WO2018003874A1 - コンベヤ装置 - Google Patents
コンベヤ装置 Download PDFInfo
- Publication number
- WO2018003874A1 WO2018003874A1 PCT/JP2017/023792 JP2017023792W WO2018003874A1 WO 2018003874 A1 WO2018003874 A1 WO 2018003874A1 JP 2017023792 W JP2017023792 W JP 2017023792W WO 2018003874 A1 WO2018003874 A1 WO 2018003874A1
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- WIPO (PCT)
- Prior art keywords
- conveyor belt
- support
- width direction
- guide pulleys
- path
- Prior art date
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Classifications
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65G—TRANSPORT OR STORAGE DEVICES, e.g. CONVEYORS FOR LOADING OR TIPPING, SHOP CONVEYOR SYSTEMS OR PNEUMATIC TUBE CONVEYORS
- B65G15/00—Conveyors having endless load-conveying surfaces, i.e. belts and like continuous members, to which tractive effort is transmitted by means other than endless driving elements of similar configuration
- B65G15/02—Conveyors having endless load-conveying surfaces, i.e. belts and like continuous members, to which tractive effort is transmitted by means other than endless driving elements of similar configuration for conveying in a circular arc
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65G—TRANSPORT OR STORAGE DEVICES, e.g. CONVEYORS FOR LOADING OR TIPPING, SHOP CONVEYOR SYSTEMS OR PNEUMATIC TUBE CONVEYORS
- B65G15/00—Conveyors having endless load-conveying surfaces, i.e. belts and like continuous members, to which tractive effort is transmitted by means other than endless driving elements of similar configuration
- B65G15/08—Conveyors having endless load-conveying surfaces, i.e. belts and like continuous members, to which tractive effort is transmitted by means other than endless driving elements of similar configuration the load-carrying surface being formed by a concave or tubular belt, e.g. a belt forming a trough
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65G—TRANSPORT OR STORAGE DEVICES, e.g. CONVEYORS FOR LOADING OR TIPPING, SHOP CONVEYOR SYSTEMS OR PNEUMATIC TUBE CONVEYORS
- B65G15/00—Conveyors having endless load-conveying surfaces, i.e. belts and like continuous members, to which tractive effort is transmitted by means other than endless driving elements of similar configuration
- B65G15/60—Arrangements for supporting or guiding belts, e.g. by fluid jets
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65G—TRANSPORT OR STORAGE DEVICES, e.g. CONVEYORS FOR LOADING OR TIPPING, SHOP CONVEYOR SYSTEMS OR PNEUMATIC TUBE CONVEYORS
- B65G21/00—Supporting or protective framework or housings for endless load-carriers or traction elements of belt or chain conveyors
- B65G21/16—Supporting or protective framework or housings for endless load-carriers or traction elements of belt or chain conveyors for conveyors having endless load-carriers movable in curved paths
- B65G21/18—Supporting or protective framework or housings for endless load-carriers or traction elements of belt or chain conveyors for conveyors having endless load-carriers movable in curved paths in three-dimensionally curved paths
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65G—TRANSPORT OR STORAGE DEVICES, e.g. CONVEYORS FOR LOADING OR TIPPING, SHOP CONVEYOR SYSTEMS OR PNEUMATIC TUBE CONVEYORS
- B65G23/00—Driving gear for endless conveyors; Belt- or chain-tensioning arrangements
- B65G23/22—Arrangements or mountings of driving motors
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65G—TRANSPORT OR STORAGE DEVICES, e.g. CONVEYORS FOR LOADING OR TIPPING, SHOP CONVEYOR SYSTEMS OR PNEUMATIC TUBE CONVEYORS
- B65G39/00—Rollers, e.g. drive rollers, or arrangements thereof incorporated in roller-ways or other types of mechanical conveyors
- B65G39/10—Arrangements of rollers
- B65G39/12—Arrangements of rollers mounted on framework
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65G—TRANSPORT OR STORAGE DEVICES, e.g. CONVEYORS FOR LOADING OR TIPPING, SHOP CONVEYOR SYSTEMS OR PNEUMATIC TUBE CONVEYORS
- B65G2201/00—Indexing codes relating to handling devices, e.g. conveyors, characterised by the type of product or load being conveyed or handled
- B65G2201/04—Bulk
- B65G2201/045—Sand, soil and mineral ore
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65G—TRANSPORT OR STORAGE DEVICES, e.g. CONVEYORS FOR LOADING OR TIPPING, SHOP CONVEYOR SYSTEMS OR PNEUMATIC TUBE CONVEYORS
- B65G2201/00—Indexing codes relating to handling devices, e.g. conveyors, characterised by the type of product or load being conveyed or handled
- B65G2201/06—Articles and bulk
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65G—TRANSPORT OR STORAGE DEVICES, e.g. CONVEYORS FOR LOADING OR TIPPING, SHOP CONVEYOR SYSTEMS OR PNEUMATIC TUBE CONVEYORS
- B65G2812/00—Indexing codes relating to the kind or type of conveyors
- B65G2812/02—Belt or chain conveyors
- B65G2812/02128—Belt conveyors
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65G—TRANSPORT OR STORAGE DEVICES, e.g. CONVEYORS FOR LOADING OR TIPPING, SHOP CONVEYOR SYSTEMS OR PNEUMATIC TUBE CONVEYORS
- B65G2812/00—Indexing codes relating to the kind or type of conveyors
- B65G2812/02—Belt or chain conveyors
- B65G2812/02128—Belt conveyors
- B65G2812/02138—Common features for belt conveyors
- B65G2812/02148—Driving means for the belts
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65G—TRANSPORT OR STORAGE DEVICES, e.g. CONVEYORS FOR LOADING OR TIPPING, SHOP CONVEYOR SYSTEMS OR PNEUMATIC TUBE CONVEYORS
- B65G2812/00—Indexing codes relating to the kind or type of conveyors
- B65G2812/02—Belt or chain conveyors
- B65G2812/02128—Belt conveyors
- B65G2812/02138—Common features for belt conveyors
- B65G2812/02168—Belts provided with guiding means, e.g. rollers
Definitions
- the present invention relates to a conveyor apparatus that can be suitably used when carrying out earth and sand excavated from an underground excavation site via a shaft or a downhole to an overhead part through the shaft.
- a shield drilling machine is introduced through this shaft, and underground ground is excavated by this drilling machine.
- underground construction it is common to excrete excavated soil produced by excavation from the inside of the tunnel to the ground through a shaft and to discharge it from a sediment discharge position on the ground by a dump truck or the like.
- a belt conveyor when transporting excavated earth and sand using a belt conveyor, there is a limit to the inclination angle at which earth and sand can be conveyed depending on the conventional belt conveyor. Therefore, conventionally, when transporting excavated earth and sand through a vertical shaft or an oblique shaft, various lifting and lowering devices are separately required.
- Patent Document 1 discloses a conveyor device suitable for carrying excavated soil from the excavation site to the ground part through the shaft.
- the vertical conveyance section is equipped with a conveyance body which can scrape the transferred object fed from the lower horizontal conveyance section into the vertical conveyance section and delivers it to the upper horizontal conveyance section in a circulating manner.
- Patent Document 1 requires a transport body for transporting excavated soil separately from the conveyor device in the vertical transport unit. Therefore, the structure of the conveyor apparatus becomes complicated. Moreover, in the technique of patent document 1, in the return side of a perpendicular
- a conveyor apparatus is disposed along a vertically extending spiral conveyance path and disposed at a position forming an inflection point, and the inflection point of the conveyance path Upper edge portions are sequentially supported by the plurality of outward guide pulleys along the spiral conveyance path in a bent state in which the plurality of outward guide pulleys and the return path guide pulley that form the Winding in such a manner that the upper edge portion is supported by the plurality of return path side guide pulleys in order along the spiral conveyance path in a bent state folded in half in the width direction, Further, the endless conveyor belt is folded back at the folding positions on the upper side and the lower side of the transport path and is developed in the width direction in the vicinity of the folding positions, And a pair of upper return pulley and a lower return pulley for guiding in the return position of, respectively while supporting so as to stretched the conveyor belt,
- the apparatus is characterized by comprising: the plurality of forward path
- the conveyor belt circulates endlessly by the drive of the drive motor, and the excavated soil is placed on the unfolded conveyor belt in the vicinity of the folding position on the lower side of the transport path. Then, the conveyor belt holds the placed excavated earth and sand so as to surround it when it shifts to a folded state folded in half in the width direction, and while maintaining the held state, it is spiral on the outgoing side.
- the excavated soil can be transported toward the upper side of the transport route along the transport route.
- the conveyor belt is reopened from the bent state, so that excavated soil can be lowered from the conveyor belt and the soil can be collected continuously.
- the unfolded state is again bent and can be returned to the return path. For this reason, it is possible to provide a conveyor device suitable for continuous conveyance in the vertical direction without a complicated device configuration.
- the conveyor belt since the conveyor belt is bent in half in the width direction during transport excluding the vicinity of the folding position on both the forward path side and the return path side, the conveyor belt can excavate soil It can be held around to prevent or suppress spills.
- excavated soil can be transported and pumped up on the forward path side, and other members such as materials can be transported on the return path side from which the excavated soil is removed.
- the location which forms the said inflexion point is set to the corner
- the portion forming the inflection point may be set at a corner portion of a support frame having an axis extending in the vertical direction and having a polygonal shape when viewed from above preferable.
- the location forming the inflection point is set at the corner of the support frame having a polygonal shape, and the forward guide pulley and the return guide pulley may be arranged at the corner of the support frame. it can.
- the support frame includes a plurality of support shafts arranged so that the axis lines extend in the vertical direction, and the plurality of support shafts are arranged such that the cross section has a polygonal shape.
- the plurality of forward path guide pulleys and the backward path guide pulleys are disposed on each of the plurality of support shafts located at the corner of the support frame.
- the upper edge portion of the conveyor belt in a bent state folded in half in the width direction is supported by a plurality of conveyor belt support mechanisms, and each conveyor belt support mechanism is a corner portion of the support frame
- the conveyor belt in a bent state having an inner support roller attached to an inner position relative to the outer support roller of the roller support plate, the outer support roller and the inner support roller being folded in half in the width direction It is preferable to hold the upper edge portion of the inner side from outside and inside.
- the upper edge of the bent conveyor belt folded in the width direction is supported by the plurality of conveyor belt support mechanisms. Therefore, the bent state of the conveyor belt can be reliably maintained. And since each conveyor belt supporting mechanism holds the upper edge of the bent conveyor belt folded in half in the width direction by the outer supporting roller and the inner supporting roller from outside and inside, it supports the running resistance of the conveyor belt Can be made smaller.
- the drive motor may be dispersedly provided at a plurality of locations among the plurality of forward path side guide pulleys, the plurality of return path side guide pulleys, the upper turnaround pulley and the lower turnaround pulley. preferable. According to this conveyor device, since the drive motors are distributed, the tension of the conveyor belt can be reduced, and high lift conveyance can be realized.
- the conveyor device According to the conveyor device according to the present invention, it is possible to provide a conveyor device suitable for continuous conveyance in the vertical direction without a complicated device configuration and without occurrence of cargo spillage.
- FIG. 5 is a schematic view on arrow 4-4 in FIG. 1;
- FIG. 5 is a schematic view on arrow 4-4 in FIG. 1;
- FIG. 5 is a schematic view on arrow 4-4 in FIG. 1;
- FIG. 5 is a schematic view on arrow 4-4 in FIG. 1;
- FIG. 5 is a schematic view on arrow 4-4 in FIG. 1;
- FIG. 5 is a schematic plan view of the conveyor apparatus shown in FIG. It is the figure seen from the direction shown by the arrow 6 in FIG. It is the figure seen from the direction shown by the arrow 7 in FIG.
- It is an expanded view of the conveyor apparatus shown in FIG.
- the state which supports the upper edge part of the conveyor belt in the bending state folded in half by the conveyor belt supporting mechanism in the width direction is shown, (a) is a right view, (b) is a front view.
- It is the schematic which shows the modification of a conveyor belt support mechanism.
- It is sectional drawing which shows a mode that the upper edge part
- the conveyor apparatus 1 shown in FIG. 1 is used when carrying out the earth and sand excavated from the underground excavation site via a shaft or a downhole to the ground part through the shaft, and is a horizontal transfer unit located on the lower side inside the shaft 2 and a vertical transport unit 3 extending in the vertical direction in the stand and a horizontal transport unit 4 located on the ground.
- the conveyor device 1 is disposed along the spiral conveyance path extending in the vertical direction in the vertical conveyance unit 3 and at points P1 to P6 forming the inflection points P11 to P16.
- a plurality of forward path first to sixth guide pulleys 21 to 26 and return path second to seventh guide pulleys 32 to 37 forming the inflection points P11 to P16 of the transport path are disposed.
- the points P1 to P6 forming the inflection points P11 to P16 of the transport path are set at the corners of the rectangular shape as viewed from above in the present embodiment, and the axis extends in the vertical direction It is disposed at the corner of the support frame 10 which is disposed as well as having a square shape as viewed from above.
- the support frame 10 includes a plurality of support shafts 12 arranged so that the axis lines extend in the vertical direction, and the plurality of support shafts 12 have a rectangular cross section. Are arranged at a predetermined pitch.
- the lower ends of the support shafts 12 are fixed to the bottom plate 11, and the upper ends are fixed to the top plate 13.
- the four support shafts 12 located at the corners of the support frame 10 where the points P1 to P6 forming the inflection points P11 to P16 of the transport path are set are arranged in pairs at the top and bottom.
- a plurality of (six in the present embodiment) forward first to sixth guide pulleys 21 to 26 and a plurality of (six in the present embodiment) second to seventh guide pulleys 32-37 are provided.
- first to sixth guide pulleys 21 to 26 and the second to seventh guide pulleys 32 to 37 on the return side will be described.
- the forward second guide pulley 22 is disposed on the upper side at a position above the forward first guide pulley 21 of the support shaft 12 disposed in the upper left corner in FIG. 6 guide pulleys 36 are arranged.
- the forward third guide pulley 23 is disposed on the upper side at a position above the forward second guide pulley 22 of the support shaft 12 disposed in the upper right corner in FIG.
- the fifth guide pulley 35 is disposed.
- the forward route fourth guide pulley 24 is disposed on the upper side at a position above the forward route third guide pulley 23 of the support shaft 12 disposed in the lower right corner in FIG. 4 guide pulleys 34 are arranged.
- the forward guide-side fifth guide pulley 25 is disposed on the upper side and The third guide pulley 33 is disposed.
- the forward sixth guide pulley 26 is disposed on the upper side and the return path on the lower side.
- the second guide pulley 32 is disposed.
- first to sixth guide pulleys 21 to 26 are provided at positions where the outer circumference of the rectangular support frame 10 is gradually raised in a spiral so as to raise the conveyor belt 40 described later in a spiral.
- the return side second to seventh guide pulleys 32 to 37 are provided at positions where the outer circumference of the rectangular support frame 10 is gradually lowered in a spiral manner so that the conveyor belt 40 is lowered in a spiral manner.
- a plurality of support shafts 15 are provided so as to extend in the disposition direction of the support shafts 12 in the horizontal transport unit 4 located on the ground.
- the forward path seventh guide pulley 27 is disposed on the upper side
- the return path first guide pulley 31 is disposed on the lower side.
- the first to sixth guide pulleys 21 to 26 on the outgoing path side are disposed to be inclined with respect to the horizontal direction along the spiral conveyance path, and are rotatable around each support shaft 12.
- the second to seventh guide pulleys 32 to 37 on the return path side are disposed to be inclined with respect to the horizontal direction along the spiral conveyance path, and are rotatable around each support shaft 12.
- the forward path seventh guide pulley 27 is rotatable around the support shaft 15.
- the return side first guide pulley 31 is rotatable around the support shaft 15.
- the conveyor device 1 also includes an endless conveyor belt 40.
- the conveyor belt 40 is configured such that the upper edge portion 41 is sequentially supported on the outer peripheries of the first to seventh guide pulleys 21 to 27 along the spiral conveyance path in a bent state folded in half in the width direction. It is wound. Further, the conveyor belt 40 is configured such that the upper edge portion 41 is sequentially supported on the outer peripheries of the first to seventh guide pulleys 31 to 37 along the spiral conveyance path in a bent state in which the conveyor belt 40 is folded in two. It is wound around. Further, the conveyor belt 40 is folded back at respective folding positions of the horizontal conveyance unit 4 located on the upper side of the conveyance path and the horizontal conveyance unit 2 located on the lower side of the conveyance path.
- an upper folding pulley 51 is provided at the folding position of the horizontal conveyance unit 4 located on the upper side of the conveyance path.
- the upper folding pulley 51 supports and guides the conveyor belt 40 so as to stretch it at the folding position.
- the upper folding pulley 51 is rotatably supported by the support member 53.
- a lower folding pulley 52 is provided at the folding position of the horizontal conveyance unit 2 located on the lower side of the conveyance path.
- the lower folding pulley 52 supports and guides the conveyor belt 40 so as to stretch it at the folding position.
- the lower folding pulley 52 is rotatably supported by the support shaft 14.
- the conveyor belt 40 is wound around the outer circumference of the forward guide seventh guide pulley 27 in a bent state in which it is folded in half in the width direction on the forward path side, and turned 90 °, In the vicinity B of the folding position of the horizontal conveyance unit 4 positioned on the side, the sheet is unfolded in the width direction, and is folded back in the unfolded state by the upper folding pulley 51. Then, after the conveyor belt 40 is folded back in the unfolded state by the upper folding pulley 51, as shown in FIG. 7, it passes through the guide rollers 54 and 55 and is widthwise on the front side of the return side first guide pulley 31 , And is wound around the outer periphery of the return side first guide pulley 31.
- the conveyor belt 40 is folded back by the lower folding pulley 52 in a bent state in which it is folded in half in the width direction on the return path side, and then a horizontal conveyance portion positioned below the conveyance path In the vicinity A of the folding position of 2, the developed state is once developed in the width direction. Then, the conveyor belt 40 is again bent in half in the width direction, and is wound around the outer periphery of the outward first guide pulley 21.
- the method of reciprocating conveyance of the conveyor belt 40 and the method of development will be described in detail later.
- a drive motor 60 for driving the upper turning pulley 51 is connected to the upper turning pulley 51. Further, although not shown, a plurality of drive motors for driving the respective guide pulleys are also dispersed in the forward first guide pulley 21, the forward third guide pulley 23, and the forward fifth guide pulley 25 and arranged and connected. It is done. Further, the upper edge portion of the conveyor belt 40 in a bent state folded in half in the width direction is supported by a plurality of conveyor belt support mechanisms 70.
- each conveyor belt support mechanism 70 is attached to each of the plurality of support shafts 12 located between the corners of the support frame. As shown in FIGS. 9A and 9B, each conveyor belt support mechanism 70 supports a roller support plate 71 attached to each support shaft 12 so as to protrude outward, and a support for the roller support plate 71. An outer support roller 72 mounted at an outer position spaced from the shaft 12 and an inner support roller 73 mounted at an inner position relative to the outer support roller 72 of the roller support plate 71 are provided.
- the upper edge portion 41 of the conveyor belt 40 in a bent state folded in half in the width direction configured by the end 40 a on one side of the conveyor belt 40 and the end 40 b on the other side is the outer support roller 72 and the inner support It is nipped and supported from the inside and outside by the roller 73.
- the roller support plate 71 in each conveyor belt support mechanism 70 is, as shown in FIG. 9A, a linear flat plate portion 71a fixed to the support shaft 12 and the outer end of the flat plate portion 71a. And an outwardly extending extension 71b, and a hanging portion 71c extending downward from a portion inside the outer end of the flat plate 71a.
- the outer support roller 72 is rotatably supported on the lower surface of the outward extension of the extension 71b.
- the inner support roller 73 is formed in a truncated cone shape, and is rotatably supported on the outer surface of the hanging portion 71c.
- an auxiliary guide roller 74 is rotatably supported between the inner surface of the lower extension of the extension 71b and the outer surface of the hanging portion 71c.
- the auxiliary guide roller 74 guides the upper edge 41 when the upper edge 41 of the conveyor belt 40 moves upward.
- each conveyor belt support mechanism 70 is supported by the forward travel seventh guide pulley 27 and the return travel first guide pulley 31. It is attached to each of a plurality of support shafts 15 except the support shaft 15 which is carried out.
- the structure of the conveyor belt support mechanism 70 is similar to that of the conveyor belt support mechanism 70 described above.
- the plurality of support shafts 14 are at the positions excluding the area where the conveyor belt 40 is in the unfolded state. It is provided to extend in the direction of arrangement of Each conveyor belt support mechanism 70 is attached to each of the plurality of support shafts 14 except the support shaft 14 on which the lower folding pulley 52 is supported.
- the structure of the conveyor belt support mechanism 70 is similar to that of the conveyor belt support mechanism 70 described above.
- the conveyor belt 40 is firstly folded in the width direction at the lower side in the width direction by the horizontal conveyance unit 2 on the forward path side as shown in FIG. It is folded back by the side folding pulley 52. Thereafter, as shown in FIG. 4, the conveyor belt 40 is in the unfolded state in which it is once unfolded in the width direction in the vicinity A of the folding position. At this time, the widening member 42 is inserted into the bent conveyor belt 40 folded in half in the width direction, and the conveyor belt 40 is developed in the widthwise direction by the action of the widening member 42. Then, the conveyor belt 40 is folded again in the width direction into a bent state again by the action of the conveyor belt support mechanism 70, and is conveyed up to the forward first guide pulley 21 of the vertical conveyance unit 3.
- the conveyor belt 40 is folded in two in the width direction, the outer periphery of the first pass guide side pulley 21, the outer periphery of the second pass guide side pulley 22, the outer periphery of the third guide pulley pass side 23, the first pass side
- the inflection points of the first to sixth guide pulleys 21 to 26 are guided in the order of the outer circumference of the fourth guide pulley 24, the outer circumference of the forward fifth guide pulley 25, and the outer circumference of the sixth forward guide pulley 26. It is conveyed so as to rise spirally in the support frame 10 while changing the direction by 90 ° at P11 to P16.
- each of the first to sixth guide pulleys 21 to 26 on the outgoing path side has an extremely large diameter as compared with the support shaft 12. Therefore, the curvature of the conveyor belt 40 guided by the outer peripheries of the first to sixth guide pulleys 21 to 26 on the outgoing path side is small. Thereby, the traveling resistance of the conveyor belt 40 can be reduced. Then, the conveyor belt 40 guided on the outer side of the forward guide-side sixth guide pulley 26 is guided by the outer side of the forward guide-side seventh guide pulley 27 in a bent state folded in half in the width direction in the horizontal conveyance unit 4 and is 90 °. Be turned around.
- the upper edge portion of the conveyor belt 40 in a bent state folded in half in the width direction is supported by a plurality of conveyor belt support mechanisms 70. For this reason, the bent state of the conveyor belt 40 is reliably maintained. And since each conveyor belt support mechanism 70 holds and supports the upper edge portion 41 of the bent conveyor belt folded in half in the width direction by the outer supporting roller 72 and the inner supporting roller 73 from the outside, the conveyor The traveling resistance of the belt 40 can be reduced.
- the upper edge 41 of the conveyor belt 40 moves upward between the inner surface of the lower extension of the extension 71 b supporting the outer support roller 72 and the outer surface of the hanging portion 71 c supporting the inner support roller 73.
- the auxiliary guide roller 74 for guiding the upper edge portion 41 at the time of rotation is rotatably supported. Therefore, even if the upper edge portion 41 of the conveyor belt 40 moves upward, the traveling of the conveyor belt 40 is guided by the auxiliary guide roller 74 and does not become a resistance.
- the conveyor belt 40 which is guided by the outer side of the forward guide side seventh guide pulley 27 and turned in a bent state folded in half in the width direction is developed in the width direction in the vicinity B of the folding position of the horizontal conveyance portion 4
- the unfolded state is folded back by the upper folding pulley 51.
- the conveyor belt 40 folded back in the unfolded state by the upper folding pulley 51 passes through the guide rollers 54 and 55 and then, by the action of the conveyor belt support mechanism 70, in the width direction on the front side of the return path side first guide pulley 31 It becomes a bent state folded in half.
- the conveyor belt 40 in a bent state folded in half in the width direction is guided along the outer periphery of the return path side first guide pulley 31 and is transported to the forward path second guide pulley 32 of the vertical transport section 3 on the return path side. Ru.
- the conveyor belt 40 is folded in half in the width direction, the outer periphery of the second road guide pulley 32, the outer periphery of the third guide pulley 33, the outer circumference of the fourth guide pulley 34, and the second road side
- the inflection point of each of the second to seventh guide pulleys 32 to 37 is guided in the order of the outer periphery of the fifth guide pulley 35, the outer periphery of the return path sixth guide pulley 36, and the outer periphery of the return path seventh guide pulley 37. It is conveyed so as to descend spirally in the support frame 10 while changing the direction by 90 ° at P16 to P11.
- each of the second to seventh guide pulleys 32 to 37 on the return path side has an extremely large diameter as compared with the support shaft 12. Therefore, the curvature of the conveyor belt 40 guided by the outer circumferences of the second to seventh guide pulleys 32 to 37 on the return path side is small. Thereby, the traveling resistance of the conveyor belt 40 can be reduced. Then, the conveyor belt 40 guided on the outer side of the return path seventh guide pulley 37 is conveyed to the lower folding pulley 52 in a bent state in which the horizontal conveyance unit 2 is folded in half in the width direction.
- the conveyor belt 40 is endlessly circulated as long as the drive motor is driving, the above-mentioned forward movement and backward movement are repeated.
- the upper edge of the bent conveyor belt 40 folded in two in the width direction is supported by a plurality of conveyor belt support mechanisms 70.
- the bent state of the conveyor belt 40 is reliably maintained.
- each conveyor belt support mechanism 70 holds and supports the upper edge portion 41 of the bent conveyor belt folded in half in the width direction by the outer supporting roller 72 and the inner supporting roller 73 from the outside, the conveyor The traveling resistance of the belt 40 can be reduced.
- the upper edge 41 of the conveyor belt 40 moves upward between the inner surface of the lower extension of the extension 71 b supporting the outer support roller 72 and the outer surface of the hanging portion 71 c supporting the inner support roller 73.
- the auxiliary guide roller 74 for guiding the upper edge portion 41 at the time of rotation is rotatably supported. Therefore, even if the upper edge portion 41 of the conveyor belt 40 moves upward, the traveling of the conveyor belt 40 is guided by the auxiliary guide roller 74 and does not become a resistance.
- a method of carrying out the earth and sand excavated from the underground excavation site by the conveyor device 1 configured as described above to the ground part through the shaft will be described.
- the horizontal conveyance unit 2 on the forward side of the conveyor belt 40 when the conveyor belt 40 is expanded in the width direction in the vicinity A of the folding position, the soil excavated from the underground excavation site is placed on the conveyor belt 40. Place. Then, when the conveyor belt 40 is bent in half in the width direction, the placed excavated soil is held so as to be surrounded by the conveyor belt 40.
- the excavated earth and sand changes the direction of the vertical conveyance unit 3 at the inflection points P11 to P16 of the first to sixth guide pulleys 21 to 26 by 90.degree. It rises spirally and is transported to the horizontal transport unit 4.
- the excavated earth and sand is held by the conveyor belt 40 so as to be surrounded by the conveyor belt 40, and is turned by 90 ° by the outward seventh guide pulley 27 together with the conveyor belt 40. Then, the excavated soil can be taken out from the conveyor belt 40 when the conveyor belt 40 is deployed in the width direction in the vicinity B of the folding position. Therefore, the excavated soil can be unloaded from the conveyor belt 40 in the vicinity B of the turning back position and continuously collected.
- the conveyor belt 40 from which the excavated soil is taken out is folded back in the unfolded state by the upper folding pulley 51, passes through the guide rollers 54, 55, and then returns to the first guide pulley 31 by the action of the conveyor belt support mechanism 70.
- the conveyor belt 40 is changed in direction by the return side first guide pulley 31 while being in a bent state that is folded in half in the width direction on the return side, and further, in the vertical conveyance unit 3, each return side second to fourth 7 Lowers spirally while changing the direction by 90 ° at inflection points P16 to P11 of the guide pulleys 32 to 37, and is conveyed to the horizontal conveyance unit 2 and returns to the original position.
- continuous conveyance in the vertical direction becomes possible without a complicated device configuration. Further, continuous conveyance in horizontal and vertical directions can be achieved with one conveyor device.
- the conveyor belt 40 is bent in half in the width direction during conveyance excluding the vicinity A and B of the folding position on both the forward path side and the return path side, and the excavated soil is surrounded by the conveyor belt 40 As it is held as such, spillage can be prevented or suppressed.
- the conveyor belt 40 is bent in half in the width direction during conveyance excluding the neighborhoods A and B at the return position on both the forward side and the return side, the excavated soil is conveyed on the outward side. Other materials such as materials can also be transported on the return road side where the soil has been excavated and excavated soil has been removed. Furthermore, since the conveyor belt 40 is bent in half in the width direction during transport excluding the portions A and B near the folding position on both the forward and return sides, a large stone in the excavated soil Even if small sand is mixed, the conveyor belt 40 can wrap and transport excavated earth and sand mixed with those large stones and small sand.
- the conveyor belt 40 is bent in half in the width direction during conveyance excluding the neighborhoods A and B at the return position on both the forward and backward sides, so that excavated soil can be surrounded by the conveyor belt 40 Because there is no risk of spillage even if the emergency stop during transport.
- drive motors for driving the respective guide pulleys are dispersed at a plurality of locations in the upper return pulley 51, the forward first guide pulley 21, the forward third guide pulley 23, and the forward fifth guide pulley 25. As it is provided, the tension of the conveyor belt can be reduced.
- the conveyor device 1 is not only used when unloading soil excavated from an underground excavation site via a shaft or an inclined shaft to the ground part through the shaft, but is also a storage to a silo for storing stored products such as coal. Can also be used for the transport of
- the horizontal conveyance parts 2 and 4 are not necessarily required.
- the conveyor belt 40 is folded back at the folding positions on the upper side and the lower side in the conveying direction in the vertical conveying unit 3 extending in the vertical direction, and is developed in the width direction in the vicinity of the folding positions.
- the lower folding pulley 52 and the upper folding pulley 51 may be guided and guided so as to stretch the conveyor belt 40 at respective folding positions instead of the horizontal conveyance units 2 and 4.
- points P1 to P6 forming inflection points P11 to P16 are square as viewed from above It does not have to be set at the corner of the polygonal shape including the shape. For example, it may be set at the corner of the Z shape as viewed from above. Further, the places P1 to P6 forming the inflection points P11 to P16 do not necessarily have to be set at the corners of the support frame 10 having a polygonal shape including a quadrilateral shape as viewed from above.
- the forward path guide pulley and the backward path guide pulley may be disposed at locations (for example, other members disposed in the upright holes) forming inflection points P11 to P16 other than the corner portions of the support frame 10.
- the support frame 10 may have a polygonal shape other than the rectangular shape as viewed from above.
- the support frame 10 may be arranged so that the axis extends in the vertical direction and has a polygonal shape as viewed from above, so that the plurality of support shafts 12 are necessarily in a polygonal shape when viewed from above It does not have to be arranged and configured.
- the height of the support frame 10 in the vertical conveyance unit 3 may be adjusted according to the height of the stand, and the numbers of the forward path guide pulleys and the return path guide pulleys are not limited to seven, respectively. It is determined by the height of 10 and the arrangement pitch in the spiral conveyance path.
- the drive motor 60 is connected to the upper folding pulley 51, and a plurality of drive motors (not shown) are connected to the forward first guide pulley 21, the forward third guide pulley 23, and the forward fifth guide pulley 25.
- the drive motor drives at least one of the first to seventh guide pulleys 21 to 27, the first to seventh guide pulleys 31 to 37, the upper return pulley 51, and the lower return pulley 52. It just needs to be connected to
- the structure of the conveyor belt support mechanism 70 is not limited to the examples shown in FIGS. 9 (A) and 9 (B).
- a plurality of rollers 75 may be arranged along a periphery of a conveyor belt 40 which is folded in two on a bracket supported at the lower side (not shown).
- the first to sixth guide pulleys 21 to 26 and the second to seventh guide pulleys 32 to 37 on the return route side are disposed not only in a pair at the top and bottom but also in parallel at the left and right. May be
- FIG. 11 shows that the upper edge portion 41 of the conveyor belt 40 is supported on the outer periphery of the outward first guide pulley 21.
- a first recess 21 a formed in a trapezoidal cross-sectional shape is formed endlessly in the circumferential direction, and a cross-sectional trapezoid is formed below the first recess 21 a
- a second recess 21b formed in a shape is formed endlessly in the circumferential direction.
- one end 40a of the conveyor belt 40 constituting the upper edge 41 of the conveyor belt 40 is formed in a trapezoidal cross-sectional shape which has a shape complementary to the first recess 21a, and is fitted to the first recess 21a Being supported.
- the other end 40b of the conveyor belt 40 constituting the upper edge 41 of the conveyor belt 40 is formed in a trapezoidal cross-sectional shape complementary to the second recess 21b, and is fitted to the second recess 21b Being supported.
- the end 40a on one side of the conveyor belt 40 is fitted into and supported by the first recess 21a of the forward first guide pulley 21, and the other end 40b of the conveyor belt 40 is on the outward side
- the conveyor belt 40 is engaged with and supported by the second recess 21 b of the first guide pulley 21, and in this state, the conveyor belt 40 is wound around the outer periphery of the outward first guide pulley 21.
- a conveyor belt 40 having a trapezoidal cross-sectional shape is formed also on all the outer peripheral surfaces of the second to seventh guide pulleys 22 to 27 and the first to seventh guide pulleys 31 to 37 on the forward route side.
- the first concave portion 21a formed in a trapezoidal cross-sectional shape is formed endlessly in the circumferential direction and the trapezoidal cross-sectional shape is formed on the lower side of the first concave portion 21a.
- a second concave portion 21b formed in a trapezoidal cross-sectional shape into which the other end 40b of the conveyor belt 40 is fitted is formed endlessly in the circumferential direction.
- the upper edge portion 41 of the conveyor belt 40 does not shift up and down, and by the appropriate frictional force due to the concavo-convex fitting, the forward first to seventh guide pulleys 21 to 27 and the backward first to seventh guide pulley 31
- the conveyor belt 40 can be endlessly circulated properly and reliably since the conveyor belt 40 is fed while being supported by the outer circumferential surface of the to 37.
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- Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- Structure Of Belt Conveyors (AREA)
- Framework For Endless Conveyors (AREA)
Abstract
Description
ここで、ベルトコンベヤを用いて掘削土砂を搬送する場合、従来のベルトコンベヤによっては、土砂を搬送し得る傾斜角度に限界がある。そのため、従来、立坑もしくは斜坑を介して掘削土砂を搬送する場合には、各種の揚重機器を別途に要していた。
例えば、特許文献1には、垂直搬送部内に、下部水平搬送部から送り込まれた被搬送物を垂直搬送部内へ掻き上げ、上部水平搬送部へ受け渡す搬送体を循環自在に装備している。
また、特許文献1記載の技術では、垂直搬送部のリタン側では、搬送体が天地逆を向くため、荷こぼれが生じやすいという問題がある。
そこで、本発明は、このような問題点に着目してなされたものであって、複雑な装置構成とすることなく、かつ荷こぼれが生じることなく、垂直方向への連続搬送用として好適なコンベヤ装置を提供することを課題とする。
前記複数の往路側ガイドプーリ及び復路側ガイドプーリと前記一組の上側折り返しプーリ及び下側折り返しプーリのうち少なくとも一つを駆動する駆動モータとを備えることを特徴とする。
このため、複雑な装置構成とすることなく、垂直方向への連続搬送用として好適なコンベヤ装置を提供することができる。
また、前述のコンベヤ装置において、前記変曲点を形成する箇所は、軸線が垂直方向に延びるように配置されるとともに上方から見て多角形形状を有する支持枠の角部に設定されることが好ましい。
また、前述のコンベヤ装置において、前記支持枠は、軸線が垂直方向に延びるように配置される複数の支持軸を備え、該複数の支持軸を横断面が多角形形状となるように配置してなり、前記複数の往路側ガイドプーリ及び復路側ガイドプーリは、前記支持枠の角部に位置する複数の支持軸のそれぞれに配置されていることが好ましい。
更に、前述のコンベヤ装置において、幅方向に二つ折りされた屈曲状態の前記コンベヤベルトの上縁部は、複数のコンベヤベルト支持機構によって支持され、各コンベヤベルト支持機構は、前記支持枠の角部間に位置する複数の支持軸のそれぞれに、外方に突出するように取り付けられたローラ支持板と、該ローラ支持板の前記支持軸から離間した外側の位置に取り付けられた外側支持ローラと、前記ローラ支持板の前記外側支持ローラに対して内側の位置に取り付けられた内側支持ローラとを備え、前記外側支持ローラと前記内側支持ローラとで幅方向に二つ折りされた屈曲状態の前記コンベヤベルトの上縁部を外内から挟持して支持することが好ましい。
このコンベヤ装置によれば、駆動モータが分散配置されるので、コンベヤベルトの張力を小さくすることができ、高揚程搬送を実現できる。
図1に示すコンベヤ装置1は、立坑もしくは斜坑を介して地下掘削現場から掘削した土砂を、立坑を通じて地上部に搬出する際に用いるものであり、立抗内の下側に位置する水平搬送部2と、立抗内において垂直方向に延在する垂直搬送部3と、地上に位置する水平搬送部4とを有する。
ここで、搬送経路の変曲点P11~P16を形成する箇所P1~P6は、本実施形態においては、上方から見て四角形形状の角部に設定されるものであり、軸線が垂直方向に延びるように配置されるとともに上方から見て四角形状を有する支持枠10の角部に設定されている。
そして、搬送経路の変曲点P11~P16を形成する箇所P1~P6が設定される支持枠10の角部に位置する4つの支持軸12のそれぞれには、上下で一対をなして配置される前述の複数(本実施形態にあっては6個)の往路側第1乃至第6ガイドプーリ21~26及び複数(本実施形態にあっては6個)の復路側第2乃至第7ガイドプーリ32~37が設けられている。
ここで、各往路側第1乃至第6ガイドプーリ21~26は、螺旋状の搬送経路に沿って水平方向に対し傾斜配置され、各支持軸12を中心に回転可能となっている。また、各復路側第2乃至第7ガイドプーリ32~37は、螺旋状の搬送経路に沿って水平方向に対し傾斜配置され、各支持軸12を中心に回転可能となっている。また、往路側第7ガイドプーリ27は、支持軸15を中心に回転可能となっている。また、復路側第1ガイドプーリ31は、支持軸15を中心に回転可能となっている。
また、幅方向に二つ折りされた屈曲状態のコンベヤベルト40の上縁部は、複数のコンベヤベルト支持機構70によって支持されている。
そして、往路側第6ガイドプーリ26の外側を案内されたコンベヤベルト40は、水平搬送部4において幅方向で二つ折りされた屈曲状態で往路側第7ガイドプーリ27の外側を案内されて90°方向転換される。
そして、上側折り返しプーリ51で展開状態のまま折り返されたコンベヤベルト40は、ガイドローラ54,55を通過した後、コンベヤベルト支持機構70の作用によって復路側第1ガイドプーリ31の手前側で幅方向で二つ折りされた屈曲状態となる。
幅方向で二つ折りされた屈曲状態となったコンベヤベルト40は、復路側第1ガイドプーリ31の外周を案内され、復路側において、垂直搬送部3の往路側第2ガイドプーリ32にまで搬送される。
そして、復路側第7ガイドプーリ37の外側を案内されたコンベヤベルト40は、水平搬送部2において幅方向で二つ折りされた屈曲状態で下側折り返しプーリ52に至るまで搬送される。
ここで、復路側において、幅方向で二つ折りされた屈曲状態のコンベヤベルト40の上縁部は、複数のコンベヤベルト支持機構70によって支持されている。このため、コンベヤベルト40の屈曲状態は確実に維持される。そして、各コンベヤベルト支持機構70は、外側支持ローラ72と内側支持ローラ73とで幅方向に二つ折りされた屈曲状態のコンベヤベルトの上縁部41を外内から挟持して支持するので、コンベヤベルト40の走行抵抗を小さくすることができる。
コンベヤベルト40の往路側における水平搬送部2で、折り返し位置の近傍Aでコンベヤベルト40が幅方向に展開された展開状態となったところで、地下掘削現場から掘削した土砂をコンベヤベルト40上に載置する。すると、コンベヤベルト40が幅方向で二つ折りされた屈曲状態となったときに、載置された掘削土砂はコンベヤベルト40により囲繞するように保持される。そして、掘削土砂は、コンベヤベルト40によって保持状態が維持されたまま垂直搬送部3を各往路側第1乃至第6ガイドプーリ21~26の変曲点P11~P16で向きを90°ずつ変えつつ螺旋状に上昇し、水平搬送部4に搬送される。
従って、折り返し位置の近傍Bで掘削土砂をコンベヤベルト40から降ろして連続的に揚土することができる。
そして、コンベヤベルト40は、復路側で、幅方向で二つ折りされた屈曲状態となったまま復路側第1ガイドプーリ31によって方向転換し、更に、垂直搬送部3で各復路側第2乃至第7ガイドプーリ32~37の変曲点P16~P11で向きを90°ずつ変えつつ螺旋状に下降し、水平搬送部2に搬送されて元の位置に戻る。
ここで、コンベヤベルト40が、往路側及び復路側とも、折り返し位置の近傍A、Bを除く搬送中において、幅方向に二つ折りの屈曲状態となっており、掘削土砂はコンベヤベルト40により囲繞するように保持されるので、荷こぼれを防止又は抑制することができる。
更に、また、コンベヤベルト40が、往路側及び復路側とも、折り返し位置の近傍A、Bを除く搬送中において、幅方向に二つ折りの屈曲状態となっているので、掘削土砂の中に大きな石や小さな砂が混じっていたとしても、コンベヤベルト40によりそれらの大きな石や小さな砂が混じった掘削土砂を包み込んで搬送することができる。
また、上側折り返しプーリ51、往路側第1ガイドプーリ21、往路側第3ガイドプーリ23及び往路側第5ガイドプーリ25には、当該ガイドプーリのそれぞれを駆動する駆動モータが複数箇所に分散して設けられているので、コンベヤベルトの張力を小さくすることができる。
例えば、コンベヤ装置1は、立坑もしくは斜坑を介して地下掘削現場から掘削した土砂を、立坑を通じて地上部に搬出する際に用いる場合のみならず、石炭などの貯蔵物を貯蔵するサイロへの貯蔵物の搬送にも用いることができる。
また、当該変曲点P11~P16を形成する箇所P1~P6は、上方から見て四角形状を含む多角形形状を有する支持枠10の角部に設定される必要は必ずしもない。往路側ガイドプーリ及び復路側ガイドプーリは、支持枠10の角部以外の変曲点P11~P16を形成する箇所(例えば、立孔に配置された他の部材)に配置されてもよい。
また、支持枠10は、軸線が垂直方向に延びるように配置されるとともに上方から見て多角形形状を有すればよく、必ずしも、複数の支持軸12を上方から見て多角形形状となるように配置して構成する必要はない。
また、駆動モータ60は上側折り返しプーリ51に接続され、図示しない複数の駆動モータが往路側第1ガイドプーリ21、往路側第3ガイドプーリ23、往路側第5ガイドプーリ25に接続されているが、駆動モータは、往路側第1乃至第7ガイドプーリ21~27及び復路側第1乃至第7ガイドプーリ31~37と上側折り返しプーリ51及び下側折り返しプーリ52のうち少なくとも一つを駆動するように接続されていればよい。
また、往路側第1乃至第6ガイドプーリ21~26及び復路側第2乃至第7ガイドプーリ32~37は、上下で一対をなして配置される場合のみならず、左右に並列して配置されてもよい。
2 水平搬送部
3 垂直搬送部
4 水平搬送部
10 支持枠
11 底板
12 支持軸
13 頂板
14 支持軸
15 支持軸
21 往路側第1ガイドプーリ(往路側ガイドプーリ)
22 往路側第2ガイドプーリ(往路側ガイドプーリ)
23 往路側第3ガイドプーリ(往路側ガイドプーリ)
24 往路側第4ガイドプーリ(往路側ガイドプーリ)
25 往路側第5ガイドプーリ(往路側ガイドプーリ)
26 往路側第6ガイドプーリ(往路側ガイドプーリ)
27 往路側第7ガイドプーリ(往路側ガイドプーリ)
31 復路側第1ガイドプーリ(復路側ガイドプーリ)
32 復路側第2ガイドプーリ(復路側ガイドプーリ)
33 復路側第3ガイドプーリ(復路側ガイドプーリ)
34 復路側第4ガイドプーリ(復路側ガイドプーリ)
35 復路側第5ガイドプーリ(復路側ガイドプーリ)
36 復路側第6ガイドプーリ(復路側ガイドプーリ)
37 復路側第7ガイドプーリ(復路側ガイドプーリ)
40 コンベヤベルト
40a 一方側の端部
40b 他方側の端部
41 上縁部
42 拡幅部材
51 上側折り返しプーリ
52 下側折り返しプーリ
53 支持部材
54,55 ガイドローラ
60 駆動モータ
70 コンベヤベルト支持機構
71 ローラ支持板
71a 平板部
71b 延長部
71c 垂下部
72 外側支持ローラ
73 内側支持ローラ
74 補助ガイドローラ
A 搬送経路の下方側に位置する水平搬送部の折り返し位置の近傍
B 搬送経路の上方側に位置する水平搬送部の折り返し位置の近傍
P1~P6 変曲点を形成する箇所
P11~P16 搬送経路の変曲点
Claims (6)
- 垂直方向に延びる螺旋状の搬送経路に沿い、かつ変曲点を形成する箇所に配置されて前記搬送経路の変曲点を形成する複数の往路側ガイドプーリ及び復路側ガイドプーリと、
幅方向で二つ折りされた屈曲状態で前記螺旋状の搬送経路に沿って前記複数の往路側ガイドプーリに順に上縁部が支持されるように巻回されるとともに、幅方向で二つ折りされた屈曲状態で前記螺旋状の搬送経路に沿って前記複数の復路側ガイドプーリに順に上縁部が支持されるように巻回され、さらに、前記搬送経路の上方側及び下方側のそれぞれの折り返し位置で折り返されるとともに前記それぞれの折り返し位置の近傍で幅方向に展開された展開状態となる無端状のコンベヤベルトと、
前記それぞれの折り返し位置で前記コンベヤベルトを張設するように支持しつつ案内する一組の上側折り返しプーリ及び下側折り返しプーリと、
前記複数の往路側ガイドプーリ及び復路側ガイドプーリと前記一組の上側折り返しプーリ及び下側折り返しプーリのうち少なくとも一つを駆動する駆動モータとを備えることを特徴とするコンベヤ装置。 - 前記変曲点を形成する箇所は、上方から見て多角形形状の角部に設定されることを特徴とする請求項1に記載のコンベヤ装置。
- 前記変曲点を形成する箇所は、軸線が垂直方向に延びるように配置されるとともに上方から見て多角形形状を有する支持枠の角部に設定されることを特徴とする請求項2に記載のコンベヤ装置。
- 前記支持枠は、軸線が垂直方向に延びるように配置される複数の支持軸を備え、該複数の支持軸を横断面が多角形形状となるように配置してなり、
前記複数の往路側ガイドプーリ及び復路側ガイドプーリは、前記変曲点を形成する箇所に設定される前記支持枠の角部に位置する複数の支持軸のそれぞれに配置されていることを特徴とする請求項3に記載のコンベヤ装置。 - 幅方向に二つ折りされた屈曲状態の前記コンベヤベルトの上縁部は、複数のコンベヤベルト支持機構によって支持され、各コンベヤベルト支持機構は、前記支持枠の角部間に位置する複数の支持軸のそれぞれに、外方に突出するように取り付けられたローラ支持板と、該ローラ支持板の前記支持軸から離間した外側の位置に取り付けられた外側支持ローラと、前記ローラ支持板の前記外側支持ローラに対して内側の位置に取り付けられた内側支持ローラとを備え、前記外側支持ローラと前記内側支持ローラとで幅方向に二つ折りされた屈曲状態の前記コンベヤベルトの上縁部を外内から挟持して支持することを特徴とする請求項3に記載のコンベヤ装置。
- 前記駆動モータは、前記複数の往路側ガイドプーリ、複数の復路側ガイドプーリ、上側折り返しプーリ及び下側折り返しプーリのうち複数箇所に分散して設けられていることを特徴とする請求項1乃至5のうちいずれか一項に記載のコンベヤ装置。
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CN201780041182.9A CN109715531B (zh) | 2016-07-01 | 2017-06-28 | 输送机装置 |
EP17820228.9A EP3480141B1 (en) | 2016-07-01 | 2017-06-28 | Conveyor apparatus |
MYPI2018003012A MY191202A (en) | 2016-07-01 | 2017-06-28 | Conveyor apparatus |
KR1020187038239A KR102341134B1 (ko) | 2016-07-01 | 2017-06-28 | 컨베이어 장치 |
US16/313,523 US10689198B2 (en) | 2016-07-01 | 2017-06-28 | Conveyor apparatus |
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