JP5037162B2 - Escalator step structure - Google Patents

Description

  The present invention is made of a metal plate in which ridges parallel to the step traveling direction for passengers to ride on the surface side and having a trapezoidal or mountain-shaped cross section are formed at a predetermined pitch in a direction perpendicular to the step traveling direction. The step structure of the escalator provided with the cleat of this, the riser for closing a level | step difference, and the flame | frame to which these cleats and a riser are fixed.

  In general, an escalator step includes a cleat for passengers to ride on its surface side, a riser for closing the step, and a frame to which these cleats and the riser are fixed. In order to prevent slip accidents of passengers, ridges parallel to the step traveling direction are formed at a predetermined pitch in a direction perpendicular to the step traveling direction.

  As the cleat, an extruded aluminum material formed by extrusion, an aluminum die-cast material formed by press-fitting molten aluminum into a mold, or a metal plate bent into a predetermined shape is used. However, since aluminum extruded profiles and die-cast materials have lower wear resistance compared to those made of metal plates, in recent years, metal plate cleats with excellent wear resistance have begun to be used. Such cleats made of metal plates are not only excellent in durability, but also the pitch between ridges and the width of the ridges can be freely changed according to the processing conditions during bending. There is an advantage that a product suitable for the escalator site can be easily provided.

  As a step structure of an escalator for fixing such a metal plate cleat to a frame, for example, in a step of a man conveyor constituted by a cleat part, a riser part, these cleat parts, a frame part to which the riser part is attached, The cleat portion is formed into a thin corrugated molded body, a reinforcing body is interposed between the corrugated molded body and the frame, and a step structure of an escalator that fixes the corrugated molded body and the reinforcing body with spot welding or a bolt (for example, (Refer to Patent Document 1), a step of a man conveyor comprising a cleat portion on which a passenger rides, a frame portion for supporting the cleat portion, and the like. And a flat portion is formed on both sides of the cleat portion, and the side clamp is formed on the flat portion. Provided with a chromatography preparative step structure of the escalator for bolting the side cleat reinforcing member provided below the corrugated molded body (e.g., see Patent Document 2.) Or the like is present.

  However, in the former escalator step structure fixed by spot welding, the electrode is usually inserted from the surface side to the bottom between the ridges between the narrow ridges of the cleat and the reinforcing body facing the tip side of this electrode. Since the electrode is also brought into contact with the part on the back side and fixed by spot welding, it is very difficult to set the electrode between the narrow protrusions of such a cleat, so the contact state of the electrode is poor. In the escalator step structure with the latter bolt fastening, since the bolts etc. are inserted and screwed from the surface side between the narrow ridges of the cleat, There is a drawback in that there is a risk of wrinkling the surface side of the cleat with the tip of the tool when screwing, and in addition, any escalator scalpel Even in the lap structure, spot welding must be performed at multiple locations from the surface side of the cleat, and work must be performed to fasten multiple locations with bolts. In any escalator step structure, there is a drawback that the aesthetic appearance on the surface side of the cleat is greatly impaired because welding marks, bolt heads, and the like are visible on the surface side of the cleat on which the passenger rides.

  Therefore, as a step structure of an escalator that does not impair the beauty of the front side of the cleat on which such passengers ride, for example, a tread board made of a thin metal plate with a rectangular cross section in which a plurality of rod-like fasteners are fused on the back surface The upper plate is provided with a plurality of holes through which the fastener passes, and the upper plate to which the tread plate is joined is formed integrally with the upper plate. A synthetic resin tread base having a curved plate, a plurality of holes through which the fastener passes, and a tread support plate to which the upper plate is joined, and the tread support plate A metal frame having a riser support plate to which the curved plate is joined, and a bracket that is provided integrally with the tread plate support plate and the riser support plate and receives a shaft of a traveling wheel; Up The upper plate and is passed through the fastener holes of the tread plate support plate, the pressing-face board, the step structure of the escalator where the step board base and the frame are coupled (e.g., see Patent Document 3.) And the like are present.

  However, in such an escalator step structure, although welding marks and bolt heads are not visible from the front side of the cleat on which the passenger rides, a plurality of rod-like fasteners are fused on the back side of the cleat. In addition, it is necessary to provide a plurality of holes for penetrating the rod-like fasteners at positions corresponding to the cleat-like fasteners of the cleats such as the tread base and the frame, so that the productivity is very high. There was a drawback of being bad.

JP-A-54-159990 JP 56-48390 A Japanese Patent Laid-Open No. 6-16374

  The present invention eliminates the drawbacks of the prior art, and a protrusion having a trapezoidal shape or a mountain shape in cross section parallel to the step traveling direction for passengers to ride on the surface side is predetermined in a direction orthogonal to the step traveling direction. A step structure of an escalator comprising a cleat made of a metal plate formed with a pitch, a riser for closing a step, and a frame to which these cleats and the riser are fixed, particularly on the surface side of the cleat It is an object of the present invention to provide an escalator step structure having good productivity and excellent productivity.

  As a result of earnest research to solve the above-mentioned problems, the present inventors have found that a protrusion having a trapezoidal shape or a mountain-shaped cross section parallel to the step traveling direction for passengers to ride on the surface thereof is orthogonal to the step traveling direction. Steps the inner walls facing each other on the back side of the ridges at the part corresponding to the ridges of the cleats as fixed reinforcing plates to fix the cleats made of metal plates formed at a predetermined pitch in the direction to the frame A pair of slits are provided at a predetermined pitch parallel to the step traveling direction with a distance connecting in a direction orthogonal to the traveling direction, and an engaging ridge formed to protrude on the cleat side is provided between each pair of slits. In addition, each engaging ridge of the fixed reinforcing plate is inserted into the back side of the ridge of the cleat, and further between the slits of the respective engaging ridges of the fixed reinforcing plate. However, if the fixed reinforcing plate is fixed to the cleat by inserting and caulking a bit that is slightly wider, each engaging ridge of the fixed reinforcing plate is inserted into the ridge of the cleat from the back side, and these By simply caulking between the slits of the engaging ridges, the fixed reinforcing plate can be firmly and securely fixed to the cleat, so that not only can the productivity be improved dramatically, but also the fixed reinforcement When the cleat is viewed from the surface side after the plate is fixed to the cleat, there are no means for fixing the fixing reinforcing plate such as welding marks or bolt heads to the cleat on the surface side of the cleat on which the passenger rides. The present invention was completed by investigating that the appearance on the surface side of the cleat can be enhanced because it does not appear.

That is, the present invention is a metal plate in which ridges having a trapezoidal shape or a mountain shape in cross section are formed at a predetermined pitch in a direction perpendicular to the step traveling direction for passengers to ride on the surface side. A cleat made of steel, a fixed reinforcing plate fixed to the back side of the cleat, a riser, and a frame to which the fixed reinforcing plate of the cleat and the riser are fixed,
The fixed reinforcing plate at a portion corresponding to the ridge of the cleat has a pair of slits separated from the step traveling direction by a distance connecting opposite inner wall surfaces on the back side of the ridge in a direction perpendicular to the step traveling direction. An engagement ridge is formed in parallel with a predetermined pitch and is formed between the pair of slits so as to protrude toward the cleat.
A bit that is slightly wider than between the slits of the respective engaging ridges of the fixed reinforcing plate in a state in which the respective engaging ridges of the fixed reinforcing plate are fitted on the back side of the ridge of the cleat. The escalator step structure is characterized in that the cleat is fixed to the fixed reinforcing plate by inserting and caulking.

  In the step structure of the escalator according to the present invention, the riser is formed with a predetermined pitch in a direction parallel to the step traveling direction and having a trapezoidal or mountain-shaped cross section in a direction perpendicular to the step traveling direction. And a riser fixing reinforcing plate that is fixed to the back side of the riser. The riser fixing reinforcing plate at a portion corresponding to the protrusion of the riser has a protrusion on the riser fixing reinforcement plate. A pair of slits are provided at a predetermined pitch parallel to the step traveling direction with a distance connecting the opposing inner wall surfaces on the back side of the strip in a direction orthogonal to the step traveling direction, and a riser between each pair of slits In the state where each of the engaging ridges of the fixed reinforcing plate for the riser is fitted on the back side of the ridge of the riser, the riser is further provided. If the riser is fixed to the fixed reinforcement plate for the riser by inserting and caulking a bit slightly wider than the slit between the engagement ridges of each fixed reinforcement plate, In addition, since it can be easily and reliably fixed, it is preferable that the productivity can be further improved, and on the surface side of the riser, a fixing reinforcing plate for the riser such as a weld mark or a bolt head is provided. Since no means for fixing to the riser appears, it has been found that the aesthetic appearance on the surface side of the riser can also be enhanced.

  In addition, if the engaging ridges of the fixed reinforcing plate and / or the engaging ridges of the riser fixing reinforcing plate are formed so as to form a mountain shape when viewed from the direction orthogonal to the step traveling direction, each engaging ridge It has also been found that it is preferable that the joint ridges can be firmly fixed because they are inserted in a state where they are inserted into the cleat or riser ridges.

  Since the step structure of the escalator according to the present invention has the above-described configuration, the engaging ridges of the fixed reinforcing plate are fitted into the ridges of the cleat from the back side and the slits of these engaging ridges are provided. By simply caulking the gap, the fixed reinforcing plate can be easily and reliably fixed to the cleat, so that the productivity can be greatly improved and the cleat is fixed after the fixed reinforcing plate is fixed to the cleat. When viewed from the surface side, there is no means for fixing the fixing reinforcing plate such as weld marks or bolt heads on the surface of the cleat on which the passenger rides. Not only can the aesthetics on the side be enhanced, but also the cleat and the fixed reinforcing plate can be inserted by the engaging ridges of the fixed reinforcing plate and between the slits of these engaging ridges. It is possible to firmly fix by the action of the caulking can be prevented for example or deviates from well cleat fixing position as force is applied to the step traveling direction with respect to the cleat, to come off.

  In addition, the fixed reinforcing plate can be easily and securely made cleat by simply inserting each engaging ridge of the fixed reinforcing plate into the ridge of the cleat from the back side and caulking between the slits of these engaging ridges. Since it can be fixed, there is no need to perform spot welding, fastener welding, or bolt fastening in order to fix the cleat as in the prior art, so the production process can be greatly omitted. .

  In the step structure of the escalator according to the present invention, the riser is formed with a predetermined pitch in a direction parallel to the step traveling direction and having a trapezoidal or mountain-shaped cross section in a direction perpendicular to the step traveling direction. And a riser fixing reinforcing plate that is fixed to the back side of the riser. The riser fixing reinforcing plate at a portion corresponding to the protrusion of the riser has a protrusion on the riser fixing reinforcement plate. A pair of slits are provided at a predetermined pitch parallel to the step traveling direction with a distance connecting the opposing inner wall surfaces on the back side of the strip in a direction orthogonal to the step traveling direction, and a riser between each pair of slits In the state where each of the engaging ridges of the fixed reinforcing plate for the riser is fitted on the back side of the ridge of the riser, the riser is further provided. If the riser is fixed to the fixed reinforcement plate for the riser by inserting and caulking a bit slightly wider than the slit between the engagement ridges of each fixed reinforcement plate, In addition, since it can be easily and reliably fixed, it is preferable that the productivity can be further improved, and on the surface side of the riser, a fixing reinforcing plate for the riser such as a weld mark or a bolt head is provided. Since no means for fixing the riser to the riser appears, not only can the aesthetics on the surface side of the riser be improved, it is preferable, but also the insertion of the riser fixing reinforcing plate by the engagement ridges and It is preferable that it can be firmly fixed by the caulking action between the slits of these engaging ridges, and further, spot welding or fastener welding is performed to fix the riser, bolts It is preferable that the production process can be greatly omitted because there is no need for tying, etc., and there is no need for equipment such as spot welding or fastener vegetation for fixing cleats and risers. It is preferable because the introduction cost of the production equipment can be reduced.

  In addition, if the engaging ridges of the fixed reinforcing plate and / or the engaging ridges of the riser fixing reinforcing plate are formed so as to form a mountain shape when viewed from the direction orthogonal to the step traveling direction, each engaging ridge The joint ridges are inserted with the cleat or riser protruding into the back of the ridge, so that each can be firmly fixed, which is preferable, and such a mountain-shaped engagement ridge Can be formed simply by pressing the portion located between the pair of slits and in the vicinity of the central portion in the longitudinal direction until it is plastically deformed into a mountain shape, so that the fixed reinforcing plate and / or It is preferable because the fixed reinforcing plate for the riser can be easily manufactured.

Hereinafter, the step structure of the escalator according to the present invention will be described in detail with reference to the drawings.
FIG. 1 is a perspective explanatory view showing one embodiment of the step structure of the escalator according to the present invention, FIG. 2 is a partially enlarged sectional explanatory view of the AA line in FIG. 1, and FIG. 3 is a partial BB line in FIG. FIG. 4 is an enlarged cross-sectional explanatory view, FIG. 4 is a cross-sectional explanatory view showing a state before caulking between the slits of each engaging bulging portion of the fixed reinforcing plate in FIG. 3, and FIG. 5 is a view of FIG. FIG. 6 is a perspective explanatory view showing an example of a fixed reinforcing plate used in the step structure of the escalator according to the present invention.

  In the drawings, reference numeral 1 denotes a cleat made of a metal plate on which the passenger rides, and is fixed to a frame 4 described later via a fixing auxiliary plate 2 described later as shown in FIGS.

  The cleat 1 is formed by bending a metal plate cut into a predetermined size, and the surface side of the cleat 1 has a cross section parallel to the step traveling direction for passengers to ride on the surface side. The ridges 1a having a trapezoidal shape or a mountain shape are formed at a predetermined pitch in a direction orthogonal to the step traveling direction.

  As shown in FIGS. 1 and 3, the ridge 1a of the cleat 1 has a trapezoidal cross section parallel to the step traveling direction, that is, a flat surface on the surface side of the ridge 1a. And the inner wall surfaces 1aa, 1aa opposite to each other on the back side are separated from each other, or the cross section is formed in a mountain shape in parallel with the step traveling direction (not shown), There is a shape in which the top side of the ridge 1a forms a surface on an arc and the upper edge sides of the inner wall surfaces 1aa, 1aa facing each other on the back side are in contact with each other. The shape of the ridge 1a is appropriately selected, and the top of the ridge 1a has a step traveling direction in order to prevent a passenger on the cleat 1 from slipping in the step traveling direction. The groove is stepped in the orthogonal direction Desirably it is formed parallel to a predetermined pitch and.

  The material of the cleat 1 is not particularly limited as long as it is made of a metal plate, but is not limited to a stainless steel plate such as a coated stainless steel plate or a clear coated stainless steel plate, a zinc-based plated steel plate, an aluminum-based plated steel plate, or a highly corrosion-resistant Zn-Al-. Plated steel sheets such as Mg alloy-plated steel sheets and Zn-Al alloy-plated steel sheets are preferably used, and on the surface side of the cleat 1, before and after the front and rear steps and the skirt guard, do not put foot A demarcation line that indicates the dangerous part of the step is displayed in yellow paint on the peripheral edge adjacent to the step or skirt guard, or by installing a plate made of yellow synthetic resin separately. Preferably it is.

  Reference numeral 2 denotes a fixed reinforcing plate 2 fixed to the back surface side of the cleat 1. In the portion corresponding to the ridge 1a of the cleat 1, the opposite inner wall surfaces 1aa and 1aa on the back surface side of the ridge 1a are stepped in the step traveling direction. A pair of slits 2a, 2a are provided at a predetermined pitch parallel to the step traveling direction with a distance connecting in a direction perpendicular to the direction of the travel, and a protrusion formed on the cleat 1 side between each pair of slits 2a, 2a. A raised portion 2b is provided. Then, in a state in which each of the engaging ridges 2b of the fixed reinforcing plate 2 is fitted on the back side of the protrusion 1a of the cleat 1, it is slightly smaller than between the slits 2a and 2a of the respective engaging ridges 2b. A fixed reinforcing plate 2 to which the cleat 1 is firmly fixed is fixed to a frame 4 (to be described later) and fixed to the back side of the ridge 1a of the cleat 1 by inserting a bit having a wide width and crimping. Since each protrusion 2b of the plate 2 is fixed, the protrusion 1a of the cleat 1 is held, so that the cleat 1 itself is reinforced.

  The fixed reinforcing plate 2 has such a shape that the engaging ridges 2b as described above can be fixed to a frame 4 to be described later in a state in which the engaging ridges 2b are provided at a predetermined pitch parallel to the step traveling direction and the cleat 1 is firmly fixed. Although not particularly limited as long as it is formed, for example, as shown in FIG. 6, a plurality of engaging ridges 2 b are projected at a predetermined pitch on the cleat 1 side, and a fixing surface for fixing to the cleat 1 and the fixing Even if it is comprised from the base part which fell from the both-sides edge of the longitudinal direction of a surface, and was further bent in the direction parallel to a fixed surface, and the hole for fixing the flame | frame 4 mentioned later was pierced Good.

  In the portion of the fixed reinforcing plate 2 corresponding to the ridge 1a of the cleat 1, the inner wall surfaces 1aa and 1aa facing each other on the back side of the ridge 1a of the cleat 1 are set in the step traveling direction as shown in FIGS. A pair of slits 2a, 2a are provided at a predetermined pitch parallel to the step traveling direction with a distance connecting in a direction orthogonal to each other, and between the pair of slits 2a, 2a, a protrusion formed on the cleat 1 side is formed. A raised portion 2b is provided.

  The pair of slits 2a, 2a are provided at a distance connecting the opposing inner wall surfaces 1aa, 1aa on the back side of the ridge 1a of the cleat 1 in a direction perpendicular to the step traveling direction. When the engaging bulge portion 2b formed to protrude toward the cleat 1 between the slits 2a and 2a is fitted on the back surface side of the ridge 1a of the cleat 1, the engagement bulge portion 2b is formed as shown in FIGS. This is because the both side surfaces are pressed into contact with the opposing inner wall surfaces 1aa and 1aa on the back side of the ridge 1a so as to be firmly fitted into the back side of the ridge 1a of the cleat 1 and between the pair of slits 2a and 2a. Specifically, when the cross section of the ridge 1a of the cleat 1 has a trapezoidal shape, the distance is above the opposing inner wall surfaces 1aa and 1aa on the back side of the ridge 1a as shown in FIGS. It is formed at a distance between the distance between the edges and the distance between the lower edges, while crossing the ridge 1a of the cleat 1 There when forming a chevron shape, the inner wall surface 1aa not shown facing the rear surface side of the projection 1a, and is formed in a distance shorter than the distance between the lower edge of 1aa.

  The engaging ridge 2b provided between the pair of slits 2a and 2a is provided by projecting and forming a portion located between the pair of slits 2a and 2a toward the cleat 1 side. For example, first, a pair of slits 2a, 2a are formed at a predetermined pitch parallel to the step traveling direction at a predetermined distance, and then a portion located between each pair of slits 2a, 2a is pressed toward the cleat 1 side. Each engaging ridge 2b may be formed to project by plastic deformation, or the fixed reinforcing plate 2 itself provided with the engaging ridge 2b may be produced by press-fitting molten aluminum into a mold. .

  The engaging ridge 2b may be formed in an arc shape or a trapezoidal shape when viewed from a direction orthogonal to the step traveling direction, but the engaging ridge 2b is orthogonal to the step traveling direction. If it is formed so as to form a mountain shape when viewed from the direction, each engaging ridge 2b is inserted in a state where it enters into the back of the ridge 1a of the cleat 1, so that the ridge of the cleat 1 is inserted. Not only is it preferable to firmly fix each so that 1a does not fall sideways, but in order to form such a mountain-shaped engaging ridge 2b, it is simply located between the pair of slits 2a, 2a. Since it can be formed by simply pressing the vicinity of the central portion in the longitudinal direction, the fixed reinforcing plate 2 can be easily manufactured, which is preferable.

  The number of the protruding protrusions 2b may be the same as the number of the protrusions 1a in the longitudinal direction of the fixed reinforcing plate 2 in parallel with the step traveling direction so that the protrusions 2b can be fitted into all the protrusions 1a of the cleat 1. As shown in FIG. 6, the number of the protrusions 2a of the cleat 1 is smaller than the number of the protrusions 1a, and the number of the engaging ridges 2b that can secure the fitting strength for securely fixing the cleat 1 is stepped. You may provide with a predetermined pitch in parallel with a direction.

  Reference numeral 3 denotes a riser for closing a step, which is fixed to a frame 4 to be described later, and prevents dust or the like from entering between the cleats 1 and 1 adjacent to each other in the step traveling direction or the passenger's feet being caught. It is.

  As shown in FIGS. 1 and 2, the riser 3 is generally formed in a circular arc shape having a convex surface on the front side in the step traveling direction from the side edge on the cleat 1 side to the side edge on the opposite side. In addition, protrusions 3a having a trapezoidal shape or a mountain shape in cross section parallel to the step traveling direction are formed at a predetermined pitch in a direction orthogonal to the step traveling direction.

  As the riser 3, for example, an extruded aluminum material formed by extrusion, an aluminum die-cast material formed by press-fitting molten aluminum into a mold, or a metal plate bent into a predetermined shape is preferable. Used.

  As shown in FIG. 1 or FIG. 2, the riser 3 is a metal in which protrusions 3 a having a trapezoidal shape or a mountain shape in cross section parallel to the step traveling direction are formed at a predetermined pitch in a direction perpendicular to the step traveling direction. The riser fixed reinforcing plate 5 is a plate-made riser, and is further provided on the back side of the riser 3. The riser fixed reinforcing plate 5 corresponding to the protrusion 3 a of the riser 3 includes A pair of slits are provided at a predetermined pitch parallel to the step traveling direction with a distance connecting the opposing inner wall surfaces on the back side of the ridge 3a in a direction orthogonal to the step traveling direction. In the middle, there are provided protruding protrusions projecting on the riser 3 side, and each engaging protrusion of the riser fixing reinforcing plate 5 is fitted on the back side of the protrusion 3a of the riser 3, and further The fixed reinforcing plate 5 for the riser When the riser 3 is fixed to the riser fixing reinforcing plate 5 by inserting and crimping a bit slightly wider than between the slits of the respective engagement raised portions, the riser 3 is fixed. In addition, since it can be easily and reliably fixed, it is preferable that the productivity can be further improved, and on the surface side of the riser 3, the fixing reinforcement for the riser such as a welding mark or a bolt head is provided. Since the means for fixing the plate 5 to the riser 3 does not appear at all, the aesthetic appearance on the surface side of the riser 3 can be improved, which is preferable, as well as each engagement of the riser fixing reinforcing plate 5 It is preferable that it can be firmly fixed by the insertion by the ridges and the action of caulking between the slits of these engagement ridges, and further, spot welding or blasting of the fasteners to fix the riser 3, bolt Since it is not necessary to perform fastening or the like, the production process can be greatly omitted, and it is preferable, and facilities such as spot welding for fixing the cleat 1 and the riser 3 and the fusion of the fasteners are required. This is preferable because the introduction cost of the production equipment can be reduced.

  The riser fixed reinforcing plate 5 fixed to the back side of the riser 3 in such a manner has substantially the same shape and configuration as the fixed reinforcing plate 2 fixed to the back side of the cleat 1 described above. The description is omitted.

  4 is a fixed reinforcing plate 2 fixed to the back side of the cleat 1 for passengers to ride on its front side, and a riser 3 for closing the step or a riser fixed to the back side of the riser 3 for closing the step. Each of the fixed reinforcing plates 5 is a frame to be fixed, and is moved in an oblique direction and a horizontal direction in a state of being connected to a step driving chain in a truss of an escalator.

  As shown in FIGS. 1 to 2, the frame 4 is generally configured in a triangular shape by a cleat support plate, a riser support plate, and a bracket, and a frame frame wheel shaft (not shown). ) And a bearing hole or the like is provided, and is mainly manufactured from an aluminum die-cast material.

  Next, a method for fixing the cleat and the fixed reinforcing plate in the step structure of the escalator according to the present invention having such a configuration will be described. The fixing method for the riser and the fixed reinforcing plate for the riser in the aspect further including the fixed reinforcing plate for the riser is substantially the same as the fixing method for the cleat and the fixed reinforcing plate described below. Omit.

First, an operation of fitting each engagement raised portion 2b of the fixed reinforcing plate 2 to the back surface side of the protrusion 1a of the cleat 1 is performed.
Specifically, first, each engaging ridge 2b of the fixed reinforcing plate 2 is lightly inserted between the inner wall surfaces 1aa and 1aa on the back surface side of each protrusion 1a of the corresponding cleat 1 and positioned. As shown in FIG. 4, the fixed reinforcing plate 2 is fixed until both side surfaces of the engaging ridges 2b of the fixed reinforcing plate 2 are in pressure contact with the opposing inner wall surfaces 1aa and 1aa on the back side of each protrusion 1a of the cleat 1. Further press in the direction in which the cleat 1 contacts.

  Next, as shown in FIG. 4, the slits of the respective engaging raised portions 2 b of the fixed reinforcing plate 2 with the respective engaging raised portions 2 b of the fixed reinforcing plate 2 fitted on the back surface side of the protrusion 1 a of the cleat 1. An operation of firmly fixing the cleat 1 to the fixed reinforcing plate 2 as shown in FIG. 3 is performed by inserting and caulking a bit slightly wider than between 2a and 2a.

  Specifically, for example, a rectangular shape having sides shorter than the slits 2a, 2a of the engaging ridge 2b of the fixed reinforcing plate 2 is formed on both sides, and gradually decreases from the front end to the rear end. Using a bit formed in a shape whose side is slightly wider than between the slits 2a and 2a, the tip of this bit is lightly inserted into the slit 2a and 2a of the engaging ridge 2b toward the cleat 1 side. Then, after positioning, the rear end portion of the bit is hit with a tool or the like to perform a caulking operation.

  At this time, as shown in FIGS. 3 and 5, the portions near the slits 2a and 2a of the engaging ridges 2b of the fixed reinforcing plate 2 are folded toward the inner wall surfaces 1aa and 1aa of the ridges 1a of the cleat 1. At the same time, the bent portions near the slits 2a and 2a further deform the lower edge sides of the inner wall surfaces 1aa and 1aa on the back surface side of the ridge 1a of the cleat 1 to be bent. Since the portions near the slits 2a, 2a and the deformed inner wall surfaces 1aa, 1aa are firmly engaged and crimped, the cleat 1 and the fixed reinforcing plate 2 are stepped in the step traveling direction. Even if a strong load is applied, it is possible to prevent the cleat 1 from being displaced from the fixed position or coming off.

  When performing such an operation, a bit may be driven into each slit 2a, 2a of each engaging ridge 2b as described above, and for example, a plurality of bits may be connected simultaneously. A tool may be prepared, and a plurality of places may be caulked simultaneously with such a tool, and only a plurality of places may be caulked appropriately without performing caulking on each of the slits 2a and 2a of all the engaging ridges 2b. May be.

  Thus, after fixing the cleat 1 to the fixed reinforcing plate 2 easily and reliably, the fixed reinforcing plate 2 fixed to the back surface side of the cleat 1 and the fixed reinforcement for riser fixed to the riser 3 or the back surface side of the riser 3. If the plate 5 is fixed to the frame 4, the step structure of the escalator according to the present invention having a good aesthetic appearance on the surface side of the cleat 1 can be obtained.

It is an isometric view explanatory drawing which shows one Example of the step structure of the escalator which concerns on this invention. FIG. 2 is a partially enlarged cross-sectional explanatory view taken along line AA in FIG. 1. FIG. 3 is a partially enlarged cross-sectional explanatory view taken along line BB in FIG. 1. FIG. 4 is a cross-sectional explanatory view showing a state before crimping between the slits of each engaging ridge of the fixed reinforcing plate in FIG. 3. FIG. 4 is a cross-sectional explanatory view showing a state in which FIG. 3 is viewed from the back side of the fixed reinforcing plate. It is an isometric view explanatory drawing which shows an example of the fixed reinforcement board used for the step structure of the escalator which concerns on this invention.

Explanation of symbols

1 Cleat
1a ridge
1aa Inner wall surface 2 Fixed reinforcement plate
2a slit
2b Engagement ridge 3 riser
3a ridge 4 frame 5 fixed reinforcement plate for riser

Claims (3)

It is made of a metal plate in which protrusions (1a) parallel to the step traveling direction for passengers to ride on the surface side and having a trapezoidal or mountain shape in cross section are formed at a predetermined pitch in a direction perpendicular to the step traveling direction. A cleat (1), a fixed reinforcing plate (2) fixed to the back side of the cleat (1), a riser (3), a fixed reinforcing plate (2) and a riser (3) of the cleat (1) Each with a fixed frame (4),
On the fixed reinforcing plate (2) corresponding to the ridge (1a) of the cleat (1), the opposing inner wall surfaces (1aa, 1aa) on the back side of the ridge (1a) are set in the step traveling direction. A pair of slits (2a, 2a) are provided at a predetermined pitch in parallel to the step traveling direction with a distance connecting in the orthogonal direction, and the cleat (1) side is between each pair of slits (2a, 2a). An engagement ridge (2b) is formed to protrude from the
Each engagement ridge (2b) of the fixed reinforcing plate (2) is fitted on the back side of the ridge (1a) of the cleat (1), and each of the fixed reinforcing plates (2) is further engaged. The cleat (1) is fixed to the fixed reinforcing plate (2) by inserting and caulking a bit slightly wider than the slit (2a, 2a) between the joint ridges (2b). An escalator step structure characterized by The riser (3) is a metal plate riser in which protrusions (3a) parallel to the step traveling direction and having a trapezoidal or mountain-shaped cross section are formed at a predetermined pitch in a direction orthogonal to the step traveling direction. And a riser fixing reinforcing plate (5) fixed to the back side of the riser (3).
In the riser fixing reinforcing plate (5) corresponding to the protrusion (3a) of the riser (3), the opposing inner wall surfaces on the back side of the protrusion (3a) are perpendicular to the step traveling direction. A pair of slits are provided at a predetermined pitch parallel to the step traveling direction with a distance to be connected to each other, and an engaging bulge protruding from the riser (3) side is provided between the pair of slits. And
In the state where each engaging ridge of the fixed reinforcing plate for riser (5) is fitted on the back side of the protrusion (3a) of the riser (3), each of the fixed reinforcing plate for riser (5) The riser (3) is fixed to the riser fixing reinforcing plate (5) by driving in and biting a bit slightly wider than between the slits of the engaging ridges. Escalator step structure.   The engaging ridge (2b) of the fixed reinforcing plate (2) and / or the engaging ridge of the fixed reinforcing plate (5) for the riser are formed so as to form a mountain shape when viewed from the direction orthogonal to the step traveling direction. The escalator step structure according to claim 1 or 2.

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