PL43367B1 - - Google Patents

Description

Published on August 31, 1960 AT ASA \ 9 OF THE POLISH PEOPLE'S REPUBLIC PATENT DESCRIPTION No 43367 Wladyslaw Kubica Bielsko-Biala, Poland Adam Kubica Wroclaw, Poland KI. 86c, 1/30 Carcass for conveyor belts and belts The patent lasts from October 10, 1959. Conveyor belts made of rubber or other plastics consist of a base called a "carcass", made of a durable material, because the task of the carcass is to take over The force from the belt drive and the force from the loads carried by the masses transferred on the belt, which places particular requirements on the structure of such a carcass. Commonly used fabrics for warp conveyor belts, most often in the form of a set of fabrics glued together with a layer. warp is high cost and limited in strength. In some cases - especially for high loads - the layers of the warp fabric are replaced by one or more layers of cords, as well as steel cords, running parallel alongside each other along the entire length of the tape. or its length. The main disadvantage of such a warp is the difficulty in ensuring the necessary equal tension in the individual strings or lines. both during the production process of the tape and in the case of subsequent joining or possible replacement of damaged sections. The use of metal wire meshes, of various commonly known constructions, for the warp conveyor belts, did not give satisfactory results, mainly from Due to insufficient flexibility and high sensitivity of the meshes to local deformations. The present invention describes a warp construction adapted to the specific requirements resulting from the operating conditions of the conveyor belts and related pedestals. The figures illustrate, for example, the carcass structures according to According to the invention, the matrix according to the invention is made of checkerboard repeating elements in the form of links, the perimeter of which is made of multiplied thin wire and shaped in the side view to resemble an elongated eight or a multiple figure eight. Checkered-matrix structure according to the invention, elements, repetitive h 0, for the sake of simplicity hereinafter referred to as "Links", is shown schematically in the plan view in Fig. 1. The length of the straight warp section, or its circumference in the "endless" connection, is a sum of an arbitrarily determined the length of the links, and the warp width - which determines the width of the conveyor belt - is the sum of the widths of an arbitrarily determined number of cells arranged next to each other. The term "multiplied thin wire" means both a greater number of thin wires bonded with each other in any way for example by twisting into a line, as well as multiple winding around the circumference of the link of one longer section of wire. Both these types of cell circuit design are present in the matrix examples described in the present invention. The warp wires may be of any material, such as steel, plastic, or other suitably strong material. The octal form of a link in the matrix in the side view is shown in FIG. 2, and the shape of a multiple eight is shown in FIG. 4. In the cells shown in FIGS. 2 and 4, the multiplied thin wire is for example a strand. The octal-shaped link in the side view consists of looped bends 1 and the straight lines 2 crossing each other. In the length of the link shown in Fig. 2, between the abdominal bends 1 there is only one intersection of the straight lines 2, thus forming a single elongated eight. In the length of the link shown in Fig. 4, between the abdominal bends 1 are woven into the circumference of the W thread link, as a result of which these parts of the link circumference intersect multiple times, thus forming the shape of a multiplied figure eight. a plan view of the same section of the warp is shown, the side view of which is shown in FIG. 2. Links 0, one of which has been curved with a thick line for convexity, look like a zigzag when viewed from above, with an amplitude equal to the length of the link. The number of zigzags in the link and their scale, which constitute the width of the link, can be any. Fig. 5 shows a top view of the same section of the warp, the side view of which is shown in Fig. 4. The top of this warp, in relation to the warp shown in Fig. 3, consists in the fact that along the length of the link 0, any number of threads W are interwoven between their end bends 1, thanks to which the warp obtains a reinforcement of the transverse strength. The W threads should be suitably strong and flexible at the same time, preferably made of a round or flat oval cord. Moreover, the threads W may have stiffened ends and have threaded protective sleeves, similarly as described below for the Z-pin. 0 For the checkerboard connection of the links 0 in the warp, their loop-shaped bends are used. may be done in any known manner, preferably hinged by a flexible split pin Z, as exemplified in the drawing. Figure 6 shows an example of a Z-clip specially adapted to perform the warp-lacing role of the invention. this is made in the form of a flexible cord 3, the ends of which 4 are stiffened over a certain length, for example by soldering or fusing the cord wires into a uniform whole. The split pin is strung with short T-sleeves, which, without losing its flexibility, ensure the location and adherence to it of the edge bends of 1 links 0. The T-sleeves may have the outer surface of the ring grooved, as shown in the picture, or may also be smooth. Fig. 7 shows the special protection of the looped bends 1 in the links 0 by means of a horseshoe-shaped washer P, free ends with protrusions 5 for folding in order to clamp and immobilize the washers P in Figures 8 to 10 show examples of links 0, made of one longer section of wire wound many times around the circumference of the link. Fig. 8 shows a link in the form of a double-sided loop, consisting of loop-like ends 1 and connector 6. Such a link is made of one wire, repeatedly wound on an oval skein, the wire then twisted around its elongated axis. to form the connector 6, leaving the loop ends untwisted 1. In FIG. 9, an axonometric view illustrates an example of a twisted pair made of flat wire with a rectangular cross section. In this example, one section of wire is wound multiple times in such a way that it forms as if two circuit circuits of the link, placed side by side and connected to each other by only one outer turn 7 of the wire. With this method of winding, the ends 9 of the twin wire are on the inside of the circuits, one end at one end and the other end at the other partial circumference of the link. The twin link circuits are braided in any odd number of threads that make up the link. in side view multiple eight figure. In addition, the circumferences of the twin link are shaped in such a way that their left-hand lap edge bends 1 abut against each other at one end of the link, while at the other right end, the links are spaced a certain distance from each other. The end of one link with adjoining edge bends 1 may be inserted between the flared end bends of the other link. Fig. 10 shows the section of the carcass according to the invention, formed from the twin links 0. 9, which are connected to a tape by the split pin Z. One link in this figure has been highlighted in black for bulging. An example of another variant of a matrix link according to the invention, a so-called multiple lamellar link, is shown in view from above, fig. 11. A characteristic feature of this link is the creation of one closed circuit of a multiplied wire of any number connecting with each other in a shape similar to twin links. The closed circumference of a multi-pinned cell can be made either from a larger number of thin wires combined with each other, e.g. by twisting into a line or it can be made of one wire repeatedly wound circumferentially. In the first case, the link circuit is closed by joining both ends of the cable together in one place. In the second case, the circuit is immediately closed with the multiple winding of the wire, and the two free ends of the wire that are present do not even have to be joined together, because it is enough for the link to be on the inner side of the bend bends. made of repetitive elements, it enables its easy production while maintaining the highest accuracy, which is indispensable for ensuring the correct, even distribution of stresses over the entire width. The octal shape of the cell's circumference provides the matrix with the high flexibility required. According to the invention, in conveyor belts and belts made of warp, no additional stresses may arise when working with bends on the drums and "on the battles supporting the drive, because the 2 eights crossing each other always remain equal. 0 links enable easy and reliable joining of sections in length without end, as well as the replacement of damaged sections of the belt. The matrix, which is the basis for the production of conveyor belts and drive belts, can be used in a naked state, protected with anti-corrosion coatings or filled with and covered with rubber or any other material PL

Claims (4)

1. Claims 1. A warp for conveyor belts and belts, characterized by the fact that it is made of chessboard-connected repeating elements in the form of links (Figs. 3, 5, 10), made of multiplied thin wire and shaped in the likeness of an elongated single or multiple eight. 2. The matrix according to claim and characterized in that it consists of cells having a zig-zag shape when viewed from above (FIG. 3). 3. The matrix according to claim 4. The apparatus of claim 1, characterized in that it is formed of cells in the shape of a bilateral petiya (FIG. 8). 4. The matrix according to claim 5. A matrix according to claim 1, characterized in that the fcg is formed from the cgrtf of the cgrtf closely related to: ... ",". 5., A matrix ... according to claim 1, characterized in that it is made of reconnecting cells (Fig. 11). $. The warp according to the sasters 1--5,;, is of the shape, that it has welded in flexible threads of a round-oval-section wire, (7. The warp according to claim 1 ^ 6, characterized by in the fact that the abdominal bundles (1) have a washer in Jwztajeie (P. 8. Warp according to claims 1 ~ * 7, characterized in that the lawleez (Z), which is shifted to its production, has stiffened ends (ii 9. The matrix according to claims 1-8, characterized by iyn% and the pin | Z) are slipped into the end caps (T). Wladyslaw Kubica Adam Kubica 1 l,! \ /) .1_ '^' S '^' Ss ^ - j * (- '^ • A' s ¦ "¦¦ - '* ^' 7 - r:). fi V f * z * Yg. 2 2 4" To patent specification No. 43367 Sheet 1To patent specification No. 43967 Sheet 2 im • in ^ * * PL