FI80092B - Procedure for creating an endless process belt and endless process belt - Google Patents

Abstract

To produce an endless process belt (1), a spiral wire (3) is attached to each end of a piece (2) of process belt woven in the usual way. The spiral wires (3) and the piece (2) of the process belt woven in the usual way are joined together by cutting finger-like projections in the edge of each piece (2, 3) that pass between one another, preferably in the shape of a triangle, and the pieces (2, 3) are fixed to one another by being filled at the edges and in nearby areas with binding material (6), that can be glue, resin, plastic or another material suitable for the purpose. From the process belt piece (2) equipped with spiral wires (3) at either end and woven in the usual way, an endless process belt (1) is formed by joining the spiral wires (3) using a normal spiral wire connection. In order to keep the process belt's (1) permeability largely unchanged, the spiral wires (3) can be filled out with different filler wires and similar.<IMAGE>

Description

1 80092

A method of forming an endless process belt and an endless process belt

The invention relates to a method for manufacturing an endless process belt, in which the ends of a woven belt piece are joined at their edges by at least one helical wire body formed of a plurality of helices, each end of the woven belt body being joined to at least one a spiral wire piece between the ends. The invention further relates to an endless process belt formed by a woven belt body and at least one helical wire body formed of a plurality of helices between its ends, connected to connect the ends of the belt body to each other, each end of the woven belt body being connected to at least one helical wire body body. used for various purposes e.g. as filter cloths to remove solids from various liquids and as conveyor belts in various industries. For such a purpose, process belts are generally mounted on various drums and cylinders 25 to provide a continuously operating filter. In filter wire operation, the process belt is required to be able to be installed and removed without dismantling the entire equipment and also in a relatively short time. Therefore, the process belts intended for this use are made in the form of seams, so that they can be threaded into place and joined into a single endless belt only in place.

Process belts are conventionally made by weaving a belt of a desired width and length of a suitable material and fabric, which is then joined together at opposite ends. Conventional process belt butt joints have been used to make the connection, with the loops at the ends of the belt or the spirals attached to the ends of the belt being attached to each other by means of a seam thread. Furthermore, a rat-5 strip is used to connect the ends, in which the ends of the process belt are bent twice and steel hooks or a spiral are attached to them, which are then correspondingly fastened to each other with a seam wire. The disadvantage of these fastening methods is that in the production of shrink wires for each application a belt blank of exactly a certain length and, on the other hand, for weaving technical reasons, must be made in order to obtain a process belt of suitable size for joining its ends. This, in turn, results in difficulties in both manufacturing and production planning, as well as a loss of capacity when weaving belts narrower than the maximum width of the machine. A further disadvantage is that in order to keep the customer service at a sufficient level, several process belts of different sizes have to be kept in stock, which thus bind capital and take up 20 storage spaces. In addition, the seam structures wear faster than other fabrics, and seams thicker than the actual process belt make operation difficult.

The object of the present invention is to provide a method for manufacturing an endless process belt which avoids the above-mentioned disadvantages and which makes it possible to produce a process belt which can be easily applied to different lengths, the length of which can be selected only after the final application. According to the invention, this is achieved by forming protruding projections on the interlocking edges of the woven belt piece and the helical wire body to be connected thereto so that the protrusions, when substantially flush with each other, form a substantially continuous belt layer with substantially adjacent edges and 80092, the woven belt body and the spiral wool body are joined together by securing them at their edges within the fabric of both the woven belt body and the spiral wire body with a flexible fastener, such as an adhesive or the like, extending substantially the entire thickness of the resulting process belt 5.

The essential idea of the invention is to attach to each end of a conventionally woven process belt by gluing or in a similar manner a substantially spiral wire piece of process belt thickness, the length of which in the longitudinal direction of the finished process belt can be selected as desired. In this case, the endless process belt is formed by connecting the spiral wires at its ends to each other either directly or, if the overall belt 15 is too long for the purpose, first removing the excess spiral wire portion and then connecting the remaining spiral wire ends together in a conventional manner. The advantage of the invention is that with this method a conventional process belt 20 can be woven for all purposes at the maximum width of the machine and when forming the actual final process belt it can be cut from a standard width belt according to the required length and width and further using as a connecting piece at both ends of the process belt one standard size process belt can be used for several different sized devices just by changing the length of the process wire. In this case, only a few standard-sized belts can be manufactured, which can also be kept in stock at a lower cost and 30 more can only be made if necessary. To obtain sufficient strength of the adhesive or other bonding seam, finger-like protrusions are cut in both the woven process belt and the helical wire, which are shaped so that when the ends of the pieces are placed against each other, the protrusions rotate against each other. In this case, when the 4 80092 pieces are glued to each other at their edges, the stress of the adhesive joint is evenly distributed over a large area and is thus sufficiently durable.

It is a further object of the invention to provide an endless process belt which can be easily adjusted to different lengths as required and which is easily economically manufactured and is characterized in that projecting projections are formed at the interconnected edges of the woven belt body and the helical wire body connected thereto. when substantially protruding from each other, the protrusions form a substantially continuous belt layer in which their edges are substantially adjacent to each other and that the woven belt body and the helical wire body 15 are joined together by securing them at their edges substantially the entire thickness of the formed process belt and the woven belt body. with a travel-extending flexible adhesive such as glue or the like.

The essential idea of the invention is that a spiral wire of substantially the same thickness as the woven process belt is joined to both ends of a conventionally woven process belt body by glue or the like, whereby the final endless process belt can be made by joining the spiral wires together in a manner known per se. In order to make the joint sufficiently durable, both in the woven belt piece and in the spiral wire piece, the edges 30 are preferably formed at their ends by cutting finger-like protrusions which, when the pieces are placed flush with each other, rest against each other. When the edges are glued together so that glue or the like fills the fabric of both the woven belt piece 35 and the spiral wire piece at least some distance from the edges of the process belt into the fabrics, in the simplest embodiment at least the entire length of the protrusion joint strength 5 sufficient. The advantage of the invention is that the actual woven process belt blank can in all cases be made as wide as possible using the full capacity of the machine and can be cut in either direction with respect to the woven belt in any direction according to the required width and length without deteriorating its performance or connection properties. Furthermore, by using spiral wires as connecting parts, the length of the final endless helical belt to be formed from the blank can be made different in different situations, whereby a process belt blank of a certain width is suitable for several different applications simply by changing the length of the helical wire section.

The invention is described in more detail in the accompanying drawings, in which Figure 1 shows an endless process belt made by the method according to the invention, Figure 2 shows in more detail the connection of a conventional woven wire and a spiral wire piece and Figure 3 shows the connection of Figure 2 in cross-section.

Figure 1 shows a process belt 1 formed by a conventionally woven process belt body 2 and helical wire pieces 3 connected to its ends. In order to join the spiral wire pieces 3 and the process belt piece 2 made of conventional fabric to each piece 2 and 3, 6,80092 interlocking finger-like, preferably triangular projections are cut which fit well into each other when the wire pieces are placed at the ends as shown in Fig. 2.

Figure 2 shows in more detail one way of making a finger joint, although it can be done in other ways. The conventionally woven process belt body 2 has cross-woven yarns 2a and 2b, and the process belt body 2 can be cut from the woven process belt 10 in either its longitudinal or transverse direction. Triangular projections are cut in the body belt body 2 to form a finger joint. The helical wire piece 3 in turn has helices 3a and connecting wires 3b and triangular projections are cut in the spiral wire body 3 in a manner corresponding to the shape of the woven belt piece 15 so that the spirals 3a and connecting wires 3b are transverse to the intended direction of the process belt 1. The process belt body 2 and the helical wire body 3 are placed end-to-end in the same plane so that the triangular protrusions rest on each other and form a substantially uniform process belt structure or layer. The pieces 2 and 3 are then fastened to each other by filling the fabrics of both pieces 2 and 3 from the area of the triangular projections and some distance from them with a suitable fastener 6, which may be an adhesive, resin, thermoplastic or other suitable material. In this case, the connecting material 6 binds the edges of the conventionally woven process belt body 2 and the helical wire body 3, and thus the pieces 2 30 and 3, together and forms a unitary process belt body. In order to strengthen the joint, a support fabric 7, which may be a thin fabric or other suitable fabric, can still be attached to one or both surfaces of the joint with the same or different jointing agent 6.

When the spiral wire body 3 is substantially the same thickness as the body 2 of the conventionally woven process belt as shown in Fig. 3, a process belt of substantially uniform thickness is obtained as a whole, the operation of which is appropriate and which lasts considerably longer than usual.

In order to form the actual endless process belt, the helical wire pieces 3 are fastened to each other by means of a conventional spiral wire joint 5 known per se, the helical wire pieces 3 forming a practically uniform helical wire body between the ends of the conventionally woven process belt body 2. In order to keep the permeability or filtration capacity of the process belt 1 substantially the same throughout its length, the gaps between the spirals 3a of the helical wire body can be filled with different filler yarns fully known per se and thus also have a permeability corresponding to the process belt 2 conventionally woven. In the area of the finger joint 4, the permeability can be improved by shaping holes in it or attaching triangular pieces to each other, for example by a seam conforming to the shape of the edges of the triangles, whereby the seam and the joint 6 would cover a much smaller area. On the other hand, in some applications, considering the permeability of the entire process belt, the marking of the seam area 4 is almost non-existent and thus often does not require more specific embodiments.

The method according to the invention and the process belt obtained by it have several advantages over previous solutions. The process belt can first be produced in certain constant widths with a predetermined amount of helical wire 3 at both ends. In this case, the installation of the process belt is quite simple, since it can be threaded in place at one end and the ends fastened to engage the endless process belt ai-35 only after this. The formation of process belts of different lengths suitable for different purposes is simple simply by removing or increasing the length of the helical wire pieces 3 and can be done by installing the process belt, whereby the process belt 5 is made of a length suitable for exactly each purpose. Since the connection does not require a special longitudinal direction from the conventionally woven process belt piece 2, but the connection can be made in both yarn directions, the process belt does not need to be woven in a certain direction, but can be cut from pre-woven standard-width process belt pieces in both transverse and longitudinal directions. can be utilized and the woven material can be used efficiently especially when the width is dimensioned taking into account the 15 most common process belt sizes in use when designing the weave. Furthermore, by using separate pieces of helical wire as connecting pieces and in making the joint, cumbersome connecting parts and the additional wear caused by them are avoided, since the joint has the same structure as the corresponding portion of the process belt around it.

An embodiment of the method according to the invention and the process belt formed by it have been described above. However, the invention is in no way limited to these examples, but can be freely modified within the scope of the claims. For example, in the manufacture of longer process sleeves, one may be formed from two or more individual process belt sections, with the individual process belt pieces being joined together in a manner similar to 30 single process belt bodies to form an endless process belt. Not only triangular but also other shaped fingers can be used in the finger joint, and the joints can be joined either by supplying glue or the like to the finger joint 4 or by pressing a strip-like joint at a suitable temperature from one side or molen of the process belt 1 into its fabric structures. The helical wire pieces 3 can be either the same length or different lengths, and each can only be so long that the other spiral can be attached to it by a normal helical connection, whereby the actual process belt blank consists only of conventionally woven process belt body 2 and both of a helical wire body 10 acting as a connecting means, and the final process belt 1 is formed by joining to the helical wire bodies 3 a separate helical wire body of suitable length to form a helical wire of the desired length.

Claims (6)

A method of producing an endless process tape (1) in which the process of finding a web piece (2) produced by weaving is joined at opposite ends by At least one of a plurality of coils (3a) made of coil wire (3) wherein each end of the woven ribbon piece (2) is joined at At least a spiral wire piece (3) and wherein the endless processing strip (1) is made of the woven ribbon piece (2) and At least one of its ends located a spiral wire piece (3), n-characterized therefrom, that at the edges of the woven band piece (2) and the coil wire piece (3), which are joined together, are formed into each other extending projections such that the pieces are arranged in substantially the same pane with the projections in each other, forming they have a substantially uniform strip layer, wherein said edges are substantially tangential to each other and - that the woven band piece (2) and the spiral wire piece 20 (3) are joined together by their edges being secured to each other by means of a woven band piece (2) ) and the fabric of the spiral virus piece (3) substantially over the entire thickness of the process band (1) to be formed, a stretching elastic adhesive (6), such as glue or the like. 2. A method according to claim 1, characterized in that at each end of the woven band piece (2), a spiral wire piece (3) which is substantially as wide as the band piece is attached, and that the endless process band (1) is formed by joining the spiral wire pieces (3) at each end. 3. A method according to claim 1, characterized in that each end of the woven strip (2) is joined to the same spiral wire piece (3), the width of which is substantially the same as that of the strip. 4. A method according to claims 1-3, characterized in that the length of the process band (1) is controlled as desired by changing the number of coils (3a) into at least one coil wire piece (3). Endless process band (1) formed by a woven band piece (2) and At least one of a plurality of spirals (3a) formed by a spiral wire piece (3), each end of the woven band piece (2) being joined to at least one spiral wire piece (3) and wherein the endless process band (1) is formed by the woven ribbon piece (2) and At least one spiral wire piece (3) located between its ends, characterized therein - that in the joined edges of the woven the band piece (2) and the spiral wire piece (3) connected thereto have been formed into mutually extending projections such that, when the pieces are arranged in substantially the same pane with the projections in each other, they form a substantially uniform band layer, their edges substantially tangent and that the woven ribbon piece (2) and the spiral virus piece 20 (3) are joined together by securing their edges to each other substantially over the entire thickness of the formed process strip (1) and within the bed of the woven ribbon piece (2) and The tissue of the virus piece (3) is stretched elastically by an elastic adhesive (6) extending into the tissue, such as glue or the like. Process band (1) according to claim 5, characterized in that at each end of the woven band piece (2) is attached a spiral wire piece (3) which is substantially as wide as the band piece, and that the endless process band (1) is formed by joining the spiral wire pieces (3) at each end.