JPWO2019159312A1 - Escalator step that allows you to visually check the fixed state on the step axis - Google Patents

Abstract

According to the present invention, the step (5) of the escalator (1), which can visually confirm the fixed state of the step (5) to the step axis (4) even when dust or the like adheres to the step (5), can be performed. The purpose is to provide. Step (5) includes a step board (8), a base (12), and a lifting section (21). The step board (8) has a plane on which the user (P) gets on during driving. The base (12) is provided below the step board (8), and fixes the step board (8) to the step shaft (4). The inner surface (16) of the base (12) faces the step axis (4). The lifting part (21) does not protrude from the inner surface (16) when the step plate (8) is fixed to the step shaft (4). The lifting portion (21) moves the tread plate (8) from the step shaft (4) by projecting the free end (24) from the inner surface (16) when the tread plate (8) is not fixed to the step shaft (4). Lift and tilt.

Description

  The present invention relates to escalator steps.

  Patent Document 1 describes an example of an escalator step. The step includes a fixing portion for fixing the step board to the step shaft. The fixing portion includes a lever and a spring on the outside. When the step plate is not fixed to the step shaft, the lever lifts and tilts the step plate from the step shaft by the elastic force of the spring. The maintenance person can visually confirm the state of the step fixed to the step axis by the inclination of the tread plate.

JP-A-10-120351

  However, dust or the like that has fallen from the sole of the user of the escalator or the like can adhere to the lever and the spring in the step of Patent Document 1. When dust or the like adheres, the lever or the spring sometimes does not move due to biting of the dust or the like. At this time, even when the step board is not fixed to the step shaft, the step board does not lift.

  The present invention has been made to solve such a problem. SUMMARY OF THE INVENTION An object of the present invention is to provide an escalator step capable of visually confirming the fixed state of the step on the step axis even when dust or the like adheres to the step.

  The step of the escalator according to the present invention includes a step plate having a flat surface on which a user gets in when the escalator is driven, a fixing portion provided below the step plate to fix the step plate to the step shaft, and the step plate being fixed to the step shaft. A lifting portion that lifts and tilts the tread plate from the step shaft by projecting partially from the inner surface when the tread plate is not fixed to the step shaft without projecting from the inner surface of the fixed portion facing the step shaft.

  According to the present invention, the step includes a step board, a fixing section, and a lifting section. The tread has a plane on which the user gets in during driving. The fixing part is provided below the step board, and fixes the step board to the step shaft. The inner surface of the fixed portion faces the step axis. The lifting portion does not protrude from the inner surface when the step board is fixed to the step shaft. The lifting portion lifts and tilts the step plate from the step shaft by partially projecting from the inner surface when the step plate is not fixed to the step shaft. Accordingly, even when dust or the like adheres to the step, the maintenance staff can more reliably visually confirm the fixing state of the step to the step axis.

FIG. 2 is a configuration diagram of an escalator including steps according to the first embodiment. FIG. 4 is a side view of the step according to the first embodiment. FIG. 3 is an enlarged perspective view of a main part of a step according to the first embodiment. FIG. 4 is an enlarged side view of a main part of a step according to the first embodiment. FIG. 4 is a side view of the step according to the first embodiment. FIG. 10 is an enlarged side view of a main part of a step according to a modification of the first embodiment. FIG. 10 is an enlarged side view of a main part of a step according to the second embodiment.

  An embodiment for carrying out the present invention will be described with reference to the accompanying drawings. In the respective drawings, the same or corresponding parts are denoted by the same reference numerals, and redundant description will be appropriately simplified or omitted.

Embodiment 1 FIG.
FIG. 1 is a configuration diagram of an escalator including steps according to the present embodiment.
In FIG. 1, the left-right direction of the escalator 1 is a direction perpendicular to the paper surface. In FIG. 1, the front-back direction of the escalator 1 is the left-right direction of the paper.

  In FIG. 1, the upper entrance 2a is provided above the escalator 1. The lower entrance 2b is provided below the escalator 1.

  The upper machine room 3 a is provided above the escalator 1. The upper machine room 3a is provided below the upper entrance 2a. The lower machine room 3 b is provided below the escalator 1. The lower machine room 3b is provided below the lower entrance 2b.

  The escalator 1 includes a plurality of step shafts 4, a plurality of steps 5, a pair of handrails 6, a driving device (not shown), and a control panel 7.

  The plurality of step shafts 4 are connected endlessly.

  Each of the plurality of steps 5 is fixed to each of the plurality of step axes 4. The plurality of steps 5 are arranged endlessly. Each of the plurality of steps 5 includes a tread plate 8. The step board 8 has a plane on which the user P gets in when the escalator 1 is operated.

  One of the pair of handrails 6 is provided to the left of the plurality of steps 5. The other of the pair of handrails 6 is provided to the right of the plurality of steps 5. Each of the pair of handrails 6 is formed endlessly.

  The drive device is provided in the upper machine room 3a.

  The control panel 7 is provided in the upper machine room 3a.

  The control panel 7 controls the operation of the driving device. The drive device circulates the plurality of step shafts 4 with the upper side as the outward path. Each of the plurality of steps 5 circulates in synchronization with each of the plurality of step axes 4. The plurality of steps 5 moving on the outward path are arranged in a stepwise manner at a fixed inclined portion of the escalator 1. The pair of handrails 6 circulate in synchronization with the plurality of steps 5.

  During the uphill operation of the escalator 1, the user P gets on one of the pair of handrails 6 on the tread plate 8 of step 5 and gets on from the lower entrance 2 b. The user P moves to the upper entrance 2a by stepping on the step board 8 in step 5 that moves on the outward route.

  When the escalator 1 is driving down, the user P grabs one of the pair of handrails 6 on the tread plate 8 in step 5 and gets on from the upper entrance 2a. The user P moves to the lower entry / exit 2b on the tread plate 8 in step 5 moving on the outward route.

Subsequently, the configuration of step 5 will be described with reference to FIGS.
FIG. 2 is a side view of the steps according to the present embodiment. FIG. 3 is an enlarged perspective view of a main part of a step according to the present embodiment.

  FIG. 2 shows a state where the step 5 is fixed to the step shaft 4.

  The step shaft 4 includes a pair of bearings 9. Each of the pair of bearings 9 is provided rotatably around the central axis of the step shaft 4. Each of the pair of bearings 9 is, for example, a nylon bush. One of the pair of bearings 9 is disposed on one side of the step shaft 4 in the left-right direction. The other of the pair of bearings 9 is arranged on the other side of the step shaft 4 in the left-right direction.

  Step 5 includes a riser 10, a pair of brackets 11, and a pair of bases 12.

  The riser 10 hangs down from one edge of the step board 8 in the front-rear direction.

  One of the pair of brackets 11 connects one side of the tread plate 8 and one side of the riser 10. The other of the pair of brackets 11 connects the other side of the step board 8 and the other side of the riser 10.

  The base 12 is an example of a fixing unit. One of the pair of bases 12 is provided below one of the pair of brackets 11. The other of the pair of bases 12 is provided below the other of the pair of brackets 11. Each of the pair of bases 12 is disposed below the step board 8 on the opposite side of the riser 10 in the front-rear direction of the step board 8.

  Each of the pair of bases 12 includes an upper base 13 and a lower base 14.

  The upper base 13 is an example of an upper fixing portion. The upper base 13 is fixed to the bracket 11. The upper base 13 has a fastening hole 15. The fastening hole 15 penetrates the end opposite to the riser 10 in the front-rear direction from above to below. The fastening hole 15 is a female screw. The upper base 13 has an inner surface 16. The inner surface 16 is disposed behind the fastening hole 15. The inner surface 16 is curved in a semicircular shape. The inner surface 16 faces the outer periphery of the bearing 9 of the step shaft 4 from above.

  The upper base 13 is an example of a lower fixing portion. The lower base 14 is connected to the upper base 13 so as to be rotatable around the left-right direction of step 5 as a rotation axis. The lower base 14 is connected behind the inner surface 16 of the upper base 13. The lower base 14 has a fastening hole 17. The fastening hole 17 penetrates the end of the upper base 13 on the same side in the front-rear direction as the fastening hole 15 from above to below. The fastening hole 17 is a female screw. The lower base 14 has an inner surface 18. The inner surface 18 is arranged between a portion connected to the upper base 13 and the fastening hole 17. The inner surface 18 is curved in a semicircular shape. The inner surface 18 faces the outer periphery of the bearing 9 of the step shaft 4 from below.

  Each of the pair of bases 12 is configured to open and close by rotating the lower base 14. Each of the pair of bases 12 is fixed to each of the bearings 9 of the step shaft 4 by tightening bolts 19.

  FIG. 3 shows the base 12 in an open state.

  The upper base 13 has an opening 20 on the inner surface 16.

  Step 5 includes a pair of lifting portions 21 and a pair of torsion springs 22.

  Each of the pair of lifting portions 21 is provided on each upper base 13 of the pair of bases 12. The lifting section 21 has a fixed end 23 and a free end 24. The fixed end 23 and the free end 24 are part of the lifting section 21.

  The fixed end 23 is arranged inside the upper base 13 from the opening 20. The fixed end 23 does not project from the inner surface 16. The fixed end 23 is rotatably provided.

  The free end 24 is an end opposite to the fixed end 23.

  Each of the pair of lifting portions 21 has a contact surface 25. The contact surface 25 is curved in a semicircular shape. The curvature of the contact surface 25 is the same as the curvature of the outer surface of the bearing 9 of the step shaft 4. The contact surface 25 has a shape that fits in the opening 20.

  The torsion spring 22 is an example of a lifting spring. Each of the pair of torsion springs 22 is provided at each fixed end 23 of the pair of lifting portions 21. The torsion spring 22 is disposed closer to the upper base 13 than the contact surface 25. One end of the torsion spring 22 is fixed to the lifting section 21. The other end of the torsion spring 22 is fixed to the upper base 13.

  When the base 12 is not fixed to the step shaft 4, the torsion spring 22 causes the free end 24 of the lifting portion 21 to protrude from the opening 20 of the inner surface 16 toward the outside of the upper base 13 by elastic force.

  When the base 12 is fixed to the step shaft 4, each of the pair of lifting portions 21 is pressed by the bearing 9 of the step shaft 4 while resisting the elastic force of the torsion spring 22. At this time, the free end 24 of the lifting portion 21 does not protrude from the inner surface 16. The contact surface 25 makes contact along the outer surface of the bearing 9 of the step shaft 4.

Subsequently, a method of visually confirming the state of the fixing of the step 5 to the step shaft 4 will be described with reference to FIGS. 4 and 5.
FIG. 4 is an enlarged side view of a main part of the step according to the present embodiment. FIG. 5 is a side view of the steps according to the present embodiment.

  FIG. 4 shows a state in which the base 12 is not fixed to the step shaft 4 due to forgetting or loosening of the bolt 19 during maintenance and inspection.

  In this case, the free end 24 of the lifting section 21 projects from the inner surface 16 by the elastic force of the torsion spring 22. The lifting unit 21 lifts the base 12 from the step shaft 4. The bracket 11 is lifted following the base 12. The tread plate 8 is lifted following the bracket 11.

  At this time, as shown in FIG. 5, the step board 8 is inclined. The maintenance person visually confirms that the step 5 is not fixed to the step shaft 4 by the inclination of the step board 8.

  As described above, the steps of the escalator according to the present embodiment include the tread plate 8, the base 12, and the lifting unit 21. The step board 8 has a plane on which the user P gets in when the escalator is operated. The base 12 is provided below the step board 8, and fixes the step board 8 to the step shaft 4. The inner surface 16 of the base 12 faces the step shaft 4. When the step board 8 is fixed to the step shaft 4, the lifting portion 21 does not project from the inner surface 16. When the step board 8 is not fixed to the step shaft 4, the lifting section 21 lifts and tilts the step board 8 from the step shaft 4 by the free end 24 protruding from the inner surface 16.

  Garbage or the like falls from the sole of the user P when driving the escalator 1. Dust and the like adhere to the outside of step 5. During operation of the escalator 1, the base 12 is fixed. At this time, the lifting portion 21 does not protrude from the inner surface 16. For this reason, the lifting unit 21 is not exposed to the outside. The lifting unit 21 does not adhere dust and the like that adhere to the outside of the step 5. Step 5 prevents the lifting unit 21 from becoming immobile due to biting of pebbles or dust. When the base 12 is not fixed to the step shaft 4 due to forgetting or loosening of the bolt 19 during maintenance and inspection, the lifting portion 21 tilts the tread plate 8. Accordingly, even when dust or the like adheres to the outside of the step 5, the maintenance staff can more reliably visually check the state of the step 5 fixed to the step shaft 4.

  The lifting unit 21 is inside the base 12. For this reason, the members constituting Step 5 can be made compact. When the step 5 is removed from the step shaft 4 and transported or stored, the lifting unit 21 does not interfere.

  Step 5 does not require the provision of a lever outside the base 12. Since the base 12 has a simple shape, manufacturing costs can be reduced.

  Step 5 includes a torsion spring 22. When the step plate 8 is not fixed to the step shaft 4, the torsion spring 22 causes the free end 24 of the lifting portion 21 to protrude from the inner surface 16 of the base 12 facing the step shaft 4 by elastic force. The lifting section 21 can lift the tread plate 8 with a simple structure.

  The lifting section 21 has a contact surface 25. When the step board 8 is fixed to the step shaft 4, the contact surface 25 contacts along the surface of the step shaft 4. Step 5 prevents a gap from being formed between the contact surface 25 and the step shaft 4. Step 5 prevents dust and the like from entering through a gap between the contact surface 25 and the step shaft 4. Thereby, in step 5, visual confirmation of the state in which the step 5 is fixed to the step shaft 4 by the maintenance staff can be more reliably performed.

  The base 12 has an upper base 13 that faces the step shaft 4 from above. The lifting unit 21 is provided on the upper base 13. Thus, even when the lower base 14 is dropped due to breakage or the like, the step 5 can lift the tread plate 8 from the step shaft 4 and tilt it.

  The pair of lifting portions 21 are provided on each of the pair of bases 12. Step 5 can reduce the load per torsion spring 22. The lifting section 21 can lift the tread plate 8 with a simpler structure.

  The lifting unit 21 may be provided on only one of the pair of bases 12. When the step board 8 is not fixed to the step shaft 4, the lifting section 21 lifts only one side of the step board 8. Step 5 tilts in the front-back direction and the left-right direction. In step 5 where the step board 8 is not fixed, since the step board 8 is asymmetrically inclined, the maintenance staff can easily confirm the difference from the step where the step board 8 is fixed.

  The lifting spring may be a leaf spring, a spring or a coil spring.

Next, a modification of the first embodiment will be described with reference to FIG.
FIG. 6 is an enlarged side view of a main part of a step according to a modification of the present embodiment.

  Each of the pair of bearings 9 has a fastening hole 26. The fastening hole 26 is a female screw.

  Each of the pair of bases 12 includes an upper base 13.

  The upper base 13 is fixed to the bracket 11. The upper base 13 has a fastening hole 15. The fastening hole 15 penetrates the end opposite to the riser 10 in the front-rear direction from above to below. The fastening hole 15 is a female screw. The upper base 13 has an inner surface 16. The inner surface 16 is disposed behind the fastening hole 15. The inner surface 16 is curved in a semicircular shape. The inner surface 16 faces the outer periphery of the bearing 9 of the step shaft 4 from above.

  Each of the pair of bases 12 is fixed to each of the pair of bearings 9 of the step shaft 4 by tightening the bolts 19 in the fastening holes 15 and 26.

  The lifting unit 21 is provided on the upper base 13. Thus, even in the base 12 having no lower base as in the present modification, the step 5 can be tilted by lifting the tread plate 8 from the step shaft 4.

Embodiment 2 FIG.
In the present embodiment, points different from the example disclosed in Embodiment 1 will be described in detail. As for features not described in the present embodiment, any of the features disclosed in the first embodiment may be employed.

The configuration of step 5 will be described with reference to FIG.
FIG. 7 is an enlarged side view of a main part of a step according to the present embodiment.

  The lifting section 21 is a leaf spring. The leaf spring is formed by bending an elastic steel plate. Steel plates are examples of elastic materials.

  Each of the pair of lifting portions 21 is provided on each upper base 13 of the pair of bases 12. The lifting section 21 has a fixed end 23 and a free end 24. The fixed end 23 and the free end 24 are part of the lifting section 21.

  The fixed end 23 is arranged inside the upper base 13 from the opening 20. The fixed end 23 does not project from the inner surface 16. The fixed end 23 is rotatably provided.

  The free end 24 is an end opposite to the fixed end 23.

  When the base 12 is not fixed to the step shaft 4, the free end 24 of the lifting portion 21 protrudes from the opening 20 of the inner surface 16 toward the outside of the upper base 13 by elastic force.

  When the base 12 is fixed to the step shaft 4, each of the pair of lifting portions 21 is pressed by the bearing 9 of the step shaft 4 while resisting its own elastic force. The free end 24 of the lifting section 21 does not project from the inner surface 16.

  The free end 24 of the lifting portion 21 projects from the inner surface 16 when the base 12 is not fixed to the step shaft 4 due to forgetting or loosening of the bolt 19 during maintenance and inspection. The lifting section 21 lifts the base 12 from the step shaft 4 by its own elastic force. The bracket 11 is lifted following the base 12. The tread plate 8 is lifted following the bracket 11.

  At this time, the step board 8 is inclined. The maintenance person visually confirms that the step 5 is not fixed to the step shaft 4 by the inclination of the step board 8.

  As described above, the step of the escalator according to the present embodiment includes the lifting unit 21. The lifting section 21 is made of an elastic material. Since the lifting portion 21 itself is formed of an elastic material, the number of parts in step 5 can be reduced. The lifting section 21 can lift the tread plate 8 with a simpler structure.

  The step of the escalator according to the present invention can be applied to an escalator system in which the step is detached from the step axis.

  Reference Signs List 1 escalator, 2a upper entrance, 2b lower entrance, 3a upper machine room, 3b lower machine room, 4 step shaft, 5 steps, 6 handrail, 7 control panel, 8 tread, 9 bearing, 10 riser, 11 bracket, 12 Base, 13 upper base, 14 lower base, 15 fastening hole, 16 inner surface, 17 fastening hole, 18 inner surface, 19 bolt, 20 opening, 21 lifting part, 22 torsion spring, 23 fixed end, 24 free end, 25 contact surface, 26 Fastening hole

The step of the escalator according to the present invention includes: a step plate having a plane on which a user gets in when the escalator is driven; a fixing portion provided below the step plate to fix the step plate to the step shaft ; and an inner surface facing the step axis of the fixing portion. having a free end which is an end portion opposite the fixed end and fixed end does not protrude from the tread plate does not protrude the free end from the inner surface facing the step axis of the fixed part when it is fixed to the step shaft footboard And a lifting section that lifts and tilts the tread plate from the step axis by projecting a free end from the opening on the inner surface when the step board is not fixed to the step axis.

The step of the escalator according to the present invention includes: a step plate having a plane on which a user gets in when the escalator is driven; a fixing portion provided below the step plate to fix the step plate to the step shaft; and an inner surface facing the step axis of the fixing portion. A stepped plate having a fixed end that does not protrude from the fixed end and a free end that is an end opposite to the fixed end, wherein the free end does not project from the inner surface of the fixed portion facing the step axis when the step plate is fixed to the step shaft. And a lifting portion that raises and tilts the tread plate from the step shaft by rotating and projecting the free end from the opening on the inner surface to the fixed portion when the is not fixed to the step shaft.

Claims (5)

A tread having a plane on which a user gets in when driving the escalator;
A fixing portion provided below the step board and fixing the step board to a step shaft;
When the step plate is fixed to the step axis, it does not protrude from the inner surface of the fixing portion facing the step axis, and when the step plate is not fixed to the step axis, it partially protrudes from the inner surface. A lifting unit that lifts and inclines the tread plate from the step axis,
Escalator step with. The step of the escalator according to claim 1, further comprising a lifting spring that causes a part of the lifting portion to protrude from the inner surface by elastic force when the step plate is not fixed to the step shaft.   The escalator step according to claim 1, wherein the lifting section is made of an elastic material.   The step of the escalator according to any one of claims 1 to 3, wherein the lifting portion has a contact surface that contacts along the surface of the step shaft when the step plate is fixed to the step shaft. . The fixing portion has an upper fixing portion facing the step axis from above,
The step of the escalator according to claim 1, wherein the lifting unit is provided on the upper fixing unit.

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