JP7050880B2 - Transport device - Google Patents

Description

The present invention relates to a transport device provided with a meandering prevention device for preventing meandering of the transport belt.

Conventionally, for example, the transfer device described in the following Patent Documents 1 and 2 is known.

This conventional conveyor is a belt conveyor in which a conveyor belt rotates to convey articles on the conveyor belt. In this conveyor, the influence of the difference in the circumference difference in the belt width direction caused by joining both ends of the belt-shaped conveyor belt to make it endless, and the conveyor in the installation situation where the conveyor is not installed horizontally. Due to the influence of twisting of the frame or the like, meandering may occur in which the rotating conveyor belt is offset to one of the belt width directions. Therefore, there is a transport device provided with a meandering prevention device for preventing such meandering of the transport belt.

The conventional meandering prevention device has a bend pulley in contact with the conveyor belt, and the bend pulley is rotatably provided around a rotation center axis orthogonal to the axial center of the bend pulley.

When the conveyor belt is not meandering, the contact resistance with the conveyor belt on both ends of the bend pulley is substantially equal, and the axial direction of the bend pulley is orthogonal to the rotational direction of the conveyor belt. Further, when the conveyor belt meanders so as to be offset to one side in the belt width direction, the contact resistance with the conveyor belt on one end side of the bend pulley becomes larger than the contact resistance with the conveyor belt on the other end side of the bend pulley, and the bend pulley The bend pulley rotates about the rotation center axis so that one end side of the belt advances in the traveling direction of the conveyor belt. The rotated bend pulley guides the conveyor belt toward the other side in the belt width direction to correct the meandering of the conveyor belt.

By the way, in the conventional meandering prevention device, as many as one bend pulley is used in the axial direction. In this case, since a wide range of the bend pulley in the axial direction is in contact with the conveyor belt on the surface, the rotation resistance of the bend pulley around the rotation center axis is large, and the bend pulley is difficult to rotate with respect to the conveyor belt. The meandering prevention effect of the conveyor belt may be insufficient. Further, although the bend pulley is divided into a plurality of pulley portions in the axial direction, when each pulley portion rotates integrally, the rotation speed of each pulley portion is the same, so that the conveyor belt partially rotates. The pulley part that rotates at a speed that does not correspond to the speed may come out, and the meandering adjustment may become unstable.

Japanese Patent No. 5879080 Jitsukaisho 60-145104

In the above-mentioned conventional transport device, the meandering prevention effect of the meandering prevention device may be insufficient.

An object of the present invention is to provide a transport device capable of effectively preventing meandering of a transport belt.

The transport device according to claim 1 has an endless transport belt for transporting articles, and a return of the transport belt around which the transport belt is wound and wraps around the transport surface region of the transport belt and below the transport surface region. A pair of end pulleys forming a region, a drive unit for rotating the conveyor belt, a pair of tapered pulleys rotatably arranged at both ends in the axial direction and reducing the diameter toward the outer end portion, and between these tapered pulleys . It has a plurality of bend pulleys which are divided into a plurality of parts in the axial direction and each of which is rotatably arranged independently of the end pulley, and the tapered pulley and the bend pulley are arranged below the end pulley. Depending on the pulley unit in contact with the return region and the meandering of the conveyor belt, one of the tapered pulleys moves in the rotation direction of the conveyor belt, and the other taper pulley moves in the direction opposite to the rotation direction of the conveyor belt. As described above, it is provided with a support unit that rotatably supports the pulley unit, and is provided with a meandering prevention device for preventing the meandering of the transport belt .

The transport device according to claim 2 has an endless transport belt for transporting articles, a transport surface region around which the transport belt is wound, and a return region of the transport belt that wraps around below the transport surface region. Between the pair of end pulleys forming the It has a plurality of bend pulleys that are divided into a plurality of parts in the axial direction and are arranged so as to be independently rotatable, and are respectively arranged below the pair of the end pulleys, and the taper pulley and the bend pulley are the conveyor belts. One of the tapered pulleys moves in the rotation direction of the conveyor belt, and the other taper pulley moves in the direction opposite to the rotation direction of the conveyor belt in response to the meandering of the pulley unit in contact with the return region and the conveyor belt. It is provided with a support unit that rotatably supports the pulley unit so as to move, and is provided with a meandering prevention device for preventing the meandering of the transport belt .

The transport device according to claim 3 is the transport device according to claim 1, wherein the meandering prevention device abuts on the support unit and rotates the pulley unit within a rotation range according to the contact position. It is provided with a rotation restricting unit that regulates and adjusts the contact position.

According to the present invention, meandering of the transport belt can be effectively prevented.

A transport device showing the first embodiment of the present invention is shown, (a) is a plan view, and (b) is a side view. Same as above It is a side view which shows the meandering prevention device of a transport device. Same as above It is an end view schematically showing the meandering prevention device of the transport device. Same as above It is a top view schematically showing the meandering prevention device of the transport device. Same as above It is a plan view of the meandering prevention device. Same as above The transport belt of the transport device rotates without meandering, (a) is a perspective view showing a meandering prevention device on the head side, and (b) is a perspective view showing a meandering prevention device on the tail side. Same as above The case where the transport belt of the transport device meanders and rotates to the left in the belt width direction when viewed from the first transport direction, (a) is a plan view of the transport device, and (b) is a perspective of the meander prevention device on the head side. Figure, (c) is a perspective view of the meandering prevention device on the tail side. Same as above The case where the transport belt of the transport device meanders and rotates to the right in the belt width direction when viewed from the first transport direction is shown. Figure, (c) is a perspective view of the meandering prevention device on the tail side. Same as above. It is an example of the installation state of the transport device, and is an end view schematically showing the meandering prevention device. It is an end view schematically showing the meandering prevention device of the transport device which shows the 2nd Embodiment of this invention. Same as above It is a perspective view of a part of the meandering prevention device.

Hereinafter, the first embodiment of the present invention will be described with reference to FIGS. 1 to 9.

In FIG. 1, the transport device 10 is a belt conveyor that carries an article on a transport surface 12 of a rotating (rotating) transport belt 11. Further, the transfer device 10 is a belt conveyor capable of rotating the transfer belt 11 in both the first transfer direction F1 which is the forward rotation direction and the second transfer direction F2 which is the reverse direction, for example.

The conveyor frame 10 is provided on a conveyor belt 11, a conveyor frame 13 that rotatably supports the conveyor belt 11, a pair of end units 14 arranged at both ends of the conveyor frame 13 in the longitudinal direction, and a lower portion of the conveyor frame 13. A pair of meandering prevention devices (aligning devices) 16 arranged at both ends of the arranged drive unit 15 and the conveyor frame 13 are provided.

The transport belt 11 is formed in an endless shape by connecting both ends of the strip-shaped flat belt. The region of the conveyor belt 11 forming the conveyor surface 12 on the upper surface side of the conveyor frame 13 is the conveyor belt region 11a, and the region of the conveyor belt 11 wrapping around to the lower side of the conveyor frame 13 is the return region 11b.

Further, the conveyor frame 13 includes a rectangular plate-shaped upper surface frame portion 20 having a longitudinal shape in the transport direction (F1 or F2), and side frame portions provided on both sides in the width direction orthogonal to the longitudinal direction of the upper surface frame portion 20. Has 21. A plurality of legs (not shown) for installing the transport device 10 on an installation surface such as a floor surface are attached to the lower portion of the conveyor frame 13. Further, the upper surface frame portion 20 and the side frame portion 21 may be separate members or integrated.

Further, as shown in FIGS. 1 to 4, the pair of end units 14 are arranged at both ends of the conveyor frame 13 in the longitudinal direction. Each of the pair of end units 14 can have a common structure.

Each end unit 14 comprises an end frame 25 attached to the longitudinal end of the conveyor frame 13 and an end pulley unit 26 supported by the end frame 25.

The end pulley unit 26 is divided into a plurality of pulley shafts 27 having both ends supported by the end frame 25 in the axial direction of the pulley shaft 27, and each of the pulley shafts 27 is provided to be independently rotatable. It has a plurality of end pulleys 28, and a spacer 29 arranged on the pulley shaft 27 between these end pulleys 28. For each end pulley 28, a bearing pulley or the like provided with a bearing that can freely rotate with respect to the pulley shaft 27 is used. The end pulley 28 (end pulley unit 26) is wound with the transport belt 11 to form a transport surface region 11a of the transport belt 11 and a return region 11b of the transport belt 11 that wraps around below the transport surface region 11a. ..

Further, as shown in FIG. 1, the drive unit 15 rotates the transport belt 11 in the first transport direction F1 or the second transport direction F2.

The drive unit 15 includes a lower frame 32 attached to the lower part of the conveyor frame 13, a drive pulley 33 rotatably supported by the lower frame 32, a plurality of guide pulleys 34, and a motor 35 for rotationally driving the drive pulley 33. I have. The return region 11b of the transport belt 11 is wound around the drive pulley 33 via a plurality of guide pulleys 34. Then, the transport belt 11 is rotated in the first transport direction F1 or the second transport direction F2 by, for example, forward rotation drive or reverse rotation drive of the motor 35. Instead of using the motor 35, a pulley with a built-in motor may be used for the drive pulley 33.

Further, as shown in FIGS. 1 to 5, the pair of meandering prevention devices 16 prevent the meandering of the transport belt 11 by correcting the meandering when the meandering of the conveyor belt 11 starts to occur. ..

The pair of meandering prevention devices 16 are provided in a common structure, and are arranged on both ends of the conveyor frame 13 under the end pulley unit 26, respectively.

Each meandering prevention device 16 includes a pulley unit (bend pulley unit) 40 and a support unit 41 that supports the pulley unit 40 with respect to the conveyor frame 13.

The pulley unit 40 rotates independently on the pulley shaft 44 between the pulley shaft 44, a pair of tapered pulleys 45 rotatably provided at both ends of the pulley shaft 44, and the pair of tapered pulleys 45. It has a plurality of bend pulleys 46 provided as possible, and a plurality of spacers 47 arranged on the pulley shaft 44 between the tapered pulley 45 and the bend pulley 46 and between the adjacent bend pulleys 46.

The pulley shaft 44 is supported by the support unit 41. The number of pulley shafts 44 is not limited to one that integrally supports the tapered pulleys 45 on both sides and a plurality of bend pulleys 46, one for each tapered pulley 45 and one for each of the plurality of bend pulleys 46, for a total of three. It may be divided into. In this case, each pulley may be arranged on the same center axis.

The outer diameter of each tapered pulley 45 on the inner end side of the taper pulley 45 is the same as the outer diameter of the bend pulley 46, and the outer diameter is reduced from the inner end side toward the outer end side. There is. For each tapered pulley 45, a bearing tapered pulley or the like provided with a bearing that can freely rotate with respect to the pulley shaft 44 is used.

Each bend pulley 46 is divided into a plurality of parts in the axial direction of the pulley shaft 44, and each is provided on the pulley shaft 44 so as to be independently rotatable. For each bend pulley 46, a bearing pulley or the like provided with a bearing that can freely rotate with respect to the pulley shaft 44 is used. Each bend pulley 46 has a cylindrical shape whose peripheral surface is parallel to the central axis (pulley shaft 44). The number of divisions of the bend pulley 46 may be any number as long as it is at least 2 or more. It is preferable that the bend pulleys 46 are provided at target positions having the same number on the left and right (axial direction) with the rotation center axis 50 as the center and the same distance from the rotation center axis 50. In this case, as in the present embodiment, the bend pulley 46 may not be arranged on the rotation center axis 50, and another bend pulley 46 may be arranged from a position separated from the rotation center axis 50 to the left and right. Alternatively, one central bend pulley 46 may be arranged on the rotation center axis 50, and other bend pulleys 46 may be arranged on the left and right sides of the central bend pulley 46.

Each spacer 47 is provided with a predetermined distance between the tapered pulley 45 and the bend pulley 46 and between adjacent bend pulleys 46.

Further, the length (width) between the outer ends of the tapered pulleys 45 at both ends of the pulley unit 40 is longer (wider) than the width of the conveyor belt 11, and even if the conveyor belt 11 meanders in the belt width direction, the tapered pulley 45 can be used. The length (width) is set in consideration of the meandering allowance so that the wound state is maintained. The outer diameters of the tapered pulley 45 and the bend pulley 46 can be larger than the outer diameter of the end pulley 28.

Further, the support unit 41 includes a support body 49 that supports the pulley unit 40, and a shaft support portion 51 that rotatably supports the support body 49 about the rotation center axis 50 orthogonal to the axial center portion of the pulley unit 40. It has an attachment 52 that attaches the support 49 to the conveyor frame 13 via the shaft support 51, and a counterweight 53 that is attached to the support 49.

The support 49 includes a horizontally long support plate 55, a pair of end plates 56 attached to both ends of the support plate 55 in the width direction, and a plurality of intermediate supports attached to the intermediate portion of the support plate 55 in the width direction. It has a part 57. The support plate 55 has a cross section orthogonal to the width direction formed into a substantially U-shaped cross section having an upper surface portion 58 and side surface portions 59 and 60 bent from both sides of the upper surface portion 58. The pair of end plates 56 support both ends of the pulley shaft 44 of the pulley unit 40 and regulate the axial position of the pulley unit 40. Each intermediate support portion 57 is interposed between adjacent bend pulleys 46 of the pulley unit 40, and supports the axial intermediate portion of the pulley shaft 44 of the pulley unit 40.

The shaft support 51 is arranged in the center in the width direction on the upper surface of the support 49. The shaft support 51 has a bearing 62, a bearing holder 63 that holds the bearing 62 and is attached to the upper surface of the support 49, and a shaft such as a screw that is fixed to the attachment 52 from the lower surface side of the support 49 through the bearing 62. It is equipped with a member 64. The bearing 62 is, for example, a ball bearing in which an outer ring and an inner ring are provided so as to be rotatable with each other via a plurality of balls. The outer ring is fixed to the support 49 by the bearing holder 63, and the inner ring is fixed to the mounting body 52 by the shaft member 64. The shaft support 51 rotatably supports the support 49 and the pulley unit 40 with respect to the mounting body 52 about the rotation center axis 50 passing through the center of the bearing 62 and the shaft member 64.

The mounting body 52 includes a connecting portion 66 to which the shaft support portion 51 is connected, and a mounting portion 67 that is bent diagonally with respect to the connecting portion 66. The mounting portion 67 is mounted on the lower surface of the conveyor frame 13 via the mounting member 68.

The pulley unit 40 supported by the support unit 41 having the mounting body 52 is located inside the transfer device 10 with respect to the end pulley unit 26 located below the end pulley unit 26 and at the longitudinal end of the transfer device 10. It is arranged in. The return region 11b of the conveyor belt 11 is wound around the taper pulley 45 and the bend pulley 46 of the pulley unit 40. Then, the pulley unit 40 applies tension from the inside of the conveyor belt 11 in the direction of increasing the winding angle of the conveyor belt 11 with respect to the end pulley unit 26. Further, the rotation center axis 50 of the support unit 41 is orthogonal to the axial direction (width direction) of the end pulley unit 26 and is inclined in the vertical direction. The inclination of the rotation center axis 50 is configured so that the upper side of the rotation center axis 50 is inclined toward the center side in the longitudinal direction of the transport device 10. In the present embodiment, the pulley unit 40 returns the return region 11b from the pulley unit 40 to the end pulley unit 26 and the return from the pulley unit 40 to the opposite side to the end pulley unit 26 (guide pulley 34 side of the drive unit 15). The return region 11b of the transport belt 11 is bent so that the angle formed with the region 11b is a predetermined angle α (for example, about 90 ° to 170 °). The rotation center axis 50 of the support unit 41 is inclined so as to coincide with the bisected angle α / 2 of the predetermined angle α.

The counterweight 53 is attached to the support 49 below the shaft support 51 (rotation center axis 50), and applies an even load to the support 49. In the present embodiment, the side surface portion 60 of the support 49 becomes substantially vertical due to the inclination of the rotation center axis 50, and the counterweight 53 is attached to the side surface portion 60. The counterweight 53 is an integral type, and the width dimension is shorter than the width dimension of the support 49, and the counterweight 53 is attached to the central portion in the width direction of the support 49. Then, a counterweight 53 that applies an even load to both sides of the support 49 in the width direction with the rotation center axis 50 sandwiched below the shaft support 51 causes a pulley together with the support 49 centering on the rotation center axis 50. The unit 40 acts to keep it horizontal. The counterweight 53 is not limited to one integrated type, but may be divided into two and attached to the left and right end portions of the support 49, respectively, and the shape can be appropriately changed.

Further, the meandering prevention device 16 includes a pair of rotation restricting units 71 for restricting the rotation range of the pulley unit 40 about the rotation center axis 50. Each rotation control unit 71 is screwed to a mounting bracket 72 having a substantially L-shaped cross section, a screw 73 screwed to the mounting bracket 72, and the screw 73, which are mounted to the conveyor frame 13 via a mounting member (not shown). A nut 74 for fixing the screw 73 to the mounting bracket 72 is provided.

The tips of the screws 73 of each rotation restricting unit 71 face the side surface portions 60 on both sides of the support 49 in the width direction (both sides of the counterweight 53). Then, the support 49 rotated about the rotation center axis 50 comes into contact with the tip end side of the screw 73, thereby restricting the rotation of the pulley unit 40 together with the support 49. By adjusting the amount of protrusion of the screw 73 from the mounting bracket 72 on the tip side, the rotation range of the pulley unit 40 can be arbitrarily adjusted.

Next, the operation and the like of the transport device 10 of the first embodiment will be described.

In FIG. 1, when the transport belt 11 rotates in the first transport direction F1, the transported object placed on the transport surface 12 of the transport belt 11 is transported in the first transport direction F1. In this case, the end portion of the transport device 10 in the first transport direction F1 is referred to as a head H, and the end portion of the transport device 10 opposite to the first transport direction F1 is referred to as a tail T.

6 (a) and 6 (b) show a case where the transport belt 11 rotates without meandering. FIG. 6A shows a perspective view of the meandering prevention device 16 on the head H side, and FIG. 6B shows a perspective view of the meandering prevention device 16 on the tail T side.

When the conveyor belt 11 is not meandering, the meandering prevention device 16 rotates with the conveyor belt 11 wound around the center of the pulley unit 40 in the axial direction, and is wound around the tapered pulleys 45 at both ends of the pulley unit 40. The amount (width) of the conveyor belt 11 becomes substantially equal, and the contact resistance with the conveyor belt 11 on both ends of the pulley unit 40 becomes substantially equal. Therefore, the pulley unit 40 rotates in a horizontal state parallel to the end pulley unit 26 to guide the conveyor belt 11.

Further, since the counterweight 53 is attached to the support 49 that supports the pulley unit 40, the action of the counterweight 53 urges the pulley unit 40 to maintain a horizontal state, and the rotation center axis 50. It is possible to suppress the wobbling of the pulley unit 40 that can rotate around the pulley unit 40 and stabilize the posture of the pulley unit 40.

Further, since the pulley unit 40 uses a plurality of bend pulleys 46 that are divided into a plurality of parts in the axial direction of the pulley shaft 44 and that can rotate independently of the pulley shaft 44, each bend pulley 46 is used. Each bend pulley 46 rotates independently according to the peripheral speed difference in the belt width direction of the conveyor belt 11 due to the contact with the conveyor belt 11 by a line. Therefore, even if there is a slight difference in the circumference of the transport belt 11 in the belt width direction, the difference in the peripheral speed of the transport belt 11 in the belt width direction due to the difference in the circumference can be absorbed by each bend pulley 46, and the transport belt 11 can be used. It is possible to suppress the occurrence of meandering.

Then, when the conveyor belt 11 meanders so as to be offset to any one of the belt width directions, the meandering prevention device 16 corrects the meandering of the conveyor belt 11 so that the conveyor belt 11 is returned to the center in the belt width direction.

The cause of the meandering of the conveyor belt 11 is the influence of the accuracy of the circumference difference in the belt width direction of the conveyor belt 11 and the influence of the installation defect of the conveyor belt 10. The conveyor belt 11 is formed in an endless shape by connecting both ends of a strip-shaped flat belt, but if the accuracy of this connection varies, a difference in peripheral length occurs in the belt width direction. When the conveyor belt 11 having a peripheral length difference in the belt width direction rotates, the peripheral length difference = the peripheral speed difference, and the peripheral speed difference occurs in the belt width direction, causing meandering in the conveyor belt 11. In addition, if the conveyor frame 13 is installed in a twisted state due to an installation failure such that the horizontal level of the conveyor frame 10 is not sufficiently secured, the end pulley unit 26 attached to the end of the conveyor frame 13 Since the conveyor belt 11 that is wound around the end pulley unit 26 and rotates is moved up or down according to the inclination of the end pulley unit 26, the conveyor belt 11 is meandered. ..

7 (a), (b), and (c) show a case where the transport belt 11 meanders and rotates to the left in the belt width direction when viewed from the first transport direction F1. 7A shows a plan view of the transport device 10, FIG. 7B shows a perspective view of the meandering prevention device 16 on the head H side, and FIG. 7C shows a perspective view of the meandering prevention device 16 on the tail T side. .. In the figure, the conveyor belt 11 is in a state where the position shown by the solid line is meandering, and the position shown by the two-dot chain line is not meandering. Further, the left side in the belt width direction when viewed from the first transport direction F1 where the transport belt 11 meanders is called the belt meander side, and the right side in the belt width direction opposite to the belt meander side is called the anti-belt meander side.

As shown in FIGS. 7A and 7B, when the transport belt 11 meanders to the left side in the belt width direction (belt meandering side) when viewed from the first transport direction F1 on the head H side of the transport device 10, the pulley unit 40 The amount (width) of the conveyor belt 11 wound around the taper pulley 45 on the meandering side of the belt increases, and the amount (width) of the conveyor belt 11 wrapped around the tapered pulley 45 on the meandering side of the anti-belt decreases. Further, the winding area of the conveyor belt 11 shifts to the smaller diameter side of the taper pulley 45 on the belt meandering side, the contact resistance between the taper pulley 45 and the conveyor belt 11 increases, and the conveyor belt 11 conveys to the larger diameter side of the taper pulley 45 on the anti-belt meandering side. The winding area of the belt 11 shifts, and the contact resistance between the taper pulley 45 and the conveyor belt 11 decreases.

Therefore, on the head H side of the transfer device 10, the force acting in the traveling direction of the return region 11b of the transfer belt 11 with respect to the end side of the belt meandering side of the pulley unit 40 is on the anti-belt meandering side of the pulley unit 40. It becomes larger than the force acting on the end side of the conveyor belt 11 in the traveling direction of the return region 11b of the conveyor belt 11, and acts on the end side of the belt meandering side and the end side of the anti-belt meandering side of this pulley unit 40. The pulley unit 40 rotates about the rotation center axis 50 due to the difference in the force applied. The direction in which the pulley unit 40 rotates is the direction in which the conveyor belt 11 is guided to the anti-belt meandering side opposite to the belt meandering side. The rotation of the pulley unit 40 is performed against the urging by the counterweight 53.

When the pulley unit 40 rotates about the rotation center axis 50, if there is only one bend pulley 46 in the axial direction, a wide range in the axial direction of the bend pulley 46 is the surface of the transport belt 11. Since they come into contact with each other, the rotation resistance of the bend pulley 46 centered on the rotation center axis 50 is large, and it is difficult for the pulley unit 40 to rotate with respect to the conveyor belt 11. Further, although the bend pulley 46 is divided into a plurality of pulleys in the axial direction, even when each pulley rotates integrally, the rotational resistance between each pulley and the conveyor belt 11 is large, and the pulley unit with respect to the conveyor belt 11 40 is hard to rotate. Moreover, since the rotation speeds of the pulleys are all the same, some pulleys may rotate at a speed that does not correspond to the rotation speed of the conveyor belt 11, and the meandering adjustment may become unstable.

Since the pulley unit 40 of the present embodiment uses a plurality of bend pulleys 46 that are divided into a plurality of parts in the axial direction of the pulley shaft 44 and that can rotate independently of the pulley shaft 44, each of them is used. The bend pulley 46 comes into contact with the conveyor belt 11 in a line, and each bend pulley 46 can rotate independently according to the difference in peripheral speed in the belt width direction of the conveyor belt 11, and the rotation center. The rotation resistance of the bend pulley 46 around the axis 50 is small, and the pulley unit 40 easily rotates with respect to the conveyor belt 11.

Therefore, when the meandering of the conveyor belt 11 occurs, the pulley unit 40 reliably rotates so as to guide the conveyor belt 11 to the anti-belt meandering side opposite to the belt meandering side on the head H side of the conveying device 10. do.

Further, when the pulley unit 40 rotates about the rotation center axis 50, the support 49 supporting the pulley unit 40 comes into contact with the screw 73 of the rotation restriction unit 71, and the pulley unit 40 is excessively rotated. Movement is regulated.

Then, as shown in FIGS. 7 (a) and 7 (b), the pulley unit 40 that has rotated about the rotation center axis 50 has the opposite reaction of the pulley unit 40 to the meandering side of the belt when viewed from the horizontal direction. The direction is to guide the conveyor belt 11 to the meandering side of the belt, and when viewed from the horizontal direction, the end side of the pulley unit 40 on the meandering side of the belt descends and the end side of the anti-belt meandering side rises. In this way, the pulley unit 40 is oriented to guide the conveyor belt 11 to the anti-belt serpentine side opposite to the belt serpentine side, so that the conveyor belt 11 has the anti-belt serpentine side opposite to the belt serpentine side. A force h1 acts toward the belt, and the end side of the belt meandering side of the pulley unit 40 descends and the end side of the anti-belt meandering side rises, so that the conveyor belt 11 opposes the belt meandering side. The force h2 toward the anti-belt meandering side of the belt acts. Due to these forces h1 and h2, the component of the force h3 in the belt width direction toward the anti-belt meandering side opposite to the belt meandering side acts on the conveyor belt 11 to correct the meandering of the conveyor belt 11.

On the other hand, as shown in FIGS. 7A and 7C, when the transport belt 11 meanders to the left side in the belt width direction (belt meandering side) when viewed from the first transport direction F1 on the tail T side of the transport device 10, the pulley The amount (width) of the conveyor belt 11 wound around the taper pulley 45 on the meandering side of the belt of the unit 40 increases, and the amount (width) of the conveyor belt 11 wrapped around the tapered pulley 45 on the meandering side of the anti-belt decreases. Further, the winding area of the conveyor belt 11 shifts to the smaller diameter side of the taper pulley 45 on the belt meandering side, the contact resistance between the taper pulley 45 and the conveyor belt 11 increases, and the conveyor belt 11 conveys to the larger diameter side of the taper pulley 45 on the anti-belt meandering side. The winding area of the belt 11 shifts, and the contact resistance between the taper pulley 45 and the conveyor belt 11 decreases.

Therefore, on the tail T side of the transfer device 10, the force acting in the traveling direction of the return region 11b of the transfer belt 11 with respect to the end side of the belt meandering side of the pulley unit 40 is on the anti-belt meandering side of the pulley unit 40. It becomes larger than the force acting on the end side of the conveyor belt 11 in the traveling direction of the return region 11b of the conveyor belt 11, and acts on the end side of the belt meandering side and the end side of the anti-belt meandering side of this pulley unit 40. The pulley unit 40 rotates about the rotation center axis 50 due to the difference in the force applied. The direction in which the pulley unit 40 rotates is the direction in which the conveyor belt 11 is guided to the anti-belt meandering side opposite to the belt meandering side. The rotation of the pulley unit 40 is performed against the urging by the counterweight 53.

Also at this time, since the pulley unit 40 uses a plurality of bend pulleys 46 that are divided into a plurality of parts in the axial direction of the pulley shaft 44 and that can rotate independently of the pulley shaft 44, each of them is used. The bend pulley 46 comes into contact with the conveyor belt 11 in a line, and each bend pulley 46 can rotate independently according to the difference in peripheral speed in the belt width direction of the conveyor belt 11, and the rotation center. The rotation resistance of the bend pulley 46 around the axis 50 is small, and the pulley unit 40 easily rotates with respect to the conveyor belt 11. Therefore, when the meandering of the conveyor belt 11 occurs, the pulley unit 40 reliably rotates so as to guide the conveyor belt 11 to the anti-belt meandering side opposite to the belt meandering side on the tail T side of the conveying device 10. do.

Further, when the pulley unit 40 rotates about the rotation center axis 50, the support 49 supporting the pulley unit 40 comes into contact with the screw 73 of the rotation restriction unit 71, and the pulley unit 40 is excessively rotated. Movement is regulated.

Then, as shown in FIGS. 7 (a) and 7 (c), the pulley unit 40 that has rotated about the rotation center axis 50 has the opposite reaction of the pulley unit 40 to the meandering side of the belt when viewed from the horizontal direction. The direction is to guide the transport belt 11 to the belt meandering side, and when viewed from the horizontal direction, the end side of the belt meandering side of the pulley unit 40 rises and the end side of the anti-belt meandering side falls. In this way, the pulley unit 40 is oriented to guide the conveyor belt 11 to the anti-belt serpentine side opposite to the belt serpentine side, so that the conveyor belt 11 has the anti-belt serpentine side opposite to the belt serpentine side. A force t1 acts toward the belt, and the end side of the belt meandering side of the pulley unit 40 rises and the end side of the anti-belt meandering side falls, so that the conveyor belt 11 opposes the belt meandering side. The force t2 toward the anti-belt meandering side of the belt acts. Due to these forces t1 and t2, the component of the force t3 in the belt width direction toward the anti-belt meandering side opposite to the belt meandering side acts on the conveyor belt 11 to correct the meandering of the conveyor belt 11.

Therefore, the meandering prevention device 16 on the head H side and the meandering prevention device 16 on the tail T side of the transfer device 10 correct the meandering of the transfer belt 11.

Since the end pulley unit 26 is also divided into a plurality of parts in the axial direction of the pulley shaft 27 and uses a plurality of end pulleys 28 that can rotate independently of the pulley shaft 27, the conveyor belt is also used. Each end pulley 28 can rotate independently according to the peripheral speed difference in the belt width direction of 11, and the meandering of the transport belt 11 can be easily corrected by the meandering prevention device 16.

Then, as the meandering of the transport belt 11 is corrected, the difference in the amount (width) of the transport belt 11 wound around the tapered pulleys 45 at both ends of the pulley unit 40 becomes smaller, that is, the transport on both ends of the pulley unit 40 becomes smaller. Since the difference in contact resistance with the belt 11 becomes small, the pulley unit 40 rotates about the rotation center axis 50 so as to return to the position before the belt meandering.

If the meandering of the conveyor belt 11 is corrected, the amount (width) of the conveyor belt 11 wound around the tapered pulleys 45 at both ends of the pulley unit 40 becomes substantially equal, and the contact resistance with the conveyor belt 11 on both ends of the pulley unit 40 becomes substantially equal. Is almost even. Therefore, the pulley unit 40 rotates in a horizontal state parallel to the end pulley unit 26 to guide the conveyor belt 11.

Further, FIGS. 8A, 8B, and 8C show a case where the transport belt 11 meanders and rotates to the right in the belt width direction when viewed from the first transport direction F1. 8A shows a plan view of the transport device 10, FIG. 8B shows a perspective view of the meandering prevention device 16 on the head H side, and FIG. 8C shows a perspective view of the meandering prevention device 16 on the tail T side. .. In the figure, the conveyor belt 11 is in a state where the position shown by the solid line is meandering, and the position shown by the two-dot chain line is not meandering. Further, the right side in the belt width direction is the belt meandering side when viewed from the first transport direction F1 where the transport belt 11 meanders, and the left side in the belt width direction opposite to the belt meandering side is the anti-belt meandering side.

Also in this case, the meandering prevention device 16 on the head H side of the transporting device 10 is similar to the case where the transporting belt 11 shown in FIG. 7 meanders and rotates to the left in the belt width direction when viewed from the first transporting direction F1. And the meandering prevention device 16 on the tail T side guides the transport belt 11 to the anti-belt meandering side opposite to the belt meandering side, and corrects the meandering of the conveyor belt 11.

As shown in FIG. 8 (b), the rotation direction of the pulley unit 40 on the head H side with respect to the meandering of the transport belt 11 about the rotation center axis 50 is the transport shown in FIG. 7 (b) described above. The direction is opposite to the case where the belt 11 meanders and rotates to the left in the belt width direction when viewed from the first transport direction F1. Similarly, as shown in FIG. 8 (c), the rotation direction of the pulley unit 40 on the tail T side with respect to the meandering of the transport belt 11 about the rotation center axis 50 is shown in FIG. 7 (c) described above. The direction is opposite to the case where the transport belt 11 meanders and rotates to the left in the belt width direction when viewed from the first transport direction F1.

Further, when the transport belt 11 is rotated in the second transport direction F2, the transported object placed on the transport surface 12 of the transport belt 11 is transported in the second transport direction F2. In this case, the end portion of the transport device 10 in the second transport direction F2 is the head H, and the end portion of the transport device 10 opposite to the second transport direction F2 is the tail T.

In this case, the transport belt 11 shown in FIGS. 7 and 8 described above is the first in the rotation direction of the pulley unit 40 on the head H side and the tail T side with respect to the meandering of the transport belt 11 about the rotation center axis 50. The direction is opposite to that when rotating in the transport direction F1.

Then, even when the transport belt 11 rotates in the second transport direction F2, the meandering prevention device 16 on the head H side and the tail T side guides the transport belt 11 to the anti-belt meandering side opposite to the belt meandering side. Then, correct the meandering of the transport belt 11.

Further, FIG. 9 shows an example of the state in which the transport device 10 is installed. This example shows a state in which the conveyor frame 13 is twisted when the conveyor frame 10 is installed without ensuring a horizontal state with respect to, for example, an uneven installation surface or an inclined installation surface. When the conveyor frame 13 is twisted, it is tilted with respect to the horizontal plane at a twist angle θ in the belt width direction of the transport surface 12.

At the end of the conveyor frame 10 shown in FIG. 9, the height on the right side of the conveyor frame 13 is high and the height on the left side is low. Along with this, the height of the end pulley unit 26 on the right end side is high, the height on the left end side is low, and the end pulley unit 26 is tilted upward (downward to the left) with respect to the horizontal plane at a twist angle θ.

When the end of the transfer device 10 shown in FIG. 9 is on the head H side, when the transfer belt 11 rotates, the transfer belt 11 tends to meander so as to move to the higher side without the meandering prevention device 16.

When the end of the transfer device 10 shown in FIG. 9 is on the tail T side, when the transfer belt 11 rotates, the transfer belt 11 tends to meander so as to move to the lower side without the meandering prevention device 16.

Since the meandering prevention device 16 has the counterweight 53 attached to the support 49 that supports the pulley unit 40, the counterweight 53 acts even when the conveyor frame 13 is twisted and the end pulley unit 26 is tilted. The pulley unit 40 is urged to stay horizontal. That is, due to the action of the counterweight 53, the pulley unit 40 rotates about the rotation center axis 50 so as to maintain a horizontal state.

When the end of the transport device 10 shown in FIG. 9 is on the head H side, the meandering prevention device 16 is in the same state as the meandering prevention device 16 on the head H side shown in FIGS. 7A and 7B. The conveyor unit 11 guides the transport belt 11 to meander to the higher side of the end pulley unit 26 to the anti-belt meandering side opposite to the belt meandering side, and prevents the conveyor belt 11 from meandering.

Further, when the end of the transport device 10 shown in FIG. 9 is on the tail T side, the meandering prevention device 16 is in the same state as the meandering prevention device 16 on the tail T side shown in FIGS. 7 (a) and 7 (c). The conveyor unit 11 guides the transport belt 11 to meander to the lower side of the end pulley unit 26 to the anti-belt meandering side opposite to the belt meandering side, and prevents the conveyor belt 11 from meandering.

Further, since the pulley unit 40 is urged to maintain a horizontal state by the action of the counterweight 53, the pulley unit 40 that can rotate around the rotation center axis 50 is suppressed from swaying, and the pulley unit is suppressed. It can stabilize 40 postures.

According to the transport device 10 of the present embodiment, the pulley unit 40 of the meandering prevention device 16 is divided into a plurality of parts in the axial direction of the pulley shaft 44, and each of them rotates independently of the pulley shaft 44. Since each bend pulley 46 has a plurality of bend pulleys 46 that can be enabled, each bend pulley 46 comes into contact with the conveyor belt 11 in a line, and each bend pulley 46 has a peripheral speed difference in the belt width direction of the conveyor belt 11. The pulley unit 40 can rotate independently, the rotation resistance of the bend pulley 46 around the rotation center axis 50 is small, and the conveyor belt 11 is guided to the opposite side to the meandering side of the belt. Is easy to rotate, and the meandering of the transport belt 11 can be effectively prevented.

Further, the meandering prevention device 16 is arranged below the end pulley 28 (end pulley unit 26), the taper pulley 45 and the bend pulley 46 of the pulley unit 40 are in contact with the return region 11b of the conveyor belt 11, and the rotation center axis 50 is the end pulley. Since the 28 (end pulley unit 26) is orthogonal to the width direction and is inclined in the vertical direction, the pulley unit 40 moves in the traveling direction of the return region 11b of the transport belt 11 according to the meandering of the transport belt 11. The pulley unit 40 rotates in two directions in the vertical direction, and the effect of guiding the transport belt 11 to the anti-belt meandering side opposite to the belt meandering side can be improved.

Moreover, the pulley unit 40 has a predetermined angle α between the return region 11b of the conveyor belt 11 and the return region 11b on the end pulley 28 side from the pulley unit 40 and the return region 11b on the opposite side of the pulley unit 40 to the end pulley 28. Since the rotation center axis 50 of the pulley unit 40 is inclined to an angle halved by a predetermined angle α, the pulley unit 40 rotates according to the meandering of the conveyor belt 11. When doing so, the rotation of the return region 11b of the transport belt 11 in the two directions of the traveling direction and the vertical direction is well-balanced, and the effect of guiding the transport belt 11 to the anti-belt meandering side opposite to the belt meandering side is further improved. Can be improved.

Further, when the taper pulley 45 and the bend pulley 46 of the pulley unit 40 have a larger diameter than the end pulley 28, the effect of guiding the transport belt 11 to the anti-belt meandering side opposite to the belt meandering side by the pulley unit 40 is improved. Can be done. In this case, since the end pulley 28 has a smaller diameter than the taper pulley 45 and the bend pulley 46 of the pulley unit 40, it is possible to arrange the transport device 10 continuously with, for example, another transport device in close proximity to the transport device 10 and others. The gap between the transport device and the transport device can be reduced, and the transport can be smoothly transferred.

Further, since the meandering prevention device 16 is arranged below the pair of end pulleys 28 (end pulley unit 26) of the transport device 10, the transport belt 11 rotates forward and reverse (first and second transport directions F1). , F2) can be used to prevent meandering.

Further, the support unit 41 is attached to the support 49 below the shaft support 51, and has a counterweight 53 that applies an even load to both sides of the support 49 in the width direction centering on the shaft support 51. Therefore, even when the conveyor frame 13 is twisted, the action of the counterweight 53 urges the pulley unit 40 to maintain a horizontal state, and the meandering of the conveyor belt 11 can be prevented. Moreover, since the pulley unit 40 is urged to maintain a horizontal state by the action of the counterweight 53, the pulley unit 40 that can rotate around the rotation center axis 50 is suppressed from swaying, and the pulley unit is suppressed. It can stabilize 40 postures.

Next, FIGS. 10 and 11 show a second embodiment.

The configuration of the rotation control unit 71 is different from that of the first embodiment. The rotation control unit 71 has a pair of pins 80 protruding from a uniform position from the center in the width direction (rotation center axis 50) on the upper surface of the support 49.

Then, when the support 49 rotates about the rotation center axis 50 together with the pulley unit 40, the pin 80 in the rotation direction comes into contact with the mounting body 52, and the rotation range of the pulley unit 40 is restricted. ..

A recess 81 into which the pin 80 enters may be provided at the position of the mounting body 52 with which the pin 80 abuts, that is, at the edge of the connecting portion 66. By adjusting the depth (diameter) of the recess 81, the rotation range of the pulley unit 40 can be adjusted.

In the case of the transport device 10 that allows the transport belt 11 to rotate in the forward and reverse directions as in the present embodiment, two meandering prevention devices 16 are used, and these two meandering prevention devices 16 are placed on both ends of the transport device 10. However, it is sufficient that one meandering prevention device 16 is arranged on at least one end side of the conveying device 10, or one meandering at a position corresponding to the return region 11b of the conveying belt 11. It suffices if the prevention device 16 is provided.

Further, the meandering prevention device 16 can also be applied to the transport device 10 in which the transport belt 11 rotates in only one direction. In this case, the meandering prevention device 16 may be arranged on both ends of the transport device 10, or the meandering prevention device 16 may be arranged only on one end side of the transport device 10. When the meandering prevention device 16 is arranged only on one end side of the transport device 10, the meandering prevention device 16 is arranged on the tail T side of the transport device 10 to meander in the transport surface region 11a of the transport belt 11. Can be reduced.

10 Conveyor
11 Conveyance belt
11a Transport surface area
11b Return area
15 Drive unit that is the drive unit
16 Meander prevention device
28 End pulley
40 pulley unit
41 Support unit
45 Tapered pulley
46 Bend pulley
71 Rotation control unit

Claims (3)

An endless transport belt that transports goods,
A pair of end pulleys around which the transport belt is wound to form a transport surface region of the transport belt and a return region of the transport belt that wraps around below the transport surface region.
The drive unit that rotates the conveyor belt and
A pair of tapered pulleys that are rotatably arranged at both ends in the axial direction and reduce the diameter toward the outer end side, and a plurality of tapered pulleys are divided in the axial direction and each can rotate independently. A pulley unit having a plurality of arranged bend pulleys, which are arranged below the end pulley and in which the tapered pulley and the bend pulley come into contact with the return region of the conveyor belt, and one of them according to the meandering of the conveyor belt. The tapered pulley is provided with a support unit that rotatably supports the pulley unit so that the tapered pulley moves in the rotational direction of the conveyor belt and the other tapered pulley moves in the direction opposite to the rotational direction of the conveyor belt. With a meandering prevention device that prevents the meandering of the conveyor belt
A transport device characterized by being provided with. An endless transport belt that transports goods,
A pair of end pulleys around which the transport belt is wound to form a transport surface region of the transport belt and a return region of the transport belt that wraps around below the transport surface region.
The drive unit that rotates the conveyor belt and
A pair of tapered pulleys that are rotatably arranged at both ends in the axial direction and reduce the diameter toward the outer end side, and a plurality of tapered pulleys are divided in the axial direction and each can rotate independently. It has a plurality of arranged bend pulleys, each of which is arranged below the pair of end pulleys, and corresponds to a pulley unit in which the tapered pulley and the bend pulley come into contact with the return region of the conveyor belt, and the meandering of the conveyor belt. A support unit that rotatably supports the pulley unit so that one of the tapered pulleys moves in the rotational direction of the conveyor belt and the other tapered pulley moves in the direction opposite to the rotational direction of the conveyor belt. With a meandering prevention device that prevents the meandering of the transport belt
A transport device characterized by being provided with. The meandering prevention device includes a rotation restricting unit that comes into contact with the support unit and regulates the rotation of the pulley unit within a rotation range according to the contact position, and the contact position can be adjusted.
The transport device according to claim 1 or 2, wherein the transfer device is characterized by the above.

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