b.

  As described above, according to the present embodiment, the rotating brush 46 that contacts at least a part of the rail 70 and the collection unit 47 that collects the dust sent by the rotating brush 46 are provided. The garbage on the rail 70 can be collected with a simple configuration that only collects the sent garbage.

The embodiment has been described above, but the present invention is not limited to the above description, and various modifications can be made without departing from the gist of the present invention.
For example, in the above-described embodiment, the configuration in which the rail 70 is not directly provided on the ceiling portion in the ceiling space is described as an example, but the present invention is not limited to this. For example, the present invention can be applied to a configuration in which a rail is attached to a ceiling and the vehicle travels in a state where a tracked carriage is suspended from the rail.

FIG. 6 is a diagram illustrating an example of a tracked carriage 100A according to a modification.
The tracked truck 100A travels along a rail 70A provided on the ceiling 101, and includes a main body 10A, a front truck 20, a rear truck 30, a cleaning truck 40A, and a controller 50A. I have. About the front side trolley 20 and the rear side trolley 30, it is the same structure as the said embodiment. However, in this case, the traveling drive unit 28 of the front carriage 20 constitutes a linear motor mechanism with the magnet disposed on the ceiling 101. The travel drive unit 28 may be provided in the rear cart 30 or may be provided in both the front cart 20 and the rear cart 30.

The rail 70A has an upper portion 73A fixed to the ceiling portion 101, a side portion 72A extending downward from the upper portion 73A, and a bottom portion 71A extending inward from the lower end portion of the side portion 72A. A space is provided in the X direction between the bottom portions 71A.
The main body 10 </ b> A is disposed below the front cart 20 and the rear cart 30. For example, a transfer device (not shown) is attached to the main body 10A. The cleaning carriage 40A has a traveling part 41A and a connecting part 42. The structure of the connection part 42 is the same as that of the said embodiment.

  The traveling unit 41A includes a traveling unit frame 43, traveling wheels 44, guide wheels 45, a brush 46A, and a collection unit 47A. Among these, the traveling unit frame 43, the traveling wheels 44, and the guide wheels 45 are the same as those in the above embodiment.

  The brush 46A has a front brush 46Aa and a rear brush 46Ab. The individual configurations of the front brush 46Aa and the rear brush 46Ab are the same as those of the front guide brush 48a and the rear guide brush 48b of the above embodiment, respectively. Here, the front brush 46Aa and the rear brush 46Ab are used to send the dust on the bottom 71A to the collection unit 47A.

  That is, the dust on the bottom 71A is moved toward the center by the front brush 46Aa and the rear brush 46Ab. And it falls below from between the bottom parts 71A. On the other hand, in the present modification, the collection unit 47A is disposed between the bottoms 71A so as to receive the dropped dust.

  As described above, even when the rail 70A is attached to the ceiling portion 101 and travels in a state where the tracked carriage 100 is suspended from the rail 70A, only the dust sent by the brush 46A is collected. With this simple configuration, the dust on the rail 70A can be collected.

Further, a mechanism for preventing the backflow of dust may be added to the collection unit 47 of the above embodiment. FIG. 7 is a cross-sectional view illustrating an example of the collection unit 47B according to the modification.
As shown in FIG. 7, the collection unit 47 </ b> B has a scraper 49. The scraper 49 is formed in a plate shape, for example, and is fixed to the + Y side tip portion 47Bb of the bottom portion of the recovery portion 47B. The scraper 49 is provided over the entire X direction of the tip portion 47Bb.

  The tip portion 47Bb to which the scraper 49 is fixed is curved downward (−Z side). The scraper 49 is disposed along the curved portion of the tip portion 47Bb. Therefore, the scraper 49 has an upper end portion 49a protruding from the tip portion 47Bb to the −Y side, and a lower end portion 49b protruding from the tip portion 47Bb to the + Y side.

  An upper end portion 49a of the scraper 49 enters the accommodation chamber 47k from the tip portion 47Bb, and protrudes in the + Z direction from the bottom portion of the recovery portion 47B. For this reason, the lower side of the opening 47Ba is covered with the upper end 49a. Accordingly, the dust stored in the storage chamber 47k of the recovery unit 47B is restricted from being discharged to the outside of the opening 47Ba by the upper end portion 49a. For this reason, it is possible to prevent the dust collected in the collection unit 47B from flowing backward.

  Further, the lower end portion 49 b of the scraper 49 is gradually formed thinner toward the tip, and is curved in the + Y direction along the bottom portion 71. For this reason, it becomes the structure which is easy to guide the dust of the bottom part 71 toward the storage chamber 47k.

Moreover, although the said embodiment gave and demonstrated the structure which sends refuse to the collection | recovery part 47 by the rotating brush 46, it does not limit to this.
For example, the configuration may be such that dust is brought to the center by the guide brush 48 and collected by the collection unit 47 without providing the rotating brush 46.

  Further, instead of the rotating brush 46, gas may be jetted from the front to the rear in the traveling direction below the traveling unit frame 43, and the dust may be sent to the collecting unit 47 by this air flow. Further, the configuration in which dust is brought from the side of the bottom 71 to the center by the guide brush 48 has been described as an example, but the present invention is not limited to this. For example, gas is injected from the side of the bottom 71 to the center. You may make it send garbage.

  In this case, for example, a gas supply source (for example, a small tank) is disposed on the traveling frame 43. In addition, a nozzle for injecting gas is arranged on the lower surface of the traveling unit frame 43. What is necessary is just to connect between a nozzle and a gas supply source via piping etc. Moreover, about a nozzle, a gas injection direction can be set so that adjustment is possible.

  In the above embodiment, the configuration in which the rotating brush 46 is rotated in conjunction with the rotation of the traveling wheel 44 has been described as an example. However, the present invention is not limited to this. For example, a configuration in which a rotation driving mechanism (for example, a motor mechanism) for rotating the rotating brush 46 is separately provided may be used.

  In the above-described embodiment, the guide brush 48 has been described by taking as an example the configuration in which the guide brush 48 includes the front guide brush 48a and the rear guide brush 48b in the traveling direction, but the present invention is not limited to this. For example, a configuration in which only one guide brush 48 is provided in the traveling direction may be used. Moreover, the structure by which three or more guide brushes are provided in the advancing direction may be sufficient. As a result, even dust caught on the screw can be reliably collected.

  Moreover, in the said embodiment, although the structure which connects the cleaning trolley | bogie 40 to the front of the front side trolley 20 was mentioned as an example and demonstrated, it is not limited to this. For example, the structure which connects the cleaning trolley | bogie 40 to the back of the rear trolley | bogie 30 may be sufficient. In this case, the control unit 50 controls the traveling speed, stop position, and the like corresponding to the configuration in which the cleaning carriage 40 is connected to the rear of the rear carriage 30.

  Moreover, in the said embodiment, although demonstrated taking the example of the structure which fixed the guide brush 48, it is not limited to this, It is good also as a structure which moves the guide brush 48. FIG. In this case, for example, the guide brush 48 can be moved in the longitudinal direction. Thereby, since it can slide on the bottom part 71, dust can be scraped off more effectively. For example, the dust 74 caught on the screw 73 can be efficiently removed by moving the front guide brush 48a in the longitudinal direction. Further, the guide brush 48 may be moved in the traveling direction of the cleaning carriage 40 or may be moved in a direction orthogonal to the traveling direction.

  α, β: Guide angle d1, d2: Guide length 20 ... Front side carriage (first carriage) 28 ... Traveling drive unit 40 ... Cleaning carriage (second carriage) 44 ... Traveling wheel 46 ... Rotating brush (brush, rotating brush) 46A ... Brush 47, 47A ... Recovery part 48 ... Guide brush 48a ... Front side guide brush 48b ... Rear side guide brush 70, 70A ... Rail (track)

Claims (8)

A tracked carriage that runs along a track,
A tracked carriage comprising: a brush that abuts at least a part of the track; and a collection unit that collects garbage sent by the brush. The brush is a rotating brush,
The tracked carriage according to claim 1, wherein the collection unit is arranged so as to collect garbage sent backward in the traveling direction by the rotating brush.   The tracked carriage according to claim 2, wherein the rotating brush rotates in conjunction with a traveling wheel.   The tracked carriage according to claim 2 or 3, further comprising a guide brush that guides dust to the rotating brush from a side of the track.   The tracked carriage according to claim 4, wherein a plurality of the guide brushes are arranged in the traveling direction.   Of the plurality of guide brushes, the front guide brush in the traveling direction has a shorter guide length from the side of the track than the rear guide brush and a guide angle with respect to the traveling direction with respect to the rear guide brush. A tracked carriage according to claim 5.   The tracked cart according to any one of claims 1 to 6, wherein the brush and the recovery unit are provided on a second cart connected to a first cart including a travel drive unit.   The tracked carriage according to claim 7, wherein the second carriage is connected to the front side in the traveling direction with respect to the first carriage.

Images