JP2009035400A - Conveyer equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide conveyor equipment always capable of smoothly transmitting driving force to a roller group by providing a transmitting rotating body opposite to the only roller group in a curved route part in regard to conveyor equipment arranged with a common endless belt over from straight route parts to curved route parts. <P>SOLUTION: This conveyor equipment 1 is formed with a conveyance route 2 having straight route parts 3X and 3Y and curved route parts 4X and 4Y by arranging rollers 26X and 26Y in a conveyor frame freely to idle. A driving means 30 for the roller group is structured by arranging a common endless belt 31 in each of the route parts along the conveying direction, and providing a driving section 41 for the endless belt. The endless belt is structured freely to abut on the roller group from the lower side, arranging the belt thickness direction in the vertical direction in the straight route parts, and structured freely to abut on a rotation receiving part of a group of transmitting rotating bodies 71 provided opposite to the roller group, arranging the belt cross direction in the vertical direction in the curved route parts. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a conveyor facility in which a roller group is rotatably arranged on a conveyor frame to form a conveyance path having a linear path portion and a curved path portion.

  Conventionally, the following configuration is provided as this type. That is, with respect to the frame, a tapered roller is provided in the curved portion, and a straight roller is provided in the straight portion. All these rollers are provided with V-belt pulleys facing from below, and these V-belt pulleys are provided with transmission pulleys that contact the rollers from below. A V belt for rotating the V belt pulley group is provided.

According to this conventional configuration, the V belt pulley group can be driven and rotated by driving the V belt by the drive unit, and the roller group can be driven and rotated via the transmission pulley that rotates integrally (for example, see Patent Document 1).
JP-A-3-143810 (page 3-4, FIGS. 1 to 3) Japanese Unexamined Patent Publication No. 63-230411 French published patent publication 2.108.878 Microfilm of Japanese Utility Model No. 59-91938 (Japanese Utility Model Application No. 61-8611)

  However, according to the above-described conventional configuration, the V belt pulley is provided facing all the rollers from below, so that the structure is complicated and the whole is expensive. Especially for a straight roller, the structure becomes more complicated by inclining the pulley shaft of the V-belt pulley.

  Accordingly, the invention according to claim 1 of the present invention is a conveyor in which a common endless flat belt is disposed over the linear path portion and the curved path portion, but the structure can be simplified and the whole can be made inexpensive. The purpose is to provide equipment.

  In order to achieve the above-mentioned object, the conveyor equipment according to claim 1 of the present invention has a linear path portion and a curved path portion by disposing a group of rollers freely on the conveyor frame. Conveyor equipment in which a path is formed, and the driving means of the roller group is configured by disposing a common endless flat belt in each path part along the transport path and providing a driving unit for the endless flat belt. The endless flat belt is configured to freely contact the roller group from the lower side with the belt thickness direction being the vertical direction in the linear path portion, and to the roller group with the belt width direction being the vertical direction in the curved path portion. It is configured to be able to come into contact with a rotation passive part of a group of transmission rotors provided facing each other, and the rotation drive part of these transmission rotors is configured to be able to contact an opposing roller. so That.

  Therefore, according to the first aspect of the present invention, in the conveying path, the conveying force can be obtained by rotating the common endless flat belt by driving the driving unit in the driving means. That is, in the linear path portion, the roller group can be driven by bringing the endless flat belt whose belt thickness direction is the vertical direction into contact with the roller group from below. In the curved path section, the transmission rotating body group is driven to rotate by an endless flat belt whose belt width direction is the vertical direction, and the rotation passive section of the transmission rotating body is brought into contact with the roller to drive the roller group. Can do.

  According to a second aspect of the present invention, there is provided the conveyor apparatus according to the first aspect, wherein the transmission rotating body is arranged to face the roller from below, and has a vertical axis on the conveyor frame side. A rotationally passive portion is formed by a laterally circumferential surface centered on the longitudinal axis thereof, and a ring-shaped rotational drive portion centered on the longitudinal axis is provided on the upward surface. The portion of the rotational drive unit that has reached a predetermined location is configured to be able to abut against the opposed roller from below, and is provided with an urging means for urging and abutting. .

  Therefore, according to the second aspect of the present invention, the transmission rotating body group is driven and rotated around the longitudinal axis by the endless flat belt, and the rotation driving unit is rotated integrally with the transmission rotating body. At this time, the portion of the rotational drive unit that reaches a predetermined location is in contact with the opposed roller from below, so that these roller groups can be driven to rotate, and the curved path portion can be brought into a drive conveyance state. At that time, the urging means urges the transmission rotor side upward so that the roller can be abutted from below with respect to the rotation drive unit with a constant abutment force (abutment pressure).

  In the conveyor apparatus according to claim 3 of the present invention, in the configuration according to claim 1 or 2, the curved path portion has a small diameter on the small-diameter side in the curve and a diameter on the large-diameter side in the curve. A large conical roller group is arranged, and the rotational drive part of the transmission rotating body is configured to be able to contact a portion where the diameter of the conical roller group is small.

  Therefore, according to the third aspect of the present invention, in the curved path portion, the rotational driving portion of the transmission rotating body is placed below the portion where the diameter of the conical roller group is small, that is, the same diameter as the diameter of the straight roller. The two roller portions can be rotated while adjusting the direction of the object to be conveyed in the curved path portion due to the change in the peripheral speed of the conical roller group. In this case, the objects to be conveyed can be continuously conveyed at the same conveyance speed.

  Furthermore, in the conveyor equipment according to claim 4 of the present invention, in the configuration according to claim 1 or 2, the curved path portion has a small diameter on the small diameter side in the curve and a diameter on the large diameter side in the curve. When a large conical roller group is arranged and the conveyance path has two types of curved path sections with different curve directions on the left and right, the endless flat belt moves in the conveyor width direction between these curved path sections. In any of the two types of curved path portions, the rotation driving portion of the transmission rotating body is configured to be able to contact the small diameter portion of the conical roller group. It is.

  Therefore, according to the invention of claim 4, by incorporating the conveyor width direction moving part, the rotation drive part of the transmission rotating body is provided in the part where the diameter of the conical roller group is small in any of the two kinds of curved path parts. The conical rollers can be rotated at the same rotation speed by contacting them from below, so that both curvilinear shapes are adjusted while adjusting the direction of the object to be conveyed in both curvilinear path portions by the change in the peripheral speed of the conical roller group. In the path portion or the like, the objects to be conveyed can be continuously conveyed at the same conveyance speed.

  According to the first aspect of the present invention described above, in the conveying path, the driving unit in the driving means can be driven to rotate the common endless flat belt to obtain the conveying force. That is, in the linear path portion, the endless flat belt whose belt thickness direction is the vertical direction is brought into contact with the roller group from below, so that the roller group can be driven and the driving force transmitted by the endless flat belt is always transmitted. Thus, the roller group can be driven and rotated at a predetermined rotational speed. In the curved path section, the transmission rotating body group is driven to rotate by an endless flat belt whose belt width direction is the vertical direction, and the rotation passive section of the transmission rotating body is brought into contact with the roller to drive the roller group. Thus, the transmission of the driving force by the endless flat belt can always be stably performed via the transmission rotating body that bends and deforms without difficulty, and the roller group can be driven and rotated at a predetermined rotational speed.

  According to such a conveyor facility, a transmission rotating body is provided only facing the roller group of the curved path portion, while a common endless flat belt is disposed across the linear path portion and the curved path portion. By providing the structure, the structure can be simplified and the whole can be made inexpensive, and the driving force can be transmitted smoothly to the roller group at all times.

  According to the second aspect of the present invention, the transmission rotating body group can be driven and rotated around the longitudinal axis by the endless flat belt, and the rotation driving unit can be rotated integrally with the transmission rotating body. At this time, the portion of the rotational drive unit that has reached a predetermined location is in contact with the opposing roller from below, so that these roller groups can be driven to rotate, and the curved path portion can be brought into a drive conveyance state. At that time, by urging and energizing the transmission rotator side by the urging means, it is possible to perform the abutting from the lower side with respect to the rotation driving unit to the roller with a constant abutting force (abutting pressure), As a result, the rotation of the roller group can always be carried out suitably and stably.

  According to the third aspect of the present invention described above, in the curved path portion, the rotational driving of the transmission rotating body is performed in a portion where the diameter of the conical roller group is small, that is, a portion having the same diameter as that of the straight roller. The roller group can be rotated at the same rotation speed by contacting the part from below, and both of them can be adjusted while adjusting the direction of the conveyed object in the curved path part due to the change in the peripheral speed of the conical roller group. In the path portion, the object to be transported can be continuously transported at the same transport speed.

  Further, according to the fourth aspect of the present invention described above, the rotation of the transmission rotating body is rotated to a portion where the diameter of the conical roller group is small in either of the two curved path portions by incorporating the conveyor width direction moving portion. The conical roller can be rotated at the same rotation speed by bringing the drive unit into contact with the lower side, so that both the curvilinear path portions adjust the direction of the object to be conveyed by changing the peripheral speed of the conical roller group. In a curved path portion or the like, the object to be transported can be continuously transported at the same transport speed.

[Embodiment 1]
In the following, the first embodiment of the present invention is used for transporting an object to be transported that has been transported on, for example, a linear path portion, on a linear path portion after being subsequently transported on a curved path portion. The state adopted for the conveyor equipment will be described with reference to the drawings.

  1 to 3, a conveyor facility 1 for transporting a case-like container (an example of an object to be transported) A is a drive roller type, and as an example, a linear conveyor device and a direction in which the curve direction is different on the left and right. The structure which consists of these 2 types of curved conveyor apparatuses is provided. That is, the conveyance path 2 of the conveyor facility 1 includes an upper linear path portion 3X formed by the upper linear conveyor device 11X, and a left curved path portion 4X formed in an arc shape by the left curved conveyor device 21X. The right curved path portion 4Y formed in an arc shape by the right curved conveyor device 21Y and the lower straight path portion 3Y formed by the lower straight conveyor device 11Y are configured in this state. Yes.

  1 to 6, 8, and 9, the frame main body 12 of both linear conveyor devices 11 </ b> X and 11 </ b> Y is provided between a pair of left and right linear conveyor frames 13 and a lower portion of both linear conveyor frames 13. The connecting frame 14 and the leg 15 connected to the lower part of the linear conveyor frame 13 are configured. Between the two linear conveyor frames 13, straight rollers 16X and 16Y are rotatably arranged at a plurality of locations (a number of locations) in the length direction (the direction of the linear path portions 3X and 3Y). Yes. That is, the straight rollers 16X and 16Y are arranged in the hexagonal holes (or notches) formed in the linear conveyor frame 13 so that the hexagonal shaft portions of the roller shafts 17X and 17Y are positioned. 13 is supported so as to be freely rotatable. As a result, linear path portions 3X and 3Y are formed above the straight rollers 16X and 16Y.

  1 to 3, 7, and 10, the frame main body 22 of both curved conveyor devices 21 </ b> X and 21 </ b> Y is a semicircular shape between a pair of left and right arc conveyor frames 23 and the lower part of both arc conveyor frames 23. And a leg 25 connected to the lower part of the arc-shaped conveyor frame 23. Between the two arcuate conveyor frames 23, conical rollers 26X and 26Y are disposed so as to be freely rotatable at a plurality of locations (a number of locations) in the length direction (the direction of the curved path portions 4X and 4Y). Yes. That is, in the left curved conveyor device 21X and the right curved conveyor device 21Y, the conical rollers 26X and 26Y having a small diameter on the small diameter side and a large diameter on the large diameter side of the curve are formed in the arc shape. Since the hexagonal shaft portions of the roller shafts 27X and 27Y are positioned in the hexagonal holes (or notches) formed in the conveyor frame 23, the roller shafts 27 are supported so as to be freely rotatable. At that time, each of the conical rollers 26X and 26Y is arranged with the direction of the axis of the roller directed toward the center of the arc. As a result, the curved path portions 4X and 4Y are formed above the conical rollers 26X and 26Y.

  1 to 3, 6, and 10, the driving means 30 of the rollers 16 </ b> X, 16 </ b> Y, 26 </ b> X, and 26 </ b> Y groups is an endless flat common to the path portions 3 </ b> X, 3 </ b> Y, 4 </ b> X, and 4 </ b> Y along the transport path 2. A belt 31 is provided and a drive unit 41 for the endless flat belt 31 is provided. At that time, the endless flat belt 31 is moved from the forward portion (action path portion) 32A to the return portion (return path portion) by guidance of guide means (described later) provided at a plurality of locations along the transport path 2. ) It is rotated to 32B.

  That is, the endless flat belt 31 is configured so as to be able to abut on the straight rollers 16X and 16Y from below in the linear path portions 3X and 3Y of the forward portion 32A with the belt thickness direction 31T as the vertical direction and from the lower side. The belt-shaped path portions 4X and 4Y are configured so as to be capable of abutting against a rotation passive portion of a group of transmission rotating bodies (described later) provided to face the conical rollers 26X and 26Y with the belt width direction 31W as the vertical direction. In addition, the rotational drive unit of these transmission rotators is configured to be able to contact the conical rollers 26X and 26Y facing each other. In the retrograde section 32B, the belt width direction 31W is moved in the vertical direction.

  The drive unit 41 is configured as follows. That is, in FIGS. 1 to 3 and FIG. 6, at both ends in the direction of the conveyance path 2 below the straight rollers 16X and 16Y (at the start end of the upper straight path portion 3X and the end of the lower straight path portion 3Y). Each of the reversal ring bodies 42 is disposed so as to be freely rotatable via a horizontal shaft body 43 supported on the connecting frame 14 side. A box-shaped drive unit frame 44 is provided between the lower portions of the two linear conveyor frames 13 in the upper linear conveyor device 11X, and a motor 45 with a speed reducer is mounted on the drive unit frame 44. A driving wheel 47 is provided on the output shaft 46 in the horizontal direction (conveyor width direction). Further, a pair of reverse guide ring bodies 48 are provided near the motor 45, and a tension guide ring body 49 whose position is adjustable is provided. An example of the drive unit 41 is configured by the above 42 to 49 and the like.

  In FIGS. 1 and 3 to 10, the guide means includes a forward portion side guide means 51 and a backward portion side guide means 61. Among them, the outward guide unit 51 includes a receiving guide portion 52 provided from the start end portion to the intermediate portion of the upper straight path portion 3X and from the intermediate portion to the end portion of the lower straight path portion 3Y. The end portion of the upper straight path portion 3X and the bending guide portion 56 provided at the start end portion of the lower straight path portion 3Y.

  The receiving guide portion 52 includes a rail-like roller support 53 provided on the connecting frame 14 side along the straight path portions 3X and 3Y, and a horizontal shaft 54 at a plurality of positions in the length direction of the roller support 53. And a receiving roller 55 provided so as to be free to rotate through. The receiving roller 55 group is positioned below the adjacent linear rollers 16X and 16Y, and receives the endless flat belt 31 from below and pushes it up (push-up guide), whereby the linear path portion 3X, In 3Y, the endless flat belt 31 with the belt thickness direction 31T in the vertical direction is configured to abut on the straight rollers 16X and 16Y from below. The reversing ring body 42 is provided on a roller support 53.

  The bending guide portion 56 is positioned at the frame assembly 57 provided on the linear conveyor frame 13 side, the terminal end portion of the upper straight path portion 3X, and the start end portion of the lower straight path portion 3Y, and the horizontal pin 58a is attached. Through the reversing roller 58 provided on the side of the frame assembly 57 so as to be freely rotatable, and the frame assembly 57 via an inclined vertical pin 59a which is positioned near the intermediate portion between the upper straight path portion 3X and the lower straight path portion 3Y. A pair of tilt reversal rollers 59 provided so as to be freely rotatable on the side, and a pair (not shown) that are positioned between the reversing roller 58 and the tilt reversal rollers 59 and that are freely rotatable on the frame assembly 57 side via the lateral pins 60a. (Single or plural) presser rollers 60.

  Therefore, the endless flat belt 31 that has reached the terminal end of the upper straight path portion 3X with the belt thickness direction 31T in the vertical direction is reversely guided by the reverse roller 58, then pressed by the presser roller 60 group, and then tilted and reversed. The belt 59 is reversely guided by the roller 59 and sent to the left curved path portion 4X so that the belt width direction 31W becomes the vertical direction. Further, the endless flat belt 31 that has reached the starting end portion of the lower straight path portion 3Y from the right curve path portion 4Y with the belt width direction 31W as the upper and lower direction is moved in the belt thickness direction 31T by the inclined inversion roller 59. After being reversely guided in this manner, after being guided by the presser roller 60 group and reversely guided by the reverse roller 58, the belt is fed to the start end portion of the lower linear path portion 3Y with the belt thickness direction 31T as the vertical direction. An example of the forward section side guide means 51 is configured by the above 52-60 and the like.

  The return part side guide means 61 is a belt width direction 31W, which is an endless flat belt 31 whose belt thickness direction 31T has been reversed by the guidance of the reversing wheel 42 from the end of the lower straight path portion 3Y. The endless flat belt 31 whose belt width direction 31W is the vertical direction is guided to the reversing guide wheel 48 of the drive unit 41 with the belt thickness direction 31T being the vertical direction. A guide ring 63 is provided on the connecting frames 14 and 24 via a vertical pin 62 so as to be freely rotatable. The proper position of the retrograde portion 31B of the endless flat belt 31 is guided by a tension-type tension adjusting portion 64. An example of the return part side guide means 61 is configured by the above 62-64 and the like.

  The transmission rotating body 71 is disposed to face the conical rollers 26X and 26Y from below, and is provided on the arcuate conveyor frame 23 side so as to be freely rotatable around the vertical axis 74A. . That is, a bracket 72 that protrudes inward is provided on a lower portion of the inner side surface of the arc-shaped conveyor frame 23 via a coupling tool (bolt / nut, etc.) 73. A cylindrical bush body 75 is provided so as to be movable up and down on a vertical body 74 standing from the bracket 72, and a transmission rotating body 71 is externally fitted on the bush body 75. It is configured to freely rotate around a certain vertical axis 74A.

  Here, the outer periphery of the transmission rotating body 71 is formed in an annular groove, and a rotationally passive portion 71a is formed by a laterally circumferential surface centering on the longitudinal axis 74A that is the outer peripheral surface of the annular groove. On the upward surface 71b of the transmission rotator 71, a ring-shaped rotation drive unit 76 centering on the longitudinal axis 74A is provided. This rotational drive part 76 consists of a round belt etc. which consist of urethane, for example, and is being fixed to the upward surface 71b with the adhesive agent etc. A compression coil that is configured so that a portion (inner side portion in the conveyor width direction) of the rotation drive unit 76 can be brought into contact with the conical rollers 26X and 26Y facing each other from below and is urged against the roller. A spring (an example of an urging means) 77 is externally fitted to the vertical axis body 74 between the bracket 72 side and the bush body 75 side. And the endless flat belt 31 whose belt width direction 31W is up and down is in contact with the inward side of the rotation passive portion 71a.

  At that time, in the curved path portions 4X and 4Y, the conical rollers 26X and 26Y group have a small diameter portion, that is, a portion having the same diameter as that of the straight rollers 16X and 16Y. A portion of the provided rotation driving unit 76 that reaches a predetermined position is configured to be freely contactable from below. As a result, the endless flat belt 31 supported and guided by the forward-portion-side guide means 51 group is transferred to the transport path 2 (conveyor width) in the upper straight path section 3X, the left curved path section 4X, and the lower straight conveyor apparatus 11Y. Although it is moved on the left side in the direction 1W), it is moved on the right side of the conveyance path 2 in the right curved path portion 4Y.

  Thus, when the conveyance path 2 has two types of curved path portions 4X and 4Y whose directions are different on the left and right, the endless flat belt 31 moves in the conveyor width direction between the curved path portions 4X and 4Y. Parts are provided. At that time, a conveyor width direction moving portion 81 is provided between the end portion of the right curved path portion 4Y and the start end portion of the lower linear conveyor device 11Y, and the end portion of the left curved path portion 4X and the right curve are provided. A conveyor width direction moving portion 85 is provided between the starting end portion of the path portion 4Y.

  That is, a left guide roller 82 is provided on the left side and a right guide roller 83 is provided on the right side at the start end portion of the lower linear conveyor device 11Y. The endless flat belt 31 guided from the left guide roller 82 to the right guide roller 83 is configured to move in a non-contact state between the adjacent (parallel) rollers 16Y and 16Y. ing. An example of the conveyor width direction moving unit 81 is configured by the above 82 to 83 and the like. The guide rollers 82 and 83 are provided so as to be freely rotatable on a vertical axis from the connection frame 24.

  Further, a right guide roller 86 is provided on the right side at the starting end portion of the right curved conveyor device 21Y, and a left guide roller 87 is provided on the left side at the end portion of the left curved conveyor device 21X. The endless flat belt 31 guided from the right guide roller 86 to the left guide roller 87 is configured to move in a non-contact state between the adjacent conical rollers 26X and 26Y. One example of the conveyor width direction moving unit 85 is configured by the above 86 to 87 and the like. The guide rollers 86 and 87 are provided so as to be freely rotatable on a vertical axis from the connection frame 14.

  As a result, in either of the two types of curved path portions 4X and 4Y, the conical rollers 26X and 26Y group reach a predetermined portion of the rotation drive portion 76 provided in the transmission rotating body 71 in a small diameter portion. These parts are configured to be able to contact from below. An example of the driving unit 30 is configured by the above 31-87 and the like.

  According to the driving means 30, the endless flat belt 31 is provided at the lower portion between the both reversing wheel bodies 42, the return portion side guiding means 61, the both reversing guide wheel bodies 48, the driving wheel body 47, and the tension guide wheel body 49. It is hung so that the inner and outer surfaces are in contact with each other and guided, and in the upper part between the two reversing wheels 42, the traveling portion side guide means 51, the transmission rotating body 71 group, and both conveyors move in the width direction. It is configured that the rotational force of the motor 45 is applied via the driving wheel body 47 by being hung so that the inner and outer surfaces thereof are in contact with and guided over the portions 81 and 85.

Hereinafter, the operation in the first embodiment will be described.
In FIG. 1, FIG. 3, FIG. 6, for example, the container A supplied to the starting end of the transport path 2 (upper linear path section 3X) by another carrying-in means (not shown) is used as the upper linear conveyor apparatus 11X. Is conveyed in a straight line on the upper straight path portion 3X, and is transported in a left semicircular shape on the left curved path portion 4X by the left curved conveyor portion 21X, and subsequently right curved by the right curved conveyor device 21Y. After being conveyed in a semicircular shape on the right path portion 4Y and linearly on the lower straight path portion 3Y by the lower straight conveyor device 11Y, the end of the transfer path 2 (lower straight path portion 3Y) It can be discharged from the section to another unloading means (not shown).

  At that time, in each of the conveyor devices 11X, 11Y, 21X, and 21Y, by rotating the driving wheel body 47 by driving the motor 45 in the driving means 30, the common endless flat belt 31 is rotated to obtain a conveying force. ing. That is, the endless flat belt 31 is reversely guided to the reversing wheel 42 at both end portions in the direction of the conveyance path 2, and is supported and guided by the traveling portion side guide means 51 in the traveling portion 32 </ b> A between the reversing wheels 42. In the return portion 32B, the guide portion 61 is supported and guided by the return portion side guide means 61, and in the vicinity of the drive wheel body 47, it is supported and guided by the reverse guide wheel body 48 and the tension guide wheel body 49.

  At this time, the endless flat belt 31 is moved from lower to upper in the forward portion 32A. That is, as shown in FIGS. 1 to 3, 5, and 9, the endless flat belt 31 having the belt thickness direction 31 </ b> T in the up-down direction is first received in the lower straight path portion 3 </ b> Y of the forward portion 32 </ b> A. By being received from below by the receiving roller 55 group of 52 and being pushed up (push-up guide), the linear roller 16Y group comes into contact with the lower roller 16Y from below and moves upward, and the linear roller 16Y group is driven to rotate. Thus, the lower straight path portion 3Y can be brought into the driving conveyance state. Next, after being reversely guided to the lower side by the reverse roller 58 of the bending guide portion 56, it is guided by the press roller 60 group to move to the lower side, and is reversely guided by the inclined reverse roller 59 to change the belt width direction 31W. It is sent out to the right curved path 4Y side (upper side) so as to be in the vertical direction.

  The endless flat belt 31 whose belt width direction 31W is up and down is guided from the left guide roller 82 of the conveyor width direction moving portion 81 to the right side guide as shown in FIGS. 1 to 5, 7, 9, and 10. By being guided to the roller 83, it is moved in the conveyor width direction from the left side to the right side. Next, in the right-curved path portion 4Y, that is, between the right guide roller 83 of the conveyor width direction moving portion 81 and the right guide roller 86 of the conveyor width direction moving portion 85, the belt width direction 31W is the endless direction. The flat belt 31 is brought into contact (pressure contact) from the inside across the rotation passive portions 71a of the transmission rotating body 71 group.

  As a result, the transmission rotating bodies 71 are each driven to rotate around the vertical axis 74 </ b> A, and the rotation driving unit 76 is rotated integrally with the transmission rotating body 71. At this time, the portion (inner side portion in the conveyor width direction 1W) of the rotation driving unit 76 that is in contact with the small diameter portion of the conical roller 26Y group facing from the lower side The conical roller 26 </ b> Y group can be driven to rotate, and the right curved path portion 4 </ b> Y can be brought into a driving conveyance state. At that time, the transmission rotating body 71 side is lifted and biased by the biasing force of the compression coil spring 77, so that the rotation of the conical roller 26Y from the lower side with respect to the rotation drive unit 76 is made constant. Contact pressure), and thus the conical roller 26Y group can always be rotated in a suitable and stable manner.

  As described above, in the right curved path portion 21Y, the rotation driving portion 76 of the transmission rotating body 71 is placed below the portion where the diameter of the conical roller 26Y group is small, that is, the same diameter as the diameter of the straight roller 16Y. , The rollers 26Y and 16Y can be rotated at the same rotational speed, and the direction of the container A is adjusted by the right curved path 4Y by the change in the peripheral speed of the conical rollers 26Y. However, the container A can be continuously transported at the same transport speed in both the path portions 4Y and 3Y.

  In this way, the endless flat belt 31 that has reached the start end of the right curved path 4Y with the belt width direction 31W in the vertical direction is moved from the right guide roller 86 to the left guide roller 87 of the conveyor width direction moving unit 85. By being guided, it is moved in the conveyor width direction from the right side to the left side. Next, in the left curved path portion 4X, that is, between the left guide roller 87 and the bending guide portion 56 of the conveyor width direction moving portion 85, the endless flat belt 31 with the belt width direction 31W in the vertical direction is transferred to the transmission rotor. Abutting (pressure contact) is performed from the inner side across the 71 groups of rotation passive portions 71a.

  Thereby, as shown in FIGS. 1 to 3 and FIG. 7, the transmission rotating bodies 71 are each driven to rotate around the vertical axis 74 </ b> A, and the rotation driving unit 76 is integrally rotated with the transmission rotating body 71. At this time, the part (inner side part in the conveyor width direction 1W) of the rotational drive unit 76 that is in a predetermined position is in contact with the part having a small diameter of the conical roller 26X group facing from the lower side. The conical roller 26X group can be driven to rotate, so that the left curved path portion 4X can be in a driving conveyance state. At that time, the transmission rotating body 71 is lifted and biased by the biasing force of the compression coil spring 77, so that the rotation of the conical roller 26X from the lower side with respect to the rotation drive unit 76 is made constant. Contact pressure), and therefore, the rotation of the conical rollers 26X group can always be performed suitably and stably.

  As described above, in the left curved path portion 4X, the rotation driving portion 76 of the transmission rotating body 71 is formed in a portion where the diameter of the conical roller 26X group is small, that is, a portion having the same diameter as the diameter of the straight rollers 16X and 16Y. , The rollers 26X, 26Y, 16X, and 16Y can be rotated at the same rotational speed, and the container is formed in the left curved path 4X by the change in the peripheral speed of the conical rollers 26X. While adjusting the direction of A, the container A can be continuously transported at the same transport speed in both the path portions 4X and 4Y.

  Further, by incorporating the conveyor width direction moving part 85, in either of the two curved path parts 4X, 4Y, the conical rollers 26X, 26Y rotate the transmission rotating body 71 to a portion where the diameter of the conical rollers 26X, 26Y is small. The drive unit 76 is brought into contact with the lower side so that the conical rollers 26X and 26Y can be rotated at the same rotational speed, so that both curved path portions 4X and 4Y can be changed by changing the peripheral speed of the conical rollers 26X and 26Y. The container A can be continuously transported at the same transport speed in both the curved path portions 4X and 4Y while adjusting the direction of the container A.

  The endless flat belt 31 that has moved to the end of the upper straight path portion 3X is first reversely guided by the inclined reversing roller 59 and then pressed by the pressing roller 60 group, as shown in FIGS. It is guided to move to the upper side, moves to the lower side with the belt thickness direction 31T as the vertical direction, and is reversely guided to the upper side by the reverse roller 58 to be the upper side, that is, the upper straight path portion 3X. While moving to the reversing ring 42 at the starting end of the roller, it is received from below by the receiving roller 55 group of the receiving guide portion 52 and is pushed up (push-up guide), so that the straight roller 16X group is moved from below. The straight roller 16X group can be driven and rotated by abutting and moving to the upper side, so that the lower straight path portion 3X can be brought into a driving conveyance state. Thereafter, the endless flat belt 31 is reversely guided by the reversing wheel 42 and then moved to the backward portion 32B.

  As described above, according to the conveyor facility 1 of the first embodiment, both the curves are formed while the common endless flat belt 31 is disposed over the linear path portions 3X and 3Y and the curved path portions 4X and 4Y. By providing the transmission rotating body 71 only facing the conical rollers 26X and 26Y group of the cylindrical path portions 4X and 4Y, the structure is simplified and the whole is inexpensive, and the drive to the rollers 16X, 16Y, 26X and 26Y group is performed. Force transmission can always be performed smoothly.

  In the first embodiment described above, a form in which the upper straight path portion 3X, the left curved path portion 4X, the right curved path portion 4Y, and the lower straight path portion 3Y are formed in this order as the conveyor facility 1 is shown. However, this is a form in which the conveyance path 2 is formed by connecting the left curved path part 4X and the right curved path part 4Y via the linear path part, one linear path part, and A form in which the conveyance path 2 is formed by one curved path part, a form in which the conveyance path 2 having an upper straight path part, an intermediate curved path part, and a lower straight path part is formed, A form in which a conveyance path 2 having a curved path portion on the side, an intermediate linear path portion, and a curved path portion on the lower side is formed, and an oval shape is formed by a pair of linear path portions and a pair of curved path portions It is a form that forms an endless transport path 2 It may be.

  In the first embodiment described above, a form in which the curved path portions 4X and 4Y are formed in a circular arc shape (60 degrees) is shown. This is because the curved path portions are formed in a semicircular shape (180 degrees). The formed form may be used.

  In the first embodiment described above, a form in which the conveyance path 2 is formed by the linear path portions 3X and 3Y and the curved path portions 4X and 4Y is shown. For example, this is the case of the linear path portions 3X and 3Y. A type in which a width-adjusting path portion is incorporated in the upper side, and a common endless flat belt 31 is disposed also in the width-adjusting path portion may be used.

  In the first embodiment described above, a form in which the curved path portions 4X, 4Y are formed by the conical rollers 26X, 26Y group is shown. This is because the straight path portions 3X, 3Y and the curved path portions 4X, 4X, 4Y may be formed by a group of straight rollers.

  In the first embodiment described above, the guide means is composed of the forward part side guide means 51 and the backward part side guide means 61, and various types of rollers are provided as the guide means 51 and 61 so as to be freely rotatable. Although shown, this may be a type in which a part of the roller is changed to a guide plate or the like and the endless flat belt 31 is slidably guided.

  In the first embodiment described above, the container A is shown as the transported object, but this can correspond to various transported objects.

BRIEF DESCRIPTION OF THE DRAWINGS It is Embodiment 1 of this invention, and is a partially notched schematic plan view of a conveyor installation. It is a schematic plan view of the conveyor equipment. It is a partially cutaway schematic side view of the conveyor equipment. It is an AA arrow line view of FIG. 1 in the conveyor equipment. It is a BB arrow line view of Drawing 1 in the conveyor equipment. It is a partially cutaway side view of the drive part in the conveyor equipment. It is CC arrow line view of FIG. 1 in the conveyor equipment. FIG. 2 is a DD arrow view of FIG. 1 in the conveyor facility. It is the E section enlarged view of FIG. 1 in the conveyor equipment. It is the F section enlarged view of FIG. 1 in the conveyor equipment.

Explanation of symbols

1 Conveyor equipment 2 Conveyance path 3X Upper straight path part 3Y Lower straight path part 4X Left curved path part (curved path part)
4Y right curved path (curved path)
11X Upper linear conveyor device 11Y Lower linear conveyor device 13 Linear conveyor frame 16X Straight roller (roller)
16Y Straight roller (roller)
21X Left-curved conveyor device 21Y Right-curved conveyor device 23 Arc-shaped conveyor frame 26X Conical roller (roller)
26Y Conical roller (roller)
30 Driving means 31 Endless flat belt 31T Belt thickness direction 31W Belt width direction 32A Forward part (action path part)
32B Returning part (return path part)
41 Drive unit 42 Reverse wheel 45 Motor 47 Drive wheel 51 Forward side guide means (guide means)
52 Receiving guide portion 55 Receiving roller 56 Bending guide portion 58 Reversing roller 59 Inclining reversing roller 60 Pressing roller 61 Returning portion side guiding means (guide means)
63 Guide wheel body 64 Tension adjusting section 71 Transmission rotating body 71a Rotary passive section 74 Vertical axis body 74A Vertical axis 75 Bush body 76 Rotation drive section 77 Compression coil spring (biasing means)
81 Conveyor width direction moving part 82 Left part guide roller 83 Right part guide roller 85 Conveyor width direction moving part 86 Right part guide roller 87 Left part guide roller A Container (conveyed object)

Claims (4)

  It is a conveyor facility in which a roller group is rotatably disposed on a conveyor frame to form a conveyance path having a linear path portion and a curved path portion, and the driving means of the roller group is arranged along the conveyance path. In addition, a common endless flat belt is disposed in each path portion, and a drive portion of the endless flat belt is provided. The endless flat belt is configured such that the belt thickness direction is defined as the vertical direction in the linear path portion. It is configured to be able to contact the roller group from below, and in the curved path portion, it is configured to be able to contact the rotational passive portion of the transmission rotating body group provided facing the roller group with the belt width direction as the vertical direction. , Conveyor equipment, characterized in that the rotation drive part of these transmission rotating bodies is configured to be able to contact the opposed rollers.   The transmission rotating body is arranged to face the roller from below, and is provided on the conveyor frame side so as to be freely rotatable around a vertical axis, and is rotated by a lateral circumferential surface around the vertical axis. A passive part is formed, and the upward surface is provided with a ring-shaped rotational drive part centered on the longitudinal axis, and the part of the rotational drive part that reaches a predetermined location can freely contact the opposing roller from below The conveyor equipment according to claim 1, further comprising an urging means for urging and abutting.   In the curved path portion, a conical roller group having a small diameter on the small diameter side in the curve and a large diameter on the large diameter side in the curve is disposed, and the transmission rotating body is arranged in a portion where the diameter of the conical roller group is small. The conveyor apparatus according to claim 1, wherein the rotation drive unit is configured to be abuttable.   In the curved path section, a conical roller group having a small diameter on the small diameter side of the curve and a large diameter on the large diameter side of the curve is arranged, and the conveyance path has two types of directions in which the curve direction is different on the left and right. When the curved path portions are provided, a conveyor width direction moving portion of the endless flat belt is provided between the curved path portions, and the diameter of the conical roller group is small in either of the two curved path portions. The conveyor equipment according to claim 1, wherein a rotational drive portion of the transmission rotating body is configured to be able to abut on the portion.

Images