JP6995366B2 - Goods transfer device - Google Patents

Description

The present invention relates to an article transporting device.

Conventionally, as a transfer device for supplying an article to a packaging machine, a transfer device using the principle of a linear motor, for example, Patent Document 1 is known. The transport device of Patent Document 1 is such that a plurality of traveling objects can be circulated while being guided by an endless guide rail formed by connecting a pair of linear straight rails and a pair of curved curved rails. By supporting the guide rails by two rollers provided on each traveling body in the front-rear direction in the traveling direction and opposed rollers located on the inner peripheral side or the outer peripheral side of the rollers via the guide rails, the vehicle travels from the guide rails. It prevents the body from coming off and prevents the traveling body from tilting toward the guide rail in the traveling direction. Further, as a characteristic detailed structure in Patent Document 1, the sliding surface of the guide rail on which the rollers slide is formed in a V shape and is engaged with the protrusions formed on the outer periphery of each roller to form a traveling body. The fixed unit is positioned so as to be located in the center of the pair of attached permanent magnets, and the change in electromagnetic force due to the change in the distance of the permanent magnets with respect to the fixed unit is suppressed.

Japanese Patent No. 6280220

However, in the transport device in Patent Document 1, when the traveling body travels on a straight rail among the endless guide rails, smooth traveling can be expected because the distance between the two rollers and the opposing rollers is constant. When approaching the rail, the traveling body is tilted with respect to the rail, so that the distance between the two rollers and the opposing roller that sandwich the guide rail varies. For example, if the roller attached to the front in the traveling direction of the traveling body is located on the curved rail and the roller rearward in the traveling direction of the traveling body is located on the straight rail, the roller located on the curved rail will be separated from the curved rail. , Vibration and abnormal noise will be generated. On the other hand, if each roller is arranged on the traveling body so that the roller and the curved rail come into contact with each other based on the state of being located on the curved rail, the roller and the straight rail interfere with each other in the state of being located on the straight rail. It becomes a factor that causes vibration and abnormal noise. The generation of such vibrations and abnormal noises becomes more prominent as the traveling speed of the traveling body increases. In addition, if the rail is worn due to the traveling body repeatedly running on the guide rail, the initial roller and rail may not be kept in contact with each other, and vibration or abnormal noise may occur due to the gap caused by the wear. There is also.

An object of the present invention is to provide an article transporting device capable of suppressing the generation of vibration and the like.

In order to solve the above problems, the article transporting apparatus of the present invention takes the following means. First, the invention according to claim 1 is
An endless th orbit formed by two linear orbits (213) provided in parallel and two curved orbits (214) connected to both ends of the two linear orbits (213). 1 orbit (201) and
A second orbit (202) having a shape similar to that of the first orbit (201), which is arranged so as to face the inner orbit of the first orbit (201) at a certain distance from the first orbit (201).
A stator (215) provided along the orbit (201, 202) over the entire circumference of the orbit (201, 202).
A mover (231), which is arranged so as to face the stator (215) and generates an electromagnetic force by a magnetic field generated by the stator (215),
It has the mover (231), and includes a plurality of traveling bodies (220) capable of independently traveling along the orbit (201, 202) by the electromagnetic force, and the traveling body (220). ) Is an article transporting device that transports the article (P) by traveling.
The traveling body (220) is
A first rolling portion that moves on either the inner peripheral side or the outer peripheral side of the first orbital orbit (201) and the first orbital orbital (201).
The second orbit (202) has a relationship opposite to the relationship in which the first rolling portion is arranged on either the inner peripheral side or the outer peripheral side with respect to the first orbit (201). It is provided with a second rolling portion that moves on the second orbit (202) on either the inner peripheral side or the outer peripheral side of the above.
One of the first and second rolling portions includes two rollers (241) arranged apart from each other in the front-rear direction along the traveling direction of the traveling body (220), and the two rollers are provided. (241) rolls while pressing one of the orbitals (201, 202) by the electromagnetic force, and the distance between the stator (215) and the mover (231) is always set to a set distance. It supports the traveling body (220) and supports it.
The other of the first and second rolling portions is a moving roller (242) movably provided with respect to the traveling body (220) so as to be able to come into contact with and separate from the other of the orbits (201, 202). ) And an urging means configured to urge the moving roller (242) to always abut against the other of the orbits (201, 202).
At positions separated in the depth direction intersecting one of the orbits (201, 202), the same size as one of the orbits (201, 202) and the orbit (201, 202). A third orbit (203) parallel to one of them is provided, and the traveling body (220) has one of the third orbit (203) and the orbit (201, 202). The mover (231) is arranged between them, and the roller (243) having the same diameter as each of the two rollers (241) and rolling on the third orbit (203) is provided. By being arranged, it is configured to regulate the tilt of the traveling body (220) in the depth direction .

According to the first aspect of the present invention, a first rolling portion moving on the first orbit (201) and a second rolling portion moving on the second orbit (202) are provided. I have. One of the first and second rolling portions includes two rollers (241) arranged apart from each other in the front-rear direction along the traveling direction of the traveling body (220). The roller (241) rolls while pressing one of the orbitals (201, 202) by an electromagnetic force, and the distance between the stator (215) and the mover (231) is always set to be a set distance. 220) is supported, and either one of the first and second rolling parts can move with respect to the traveling body (220) so as to be able to contact and separate from the other of the orbital tracks (201, 202). It is provided with a moving roller (242) provided in the above and an urging means (226) for urging the moving roller (242) toward the other side of the orbital track (201, 202). Therefore, even in a situation where the traveling body (220) straddles a straight track (213) and a curved track (214), or a situation where the traveling body (220) is located on the curved track (214), the traveling body (220) is located on the curved track (214). Since the moving roller (242) is urged toward the other side of the orbit (201, 202), it is possible to suppress the departure from the track, and it is possible to suppress the generation of vibration and abnormal noise during traveling.

Further , since the urging means (226) is urged so that the moving roller (242) always abuts on the other of the orbits (201, 202), the urging means (226) may be at any position of the other of the orbits (201, 202). Since the moving roller (242) is kept in contact with the track, it is possible to further suppress the generation of vibration, abnormal noise, etc. during traveling of the traveling body (220).

Further , by disposing a roller (243) that rolls on the third orbital track (203), it is configured to regulate the tilting of the traveling body (220) in the depth direction. Therefore, the traveling body (220) can suppress the fluctuation of the electromagnetic force by preventing the tilt fluctuation in the depth direction and keeping the posture constant, and further generates vibrations and abnormal noises during traveling. Can be suppressed.

Next, in the invention according to claim 2, which is subordinate to claim 1 , the linear orbit (213) in the first orbital orbit (201) is in the transport path (110) on which the article (P) is placed. A pusher (236) that is arranged along the line and can abut and push the article (P) placed on the transport path (110) to the rear in the travel direction. ) Is provided.

According to the second aspect of the present invention, the traveling body (220) can convey the article (P) in the transport path (110) while preventing the generation of vibration, abnormal noise, and the like. ..

Next, in the invention according to claim 1 or claim 2, the moving roller (242) has an orbital locus in the first orbital orbit (201) and the second orbital orbit (202). Is supported by a guide (224, 225) that allows movement only in opposite directions.

According to the third aspect of the present invention, since the moving roller (242) is guided only in the direction of contact with the orbit (201, 202), malfunction can be suppressed.

The present invention can provide an article transporting device capable of suppressing the generation of vibration and the like by taking the means of each of the above inventions.

It is a front view which showed the state which pushes each article which arrives continuously toward a packaging machine in the article transporting apparatus which concerns on embodiment. It is a perspective view of the traveling body in the article transporting apparatus. FIG. 3 is a cross-sectional view taken along the line III-III of FIG. FIG. 3 is a sectional view taken along line IV-IV of FIG. It is an enlarged view of the V part of FIG.

Hereinafter, embodiments of the article transporting apparatus of the present invention will be described with reference to the drawings.

As shown in FIG. 1, the article transporting device of the present embodiment independently accelerates or decelerates each of the articles P sequentially placed on the receiving unit 112A for receiving the articles P, or travels at a constant speed. A packaging machine that feeds by the pusher 236 and adjusts the interval in the push direction of each article P and the traveling speed of the pusher 236 from the delivery unit 112B that sends out the article P toward a packaging machine such as a horizontal bag filling machine. It is a device that sends out at regular intervals according to the packaging timing based on the information on the packaging timing obtained from.

As shown in FIG. 1, the article transfer device is mounted on the first transfer bed 110 having a flat transfer surface on which the article P discharged from the first conveyor 100 is placed, and on the first transfer bed 110 above the first transfer bed 110. It is provided with an overhead type second conveyor 200 having a plurality of pushers 236 capable of pushing the placed article P, and an article detecting unit 150 for detecting the article P arriving at the receiving unit 112A.

The first conveyor 100 places the article P discharged from the manufacturing machine on the upstream side at irregular intervals (randomly) in the front-rear direction in the transport direction on the transport surface 102 composed of an endless belt, and delivers the article P at a constant speed. It is a device. A first conveyor bed 110 (conveyor path) is connected to the downstream end 102b of the transport surface 102 of the first conveyor 100.

The first conveyor bed 110 is arranged on the downstream side of the first conveyor 100, and constitutes a flat conveyor surface 112 on which the article P discharged from the first conveyor 100 is placed and linearly conveyed. The portion where the first transport bed 110 and the downstream end 102b of the first conveyor 100 are connected is the receiving portion 112A for receiving the article P.

The article detection unit 150 detects the article P arriving at the receiving unit 112A on the side in the width direction intersecting the transport direction of the first conveyor 100. For example, the article detection unit 150 is composed of a photoelectric sensor or the like. The article detection unit 150 detects the article P on the transport upstream side of the receiving unit 112A.

On the downstream side of the first transport bed 110 of the article transport device, a supply conveyor 300 that constitutes a part of a horizontal bag-making filling machine (not shown) as a packaging machine is arranged. The supply conveyor 300 has a flat mounting surface 302 on which the articles P transmitted from the delivery unit 112B of the first transport bed 110 of the article transport device are sequentially mounted, and is mounted on the mounting surface 302. It is a device that pushes each placed article P by each of the second pushers 322 that arrive at the outer periphery of the endless cord at regular intervals, and conveys each article P at a constant interval and a constant speed. The supply conveyor 300 constitutes a part of a horizontal bag-making filling machine (packaging machine), and is a horizontal bag-making filling machine determined by an operator or the like before operation, and the number of packages per minute (processing capacity). ), The article P is transported at the transport speed of the article P. The portion where the first transport bed 110 and the mounting surface 302 of the supply conveyor 300 are connected is the delivery unit 112B that sends out the article P. The space in which the article P placed on the first transport bed 110 is pushed from the receiving section 112A to the sending section 112B by the pusher 236 corresponds to the transport path of the present invention.

Although not shown, the horizontal bag-making filling machine (packaging machine) forms a strip-shaped film drawn from a raw roll as a film supply source into a tubular shape by superimposing both end edges of the film by a film forming means. At that time, the article P is supplied from the supply conveyor 300 to the film being molded at predetermined intervals, a vertical seal is applied to the polymerized portion of the film laminated along the film feed direction, and the film is crossed in the film feed direction in the left-right direction. It is a well-known packaging machine that obtains a packaged product by applying a horizontal seal along the line.

As shown in FIGS. 1 to 3, the overhead type second conveyor 200 includes a pair of linear linear rails 213 (linear trajectories) arranged horizontally and parallel to each other so as to face each other vertically and vertically. It has a pair of curved curved rails 214 (curved tracks) connecting both ends of the straight rails 213, and the outer peripheral sides of the upper and lower straight rails 213 and the outer peripheral sides of the curved rails 214, respectively. Each of these constitutes a vertically endless first orbital orbit 201. On the inner peripheral side of the first orbital 201, a second orbital 202 having a shape similar to that of the first orbital 201, which is arranged facing each other at a certain distance, is configured. Further, at a position separated to the depth side in the depth direction orthogonal to the virtual plane VP (see FIG. 3) formed by the first orbital track 201 and the second orbital orbit 202, the above-mentioned pair of curved rails 214 and the above-mentioned pair of curved rails 214 A third orbit 203 parallel to the first orbit 201 is provided because it has the same shape and size as the straight rail 213.

Along the first orbital track 201 and the second orbital track 202, a plurality of traveling bodies 220 are arranged so as to be able to circulate in one direction independently of each other by the thrust obtained by the linear motor. Further, the second conveyor 200 is connected to the control unit (not shown) of the horizontal bag-making filling machine so that information can be exchanged, and the traveling body 220 travels based on the detection information of the article P by the article detecting unit 150 and the like. It is equipped with a control unit (not shown) that controls commands to apply thrust to the conveyor. In the linear motor, the coil 215 as a stator that generates a magnetic field over the entire area of the first orbital orbital 201 and the second orbital orbital 202 is arranged along the first orbital orbital 201 and the second orbital orbital 202. A permanent magnet 231 as a mover is fixed to each traveling body 220, and the current supply to the coil 215 is controlled based on a command from the control unit in the second conveyor 200, so that the electromagnetic force generated by the magnetic field generated by the stator is generated. Generates a thrust.

The traveling body 220 in the article transport device includes a main body portion 221, two first rollers 241 as a first rolling portion, two second rollers 242 as a second rolling portion, and a third rolling portion. It has two third rollers 243 as moving parts, a permanent magnet 231 as a mover, and a sensor 232.

The main body portion 221 has a substantially L-shaped frame shape formed by the first support portion 222 and the second support portion 223. The first support portion 222 is a rectangular parallelepiped member adjacent to the width direction (depth direction) intersecting the extending direction (circumferential direction) of the straight rail 213 and the curved rail 214. The second support portion 223 is a flat plate-shaped member arranged in the horizontal direction on the outer peripheral side of the first orbital orbit 201 so as to span the first orbital orbit 201 to the third orbit 203. It is extended to. The main body portion 221 has a structure in which it is slidably fitted to a pair of straight rails 213 and curved rails 214 via a first roller 241 and a second roller 242 as rotating members. A first roller 241 as a first rolling portion on the outer peripheral side of the straight rail 213 and the curved rail 214 on the front side in the depth direction, and a second rolling portion on the inner peripheral side of the straight rail 213 and the curved rail 214. The second roller 242 (moving roller) of the above is configured. A third roller 243 as a third rolling portion is configured on the outer peripheral side of the straight rail 213 and the curved rail 214 on the back side in the depth direction from the first transport bed 110 side. The sizes and shapes of the first roller 241 and the second roller 242 and the third roller 243 are all the same. As a result, the traveling body 220 can move without falling off when traveling in the vertical direction on the straight rail 213 and the curved rail 214. A first roller 241 as a first rolling portion and a second roller 242 as a second rolling portion are rotatably supported on the first support portion 222. A permanent magnet 231 (movable element) is held in the second support portion 223, and a third roller 243 as a third rolling portion is rotatably supported.

The first roller 241 as the first rolling portion moves on the first orbital track 201 on the outer peripheral side of the first orbital track 201, and is separated in the front-rear direction along the traveling direction of the traveling body 220. There are two. The first roller 241 is pivotally supported by the first support portion 222 corresponding to a position along the outer peripheral side of the first orbital track 201. The first roller 241 is rotatably supported by the first support portion 222, but is held so that the shaft support position does not move. The first roller 241 is attracted toward the inner peripheral side of the first orbital orbit 201 by an attractive force consisting of an electromagnetic force in the coil 215 (stator) and the permanent magnet 231 (movable element), and the first orbit is made. It is a structure that rolls while pressing the orbit 201. The state in which the first roller 241 rolling on the outer peripheral side of the first orbital track 201 and the first orbital track 201 are in contact with each other is the reference position of the traveling body 220, and the distance between the coil 215 and the permanent magnet 231 is set. The distance D is set in advance.

The second roller 242 as the second rolling portion has a relationship opposite to the relationship in which the first roller 241 is arranged on the outer peripheral side with respect to the first orbital track 201. It is arranged on the inner peripheral side with respect to the above, and two are provided apart from each other in the front-rear direction along the traveling direction of the traveling body 220 so as to move on the second orbital track 202. The second roller 242 is pivotally supported by the first support portion 222 corresponding to a position along the inner peripheral side of the second orbital track 202. Here, each of the second rollers 242 corresponds to the moving rollers of the present invention provided so as to be movable with respect to the traveling body 220 so as to be in contact with and separated from the second orbital track 202. As shown in FIG. 4, the first support portion 222 is formed with a long groove 224 cut out in a direction in which the first support portion 222 is in contact with and separated from the second orbital orbit 202. A block-shaped sliding guide member 225 having a width corresponding to the opening width of the long groove 224 is slidably fitted in the long groove 224. The sliding guide member 225 is pivotally supported by the rotation axis of the second roller 242 in the width direction intersecting the second circumferential track 202 (in other words, the direction orthogonal to the sliding direction of the sliding guide member 225). There is. As a result, the second roller 242 is configured to allow movement only in the direction in which the orbital loci in the first orbital orbital 201 and the second orbital orbital 202 face each other. The long groove 224 and the sliding guide member 225 correspond to the guide portion of the present invention. Further, the second roller 242 includes a spring 226 (a urging means) for urging toward the second orbit 202. Specifically, a spring 226 (biasing member) is interposed between the sliding guide member 225 and the long groove 224 in the sliding direction of the sliding guide member 225. The separation distance between the two second rollers 242 on the inner peripheral side of the second orbital track 202 is set to be smaller than the separation distance between the two first rollers 241 on the outer peripheral side of the first orbital track 201. .. As a result, the traveling body 220 can smoothly travel even on the curved rail 214.

The third roller 243 as the third rolling portion moves on the third orbital track 203 on the outer peripheral side of the third orbital track 203. Two third rollers 243 are provided on the second support portion 223 so as to be separated from each other in the front-rear direction along the traveling direction of the traveling body 220. The third roller 243 is configured to regulate the tilt of the traveling body 220 in the depth direction by being arranged at the same diameter and pitch as each of the first rollers 241.

The permanent magnet 231 is configured as a mover in the traveling body 220. The permanent magnet 231 is located on the second support portion 223 and at a position separated in the depth direction orthogonal to the virtual plane VP formed by the first orbit 201 and the second orbit 202, and is the first position. It is arranged between the orbit 201 and the third orbit 203. As a result, the current supply is controlled to the coil 215 by providing it inside the orbital orbit from the permanent magnet 231. , And the traveling body 220 can move along the orbital tracks 201, 202, 203 including the pair of straight rails 213 and the curved rails 214.

Further, the sensor 232 is arranged in the main body portion 221. The sensor 232 transmits signals such as unique information of each traveling body 220 (identification data of each traveling body 220 and unique movement error information) to the control unit.

A pusher 236 is arranged on the front side of the width direction intersecting the circulation running direction of the traveling body 220. The traveling body 220 has a base portion 233 rotatable about a fulcrum 234 on the side of the main body portion 221 and is provided with a rod-shaped arm portion 235 extending in the width direction from the base portion 233. .. The pusher 236 is fixed in a hanging shape from the tip of the arm portion 235. The pusher 236 is a flat plate-shaped member, and is provided with a notch 238A having a notch at the center in the width direction, and the tip of the second pusher 322 passes through the notch 238A without contacting the notch 238A. It is configured to get. Further, the front side of the push body 236 is a push surface 238 that pushes the article P placed on the first transport bed 110. Further, on the back surface side opposite to the pushing surface 238, a flat plate-shaped regulating member 239 extending rearward from the tip portion 237 of the pushing body 236 is provided. Further, a cam follower (not shown) is disposed on the base 233. Further, in the range shifted from the straight rail 213 facing the delivery portion 112B of the first transport bed 110 to the curved rail 214 in the orbit 210, the cam groove 216 that engages with the cam follower (not shown) along the orbit 210. Are arranged.

Next, the movement of the article transporting device will be described. As shown in FIGS. 1 to 5, the article P discharged from the manufacturing machine on the upstream side is conveyed toward the first transfer bed 110 by the first conveyor 100. The article detection unit 150 sends the detection information to the control unit each time it detects that the article P arrives at the receiving unit 112A. Upon receiving the detection information, the control unit acquires information regarding the moving position of each second pusher 322 obtained from the pulse information of the encoder attached to the supply conveyor 300 and the like. The control unit determines to which the traveling body 220 the detected article P is associated with the pushing body 236, and gives a traveling command to the traveling body 220 according to the packaging timing of the supply conveyor 300 to travel the traveling body 220. Then, the article P is pushed to the delivery unit 112B.

In the range shifted from the straight rail 213 to the curved rail 214, the cam groove 216 that engages with the cam follower (not shown) along the circuit path is the straight rail 213 of the frame body (not shown) of the second conveyor 200. It is arranged together with the curved rail 214. In the traveling body 220 that has pushed the article P to the sending portion 112B, when the cam follower (not shown) engages with the cam groove 216, the base portion 233 rotates and the tip portion 237 of the pushing body 236 tilts to the rear side. 236 moves the article P without pushing it forward.

Here, when the traveling body 220 travels on the straight rail 213, the urging force acts so that the sliding guide member 225 always abuts on the second orbital track 202 by the urging force of the spring 226. On the other hand, when the traveling body 220 approaches the curved rail 214 from the straight rail 213, the traveling body 220 is in an inclined posture with respect to the rail, so that the distance between the first roller 241 and the second roller 242 that sandwich the rail varies. When the first roller 241 and the second roller 242 in the traveling body 220 move from the straight rail 213 to the curved rail 214 or are located on the curved rail 214, the first roller 241 and the second roller 242 are separated from the curved rail 214. It can be a relationship like this. Here, when the second roller 242 and the second orbit 202 are separated from each other, the second roller 242 is always pressed against the second orbit 202 by the urging of the spring 226. .. This is also the case when the first orbital track 201 or the second orbital track 202 is separated from the curved rail 214 due to the influence of wear or the like. On the other hand, when the first roller 241 and the second roller 242 in the traveling body 220 shift from the curved rail 214 to the straight rail 213, the second roller 242 may be in a relationship of receiving a pressing force from the second orbit 202. .. When the second roller 242 receives a pressing force from the second orbital orbit 202, the spring 226 absorbs the pressing force so that the second roller 242 does not separate from the second orbiting orbit 202. It is designed to move. Therefore, the traveling body 220 is configured to travel while holding the preset distance D in the coil 215 and the permanent magnet 231.

The article transporting device as described above has the following effects.
The traveling body 220 rolls while the first roller 241 presses against the first orbital track 201 from the outer peripheral side by an attractive force consisting of an electromagnetic force in a coil 215 (stator) and a permanent magnet 231 (movable element). Since the moving state is used as a reference, the coil 215 and the permanent magnet 231 are configured to hold a preset distance D, and the first roller 241 generates vibrations and abnormal noises due to the interference of the first orbital track 201. Can be suppressed and moved properly.
Even when the traveling body 220 travels on a portion where the straight rail 213 and the curved rail 214 are worn and the rail width is narrowed, the urging force of the spring 226 between the straight rail 213 and the curved rail 214 and the first roller 241. By pressing the first roller 241 against the first orbital track 201 so that no gap is formed in the rail, the generation of vibration, abnormal noise, and the like can be suppressed.

Although the embodiment of the present invention has been described above, the article transporting device of the present invention is not limited to the embodiment, and can be implemented in various other embodiments as follows.
The orbit may be arranged so that the traveling body 220 circulates in the horizontal direction.
The mover of the linear motor in the traveling body 220 may be provided with an electromagnetic coil instead of the permanent magnet 231.
The article transport device is not limited to a conveyor that pushes the article P placed on the first transport bed 110 configured as a transport path by the pusher 236, and the article P is placed and transferred on the traveling body. It may be a conveyor or the like.
-As the urging means, it is preferable to use an elastic body made of a leaf spring, a coil spring, rubber or the like, but other methods such as using a magnetic force such as a magnet may be used.
-When a gap is created between the roller and the orbit due to wear of the rail as the orbit, the urging means may be configured to act only to fill the gap, or the traveling body. When either or both of the two rollers of 220 are located on the curved rail 214 (curved track), they may act only in a direction that reduces the pressing force of the rollers against the curved rail 214. It is preferable to act in both the former and the latter.
In the present embodiment, the attractive force generated between the coil 215 (stator) and the permanent magnet 231 (movable element) causes the first from the outer peripheral side of the first orbit 201 to the first orbit 201. The structure was such that the roller 241 presses, but the present invention is not limited to this.
The direction of the attractive force is opposite to that of the present embodiment, and the second roller 242 presses the inner circumference of the second orbital orbit 202 so that the distance between the coil 215 and the permanent magnet 231 is always set in advance. The configuration held in D, that is, the configuration in which the reference is provided on the inner circumference of the second orbital 202 may be used.
The direction of the attractive force is the same as that of the present embodiment, and the second roller 242 presses the outer circumference of the second orbital orbit 202 so that the distance D between the coil 215 and the permanent magnet 231 is always set to a preset distance D. A configuration for holding, that is, a configuration in which a reference is provided on the outer periphery of the second orbital 202 may be used.
The distance between the coil 215 and the permanent magnet 231 is always set in advance by the first roller 241 pressing the inner circumference of the first orbital track 201 with the direction of the attractive force opposite to that of the present embodiment. The configuration held in D, that is, the configuration in which the reference is provided on the inner circumference of the first orbital track 201 may be used.
By generating a repulsive force between the coil 215 and the permanent magnet 231, the inner circumference or the outer circumference of the first orbital orbital 201 and the second orbital orbital 202 may be used as a reference.
The coil 215 may be arranged on the outer peripheral side of the orbit from the arrangement position of the permanent magnet 231.
-A variety of modified examples can be configured by adopting one or more of the above configurations, and the same effects as those of the present embodiment are effective in any of the modified examples.
The direction in which the rotation axes of the first roller 241 and the second roller 242 extend is preferably orthogonal to the direction in which the coil 215 and the permanent magnet 231 face each other, and is orthogonal to the traveling direction. The coil 215 and the permanent magnet 231 may be inclined with respect to the opposite direction.
-In this embodiment, an example in which two second rollers 242 are arranged on the traveling body 220 is shown, but the number of the second rollers 242 may be one or the like.

110: 1st orbital bed (transportation path) 201: 1st orbital orbit 202: 2nd orbital orbit 203: 3rd orbital orbit 213: Straight rail (straight orbit) 214: Curved rail (curved orbit) )
215: Coil (stator) 220: Traveling body 224: Long groove (guide)
225: Sliding guide member (guidance part) 226: Spring (urging means)
231: Permanent magnet (movable element) 241: First roller (first rolling part)
242: 2nd roller (moving roller) (2nd rolling part) 243: 3rd roller P: Article

Claims (3)

Two linear orbits provided in parallel and an endless first orbit formed by two curved orbits connected to both ends of the two linear orbits.
A second orbit having a shape similar to that of the first orbit, which is arranged so as to face the inner orbit of the first orbit at a certain distance from the first orbit.
A stator provided along the orbit over the entire circumference of the orbit, and a stator.
A mover that is arranged so as to face the stator and generates an electromagnetic force by a magnetic field generated by the stator.
An article transporting device having the mover, provided with a plurality of traveling bodies capable of independently traveling along the orbit by the electromagnetic force, and transporting articles by the traveling of the traveling bodies. ,
The traveling body is
A first rolling portion that moves on the first orbit on either the inner or outer circumference of the first orbit, and
The inner peripheral side or the outer peripheral side of the second orbit so that the first rolling portion with respect to the first orbit has a relationship opposite to the relationship of being arranged on either the inner peripheral side or the outer peripheral side. On either side, it comprises a second rolling section that moves on the second orbit.
One of the first and second rolling portions includes two rollers arranged apart from each other in the front-rear direction along the traveling direction of the traveling body, and the two rollers are said by the electromagnetic force. The traveling body is supported so that the space between the stator and the mover is always a set distance while rolling while pressing one of the orbits.
The other of the first and the second rolling portions is a moving roller provided so as to be movable with respect to the traveling body so as to be able to come into contact with the other of the orbit, and the moving roller is of the orbit. It is equipped with an urging means configured to always abut on the other.
A third orbit that is the same size as one of the orbits and is parallel to one of the orbits is provided at a position separated in the depth direction that intersects with one of the orbits. In the traveling body, the mover is disposed between the third orbit and one of the orbits, and the third roller has the same diameter as each of the two rollers. An article transport device configured to regulate tilting of the traveling body in the depth direction by disposing a roller that rolls on an orbit . The linear track in the first orbital track is arranged along the transport path on which the article is placed, and the traveling body has the article placed on the transport path in the traveling direction. The article transport device according to claim 1, wherein a pusher capable of abutting and pushing backward is provided. The article transport device according to claim 1 or 2 , wherein the moving roller is supported by a guide portion that allows movement only in a direction in which the orbital loci in the first orbital orbit and the orbital locus in the second orbital orbit face each other. ..

Images