FR2527301A1 - Forming expandable bellows filter - by forming cylindrical tube filter, sealing inside, expanding to deform tube and removing seal - Google Patents

Abstract

Method of mfg. an expandable bellows filter comprises (a) selecting a cylindrical filter tube; (b) placing inside the tube an expansible sealed element; (c) submitting the sealed element to internal pressure to expand and deform the tube; (d) forming on the tube, waves perpendicular to the tube axis by deformation against a series of moulds applied during the course of expansion of the sealed element, and closing the moulds together along the length of the tube; (e) removing the pressure and (f) the sealed element. The filter is esp. for filtering high pressure steam at high temp. The method overcomes the prior art problems of forming a wave form on the side of a tube and producing a deformation of a fine metal foil which is highly stretched into a wave form.

Description

 The present invention relates to a filtering expansion bellows, in particular for filtering steam at high pressure and at high temperature, as well as a method for forming such a bellows.

We already know the expansion bellows
intended to absorb expansions, vibrations, misalignments in pipes and fluid lines. These bellows, used mainly in the steel and petrochemical industries. nuclear energy or in heating installations have two essential characteristics. First of all, they are waterproof, generally made of metal or elastomer. Then they are provided with expansion waves perpendicular to their axis. They are often obtained from a sealed, starting tube which is subjected to expansion by hydroforming for the formation of waves.

 Metallic fabric filters are also known, comprising mesh voids. Filters of a generally pleated tubular shape have even been proposed, provided with waves parallel to their axis, intended to increase the filtering surface. The formation of these waves parallel to the axis of the tubes or folds, does not pose any difficulty, it is obtained by feeding in metallic fabric.

 On the other hand, obtaining waves perpendicular to the axis of a tube at the filtering start poses a priori a pressing problem.

 In addition, the threads of a metallic fabric being very thin and strongly stretched, the deformation of this fabric to obtain perpendicular waves poses a second problem.

 The present invention aims to solve these problems and therefore to provide a filtering expansion bellows.

 To this end, the present invention relates first of all to a process for forming a filtering expansion bellows, characterized in that a filter tube is taken in cylindrical form, an element is placed inside the filter tube waterproof extensible, the sealed element is subjected to an internal pressure to expand it and thus deform the filter tube, the pressure is released and the sealed element is removed.

 Thus, thanks to the method of the invention, the deformation of the filter tube, which is not leaktight, is obtained by the introduction of a sealed inner element forming with the tube to be deformed, an assembly that is also leaktight and can therefore be deformed by pressure.

 In a preferred implementation of the invention process, the waves of the bellows, perpendicular to the axis of the initial filter tube, are obtained by deformation against a series of molds which are brought together during the expansion of the sealed element.

 This mutual approximation is advantageously obtained between a fixed shutter plate and a movable shutter plate which is moved by a jack.

 In this case, the initial axial distance between two neighboring molds is equal to the developed length of the waves to be formed.

 In the case where the filter tube is made of fabric, preferably metallic, either a woven fabric with warp and weft threads, or a nonwoven fabric with warp or weft threads arranged on a filtering support, forms the initial cylindrical filter tube by cutting from the fabric a rectangular flank with sides inclined substantially at 450 on the threads of the fabric. In this way, and although these wires can practically not be stretched, the waves are obtained by deformation of the voids.

 The present invention also relates to a filtering expansion bellows, of generally tubular shape, characterized in that it comprises expansion waves perpendicular to the axis of the tube.

 In a preferred embodiment of the invention, the bellows is made of fabric, advantageously metallic, but any other mechanically inert material would also be suitable, and the threads of the fabric are inclined at 450 on the generatrices of the tubular bellows.

 Of course, the bellows of the invention can also be knitted or can also be obtained by braiding the threads.

 The bellows may include one or more thicknesses of fabric.

 The bellows of the invention also has two particular advantages.

 Thanks to the very small thickness of the fabric threads, it is very flexible and in any case much more flexible than a bellows made of solid material.

 Thanks to the waves perpendicular to its axis, it can be unclogged by compression of the waves, which cannot be done with parallel waves.

The invention will be better understood with the aid of the following description of the method of forming the bellows of the invention and of two embodiments of this bellows, with reference to the appended drawings, in which
- Figure 1 is a view of a starting sieve
- Figure 2 is a simplified perspective view of a starting tube
- Figure 3 is a simplified partial sectional view of the wave formation device of the bellows of the invention, at the start of the wave formation process
- Figure 4 is a view of the device of Figure 3 during an intermediate phase of the wave forming process
- Figure 5 is a view of the device of Figure 3 at the end of the wave forming process
FIG. 6 is a view of a first embodiment of the filter bellows of the invention, and
- Figure 7 is a view of a second embodiment of the bellows of the invention.

 We start with a metallic fabric, or sieve, 1, with warp threads 2 and weft threads 3. We cut in fabric 1 a rectangular sidewall 4, with sides 5, 6 inclined at 450 on the threads 2 and 3 of the fabric 1. The flank is wound on itself around an axis parallel to the short side 5 of the flank, to obtain an initial tube 8 with two thicknesses of fabric, of axis 7. The wires 2, 3 of the wound fabric remains inclined at 450 on the generatrices 9 of the tube 8. The height of the tube 8 is equal to the length of the side 5 of the sidewall 4 and the circumference of the tube is equal to the length of the long side 6 of the sidewall 4, divided by the number of thicknesses, in this case two.

 Take the tube 8, and place inside an air chamber 10, made of elastomer, also substantially cylindrical, with a diameter slightly smaller than the inside diameter of the tube 8. Instead of the chamber 10, any other could be placed. expandable waterproof element. A series of molds 11, of generally circular shape, and regularly spaced so that the distance between the median planes of two neighboring molds is equal to the developed length of the waves to be formed, are placed against the outer surface of the tube 8. The intermediate molds actually have a median plane of symmetry while the two opposite end molds in fact only correspond to an intermediate half-mold. The molds 11 are initially kept spaced apart by spacers 12, coaxial with the tube 8 and the chamber 10.

 The assembly formed by the chamber 10 and the tube 8 is closed off by a fixed plate 13 and a plate 14 arranged to be moved and brought closer to the plate 8 by a jack, not shown.

 The sealed assembly (10, 8) is then subjected to an expansion by an internal pressure which is created through the fixed plate, for example. The assembly begins by expanding or bulging convexly between the molds 12. The spacers 12 are then removed, the molds 11 remaining held by the bulges of the assembly. Then, the expansion continuing, the actuator is actuated to bring the molds 11 closer to one another.

 By deformation, or buckling, against the molds 11, waves are formed perpendicular to the axis 7, waves which, at the end of the process, are limited to the volumes comprised between the molds in contact with each other and follow their walls.

 The pressure inside is then canceled and, the chamber 10 having resumed its initial shape> all that remains is to remove it as well as the molds 11 to recover the filter bellows, with its waves 15 perpendicular to its axis 7 .

 We can easily understand the utility of the particular cutting of the sidewall 4 in the fabric 1. In fact, at the level of the waves, the diameter, or the circumference, of the bellows is larger than between the waves where the diameter is that of the tube. of departure. Let us consider the meshes, or the voids of mesh, of a circumference orthogonal to the axis of the tube. At the start, these are small squares with diagonals respectively parallel and orthogonal to the axis of the tube. If we transform these small squares into diamonds and then into flat diamonds, along the circumference considered, the length of the diagonal orthogonal to the axis will become equal to twice the length of the sides of the starting squares, i.e. - say greater than the starting orthogonal diagonal. This is how we can explain the increase in the circumference of the starting tube at the level of the waves.

 The embodiment 8 ′ of the bellows of FIG. 7 differs from that 8 of FIG. 6 only in that the starting sieve is not made of fabric but a sieve obtained by braiding of threads.

 We have just described a filtering expansion bellows and its formation process consisting of a metal screen.

It is understood that this is not a limiting characteristic of the invention and that a sieve made of any other inertemechanically material, that is to say a material which does not regain its shape, could be used initial after a deformation, or else, not elastic.

 It is also possible to have, parallel to the axis of the bellows, in the starting material, reinforcing wires.

 Although the present invention relates very particularly to a filtering expansion bellows, it may be advantageous to transform it into a sealed or non-filtering bellows. It is indeed very easy to coat this filter bellows, inside or outside, with a layer of rubber, PVC, silicone or other similar waterproof material, and thus obtain a much more flexible bellows than those that could be obtained with solid materials, thanks to the fineness of the starting sieve.

 Finally, and in the same vein, we may want to replace the expandable chamber with an inert non-elastic chamber and leave it inside the starting screen, after the formation of waves, always to obtain a conventional bellows but particularly flexible, including the sieve and the chamber whose shapes fit together.

Claims (13)

Claims  1.- A method of forming a filtering expansion bellows, characterized in that a filter tube is taken in cylindrical form (8), an expandable waterproof element (10) is placed inside the filter tube, subjects the sealed element to an internal pressure, to expand it and thus deform the filter tube, the pressure is released, and the sealed element is removed.  2.- Method according to claim 1, in which waves (15) are formed on the filter tube perpendicular to the axis (7) of the tube (8) by deformation against a series of molds (11) which are brought together. each other during the expansion of the sealed member.  3. A method according to claim 2, wherein the molds (11) are brought close to each other between a fixed shutter plate (13) and a movable shutter plate (14) which is moved by a jack.  4.- Method according to one of claims 2 and 3, wherein the initial axial distance between two neighboring molds is equal to the developed length of the waves to be formed.  5.- Method according to one of claims 1 to 4; wherein, to form the starting cylindrical filter tube, dn cut from a fabric (1) a rectangular flank (4) with sides (5,6) inclined substantially at 450 on the threads (2,3) of the fabric.  6.- A method of forming an expansion bellows, characterized in that a cylindrical screen is taken, a mechanically inert waterproof element is placed inside the screen, the sealed element is subjected to an internal pressure to thus expanding and deforming the assembly, and the pressure is canceled.  7.- Filter expansion bellows of generally tubular shape, characterized in that it comprises expansion waves (15) perpendicular to the axis (7) of the tube (8).  8.- Bellows according to claim 7, characterized in that it is made of fabric (1) and the threads (2,3) of the fabric (1), are inclined substantially at 450 on the generatrices of the bellows (8).  9.- Bellows according to claim 7, characterized in that it is formed in a sieve obtained by braiding son (8 ').  10.- Bellows according to claim 7, characterized in that it is formed in a knitted fabric.  11.- Bellows according to one of claims 7 to 10, characterized in that it comprises several thicknesses wound on each other.  12.- Expansion bellows, characterized in that it comprises a filtering expansion bellows according to one of claims 7 to 11 coated with a layer of a waterproof material.  13.- Expansion bellows, characterized in that it comprises a filtering expansion bellows according to one of claims 7 to 11 formed in a sieve and, inside the sieve, a mechanically inert sealed element conforming to the shape of the sieve .