CS272222B2 - Running strip from elastic material, especially for railing of escalators and railways - Google Patents

Abstract

Handrail is of C-shaped section injection moulded in polyurethane or foamed polyurethane or similar synthetic plastics with a web reinforced by a steel wire insert. One surface is lamellated by transverse grooves while the opposite surface is sinuously shaped with peaks opposite the grooves and the groove bottoms are rounded. The ends of the handrail are provided with attachments to enable formation into an endless loop.

Description

The invention relates. a running belt made of flexible material, especially for railing of escalators and steps, reinforced with an insert and with a C-shaped profile

At present, the railings of the railing are made of rubber in which the reinforcing material is a textile, metal liner or steel strip or various combinations thereof.

For example, it is known to have a rubber railing running belt of a moving track which, in order to drive it with the conveyor belt, is provided with a vulcanized steel insert of appropriate length, engaging the teeth of the wheels.

In another known embodiment, the handrail of the handrail comprises an oel liner to prevent the handrail of the handrail from expanding. This insert is formed of an endless perforated ooel strip, arranged along the rail parallel to the axis of the wheels.

In another known embodiment, a handrail running strip provided with a colored cover plate is reinforced with a cord fabric layer.

It is also known to have a handrail in which a glass fabric insert is incorporated in the rubber material in order to prevent it from expanding and to maintain the tensile force. At the same time, at least the warp of the fabric must be made of glass fiber. Since the glass fabric is poorly adhered, its adhesion increases, especially when forming an endless belt, by joining its cones, with rubberized textile layers usually inserted between the glass fabric.

Another known handrail circulating belt differs from the known embodiments in that it is to be the outer surface is formed for better visibility of depressions, notches, letters or figures.

In the known solutions, the sliding surface of the handrail running belt is mostly of textile.

A common drawback of the known handrail running belts is that in the event of wear on the sliding textile surface, the belts can no longer be repaired and that, due to the construction of these handrails, the neutral layer is embedded in the asymmetric belt, exposing the sliding arms of the C-shaped profile. they contain several components. This results in fatigue of the system, which results in the tearing off of the textile layers.

It is very prone and requires extraordinary precision of the preparatory operations.

In order to reduce the expansion of the handrail belt, the use of structural textiles and wire wires is increasing, but making the handrail belt even more complicated.

According to current practice, in order to achieve the connection of the two ends of the handrail running belt and thus of its infinity, it is also necessary to roughen or roughen the operations.

Gates of the raw rubber mixture, arranged between the molded jointed vulcanizing presses, forming a continuous belt from a linear belt. It is necessary to join the vulcanization at the assembly site. Since the continuity of the individual reinforcement layers is interrupted by the vulcanization of the bonded rubber railings, these points are weak points compared to other parts of the railing runner strip.

SUMMARY OF THE INVENTION It is an object of the present invention to overcome these disadvantages.

The invention is based on the discovery that the use of materials and corresponding physical properties and the creation of a special suitable form of railing can accomplish the intended task.

The object of the invention is based on the object of the invention that the elastic material of which the injection-molding belt is made is a polyurethane or other plastic having a hardness of more than 80 Sh °, at least one outer surface and an inner surface. The Jilooha side leg of the C-shaped profile leg is laminated, the opposing outer and inner surfaces joining the C-leg side leg side are of a wavy lamellar tendency, or one of the ribs is corrugated, the other lamellated, the reinforcing insert being of a jelly wire. The steel wire reinforcement insert, to whose opposite cones the metal fasteners are attached, is embedded in a belt made of polyurethane or other plastic and located in the middle of the C-shaped profile. In another embodiment, the ooel wire reinforcement insert is cast in the middle of the letter-shaped profile. C, external recesses are formed on the side legs of the C-shaped profile and / or internal recesses are formed on the inner surface of the shoulder legs. The outer recesses in the shoulder of the C-shaped profile are formed by spaced-apart spans, the bottom of which forms a section of a circular arc of a given radius in section. B _e C-shaped front legs lying opposite the inner winch They are provided with convex bulges and concave bulges at the height of at least 2 mm at their opposite jaws. A convex recess of the inner recess is formed on the corrugated or opposed lamellar surface connecting surface lying opposite the bottom of the outer recess, forming a section of a circular arc of a given radius in cross-section between successive convex recesses of the inner recess formed on the surface lying opposite the corrugated or embossed surface The circular arches of the bottom of the outer recess and the convex concave of the inner recess are circular sections of concentric circles, with the contact points of the circular arcs defined by the given radius of the convex concave concave of the inner recess and the given radius. the inner recesses form an angle of at least 45 ° with the center of the concentric circles of the given radius of the convex bulge of the inner recess and the outer recess. The larger recesses are greater than the width of the outer recess and the width of the outer recess is greater than the difference given by the radii of the concentric circles of the convex bulge of the inner recess and the radius of the outer recess.

The solution according to the invention has a number of advantages. Lamination of the C-shaped profile increases the flexibility of the handrail running belt. The outer and inner recesses of the C-shaped profile reduce the thickness of the shoulder legs and the connecting surfaces of the running belt. By creating thin-walled concave arcs, the compressive stresses overcome the bending stresses, thereby extending the life of the running belt, and by making the insert stronger, running belts of any length can be produced.

BRIEF DESCRIPTION OF THE DRAWINGS The invention is explained in more detail below with reference to the accompanying drawings, in which: FIG. 1 is a cross-sectional perspective view of an embodiment of the invention; FIG. 2 shows another embodiment also in axonometric sectional view; FIG. 3 is a partially cross-sectional view of the coupling element; FIG. 4 is a partial cross-sectional view of the connecting element shown in FIG. 3; FIG. 5 is a longitudinal sectional view of the handrail running strip of the embodiment of FIG. 2; FIG. 6 shows an embodiment of a conventional belt according to the invention provided with lamellas from the outer and inner sides; FIG. 7 is a section along line A-A in FIG. 5.

^: Figure 1. 2 are axonometric show two different embodiments of the endless belt. The running strip according to the invention has a C-shaped profile. In the embodiment according to bbr. The reinforcement insert 7 is embedded in a belt 17 made of polyurethane or other plastic. This solution is particularly advantageous because by changing the physical properties of the material of the belt 17, it is possible to have a favorable effect on the sliding and friction properties and the service life of the running rail.

The desired stiffness of the runner profile is achieved by increasing the Shore hardness scale to 90 to 95 Sh °. With this solution it is unnecessary to insert other inserts, it is · · -I '

CS 272 222 B2, which reinforces the liner 1 of the multi-wires, while providing the appropriate design and utilization of the properties of the material used to reinforce the insert 1, provides the prerequisites for meeting all requirements.

^S In the embodiment of FIG. 1 Jaouich boěníoh both arms of the endless belt 2 in vnějšíob ploqháoh external recesses whereas the embodiment of FIG. 2, the inner surface of the endless belt 4 is provided with the recesses formed across dolo endless belt. Opposite Sela of the side arms 2 of the conveyor belt, opposite the inner recesses 4 or at least one of these bodies, are provided with convex bulges 6 and concave bulges to produce arcs whose height, at least 2 mm, allows its bending when rolling the conveyor belt and thus shortening the length of the arc 2 of the C-shaped profile. In the embodiment of FIG. 2, the inserts 3 are embedded in the C-shaped profile.

Since the coefficient of friction of the polyurethane surfaces, especially those of foamed polyurethane, is close to the coefficient of friction of the fabric, it becomes unnecessary to coat the sliding surfaces which are in contact with the metal rails with the textile.

The inner surface of the running rails made of polyurethane foam can be roughened after a certain amount of wear and a new polyurethane layer can be applied by injection molding. In this way, the running belt can be renewed and its service life increased.

Since the conveyor belts do not comprise textile inserts, they are provided with reinforcement of the insole 1 and 1, respectively. With the inserts 1 made of ooel wires, it was possible to attach metal fasteners 8 thereto. By means of these metal fasteners 8 it is possible to produce running rails with mechanical joints without any vulcanization.

The running belts according to the invention can be produced in a length corresponding to the particular area of use or in some areas. In the known solutions, the handrail running strips can be cut off at the point of use, and after a complicated preparatory operation they can be joined to the endless belt to the desired length, as indicated, by vulcanization. the impeller belt strength is not reliably ensured.

FIGS. 3 and 4 show an example of the meohaniocular connection of the cones or the individual sections of the treadmill in a top or side view, respectively. The handrail circulating strip made by injection molding is connected with its cone 13 to the edge 12 of the metal closure 8. The metal closure 8 are fastened together by screws 11 and right-hand or left-hand threads. The middle part of the bolts 11 can be formed with a hexagon head and can be simply tightened with a spanner. The screws 11 may also be cylindrical. In this case, it can be screwed and pulled to the holes 10 by means of steel pins.

Access to the screws 11 is ensured by the grooves 2, as shown in FIG. 3.

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The metal fasteners 8 are connected by a treadmill connector 13 by attaching them to the cones of the wire _{4 to} strengthen the insert 1. The steel wires are inserted into the comb holes of the metal caps 8. It is fastened with fastening pins which hammer into the fastening holes 15 perpendicular to the ridge holes so that they bend and wedge between fastening the hole 15 and fastening pins during hammering.

The wires of the reinforcement of the insert 1 can be inserted into the metal closures for a longer time, which is made possible by the recess 14.

The above-described metal joints can be manufactured in any desired length of Binoty series and selected according to the length of the series produced so that any length of the circulation strip can be assembled from one or more sections in place using metal connecting elements.

CS 272 222 B2

The possibility of forming an endless belt by joining the ends of the polyurethane linear portions of the belt with a meohane joint does not preclude the use of other methods of forming an endless belt. Thus, for example, endless running belts can be formed from foam polyurethane at the point of use. In this solution, the polyurethane coating is removed from the carrier wires by reinforcing the insert 1 for a certain period of time on the conveyor belt assembly. they are attached to each other, then inserted into the jointing tool and the folded wire is sprayed with polyurethane foam.

Since the inventive running belt does not comprise a textile insert, the endless belts produced by the method described are less stressed to shear in use, so that the linear belts thus bonded are substantially more durable than the prior art rubber running belts bonded to the endless belts by vulcanizing.

Making Curved ploohý side arms two shaped profile C shown in Fig. 5 »lamellated plooha is formed so that between the projections are in mutual spacing b external recesses 2 ⁰ Zirc and, wherein the spacing b between the outer recess 2 tons i.e. the thickness had The bottom of the outer bead 2 forms a section of a circular arc with a radius r of the determined vibration in cross section. In the embodiment shown in Fig. 5, the outer face of the side arm 2 of the C-shaped profile is lamelled. the inner connecting surfaces of the arms 6 with the concave concavity 6 with the convex concavity 6 facing the lamellar outer part are corrugated. The inner edge of the joining surfaces lies concave with respect to the outer recess 21, each convex, forming a section of a circular arc of a given radius r in cross-section. The circles of radii r1 and r2 are concentrated. Between the outer recesses 2 ^{and e} form protrusions on the outside of the side legs 2 of the C-shaped profiles on the opposite inner side of the side leg 2 of the C-shaped profile of the running belt are concave bulges 2 forming a section of a circular arc of radius r of the circle (Figs. 2, 5, 7). The height of the convex connecting arcs 2 (FIG. 2) formed by the outer recesses 2 ^and opposing concave! 2. bulges in křídám case smaller than the width and won by 2 · Liaison feast určemýoh circle radii r2 ^ ar enclose the middle section connecting the circle of radius r ^ r ₂ · Angle 45 ° 'Fig. 6 shows the embodiment of FIG. 1 in which the side arms 2 of the conveyor belt are laminated both on their inner surface and on their outer surface, i.e. the inner p-position is provided with inner recesses 4 and the outer surface of the outer recesses 2. strengthening the insert 1 arranged in the belt 17.

Fig. 7 is a cross-sectional view taken along line AA of the embodiment shown in Fig. 6. It can be seen from Fig. 7 that the outer recesses 2J ^are formed symmetrically to the inner recesses 4. On each side of the inner recess 4, an outer recess 2f is formed in each case, i.e. one inner recess 4 and two are arranged alternately one after the other. outer recesses 2 <Between two consecutive inner recesses 4, two outer recesses 2 are each formed on the opposite surface.

The same arrangement is, of course, also possible in the embodiment of the conveyor belt of FIG. 2.

However, the railing running strip can also be arranged such that the recesses 21 and 16 are formed alternately on the inner surface and the outer surface.

The sliding surface of the conveyor belt according to the invention may be provided with a metal insert or a plastic insert, reducing the friction between the conveyor belt and the rail or reducing the degree of wear.

Claims (9)

WHENWATHHALLBZU 1. A tread strip of resilient material, in particular for railing of movable tracks and the like, provided with a reinforcement insert and a C-shaped profile, characterized in that the elastic material of which the tread band is formed is polyurethane, foamed polyurethane. or other plastic with a hardness vyěěí 80 SH °, wherein at least ^one vnějěí povrohová surface and the inner povrohová surface of the side arms (2) of the profile is lamellated opposite down-corner internal and an external ploohy spojujíoí Hoen arm (2) profiles are corrugated him lamellar, or one of the ribs is corrugated, the other lamellar, wherein the reinforcement insert (1) is made of ooel wire. 2. The running strip according to claim 1, characterized in that the reinforcing insert (1) of steel wire, to which opposite ends of the metal fasteners (8) are attached, is embedded in a strip (17) made of polyurethane or other plastic; located in the middle of the profile. 3. The running strip according to claim 1, characterized in that the reinforcing insert (1) made of oel wire is cast in the middle of the profile. Orbit according to one of Claims 1 to 3, characterized in that external recesses (3) are formed on its lateral legs (2) and / or on the inner surface connecting surface and inner recesses (2) are formed on the lower surface of the lateral legs (2). 4). 5. The running belt according to claim 4, characterized in that the outer recesses (3) in the lateral shoulder (2) of the running belt are formed at specified spacing (b), the bottom of which forms a circular arc of a given radius (r ^). . 6. The running belt according to claim 4, characterized in that its side arms (2) opposite the inner recess (4) are provided with convex concavities (6) and concave concavities (7) forming arcs (5) on their opposite faces. at least 2 mm. rj Circulating strip according to one of Claims 1 to 6, characterized in that a convex bulge (6) of the inner recess (4) forming a circular section of a circular arc of the circle is formed on the corrugated or opposed laminated surface connecting surface lying against the bottom of the recess (3). of a given radius (r ^), between the consecutive convex concavities (6), a concave concavity (7) is formed on the surface against the corrugated nobo-lamelled surface, the concave concavity (7) of the inner recess (4) forming a circular arc section the radius (r ^). Circulating strip according to claim 7, characterized in that the circular arcs of the bottom of the outer recess (3) and the convex bulge (6) of the inner recess (4) are circular sections of concentric circles, wherein the tactile rounds of the circular arcs determined by a given radius (rg) The concave bulge (7) of the inner recess (4) forms an angle of at least 45 ° through the center of the concentric circles of said radii (r, rg). Circulating belt according to claim 7, 8, characterized in that the pitch (b) between the outer recesses (3) is greater than the width (a) of the outer recess (3) and the width (a) of the outer recess (j) is greater than radius difference (rg - r ^) of concentric circles.