FR2897784A1 - Filter for tubular chamber, especially of air conditioning circuit condenser, is supported by steel spring strip in flexed and pre-stressed configuration - Google Patents

Abstract

A filter, for installation inside a chamber (14) with a tubular wall (12), comprises a body (26) supported in a selected axial position in the chamber by a spring steel strip (38) in a flexed and pre-stressed configuration. The strip is attached by a toothed aperture to molded a projection (36) on the body of the filter, with its ends (40) pressed against the internal walls of the chamber, its length at rest being greater than the internal dimension of the chamber.

Description

Filter for tubular tank, in particular for a heat exchanger

heat

  The invention relates to a filter adapted to be installed inside a tubular wall tank, and comprising a filter body and holding means arranged to hold the filter in a chosen axial position in the tank.

  It is known filter bodies having at least one seal or a clean sealing lip to bear tight against the tubular wall of the reservoir. Thus, when the filter is installed in the tank, it defines in the latter an upstream zone for a fluid to be filtered and a downstream zone for the filtered fluid.

  Two fluid access orifices at different heights or axial positions, namely an inlet opening into the upstream zone and an outlet opening opening into the downstream zone, are then provided in the tubular wall of the reservoir.

  In one application of the invention, the tank is associated with a heat exchanger, in particular an air-conditioning condenser, for motor vehicles.

  In this particular application to an air conditioning condenser, the inlet orifice receives a condensed refrigerant fluid which opens into the upstream zone of the reservoir, is then filtered, then gains the downstream zone, and finally leaves the reservoir through the orifice. outlet to reach a part of the condenser where the coolant is subcooled.

  For this, the tank inlet port communicates with a last condensation pass of the condenser tube bundle, while the outlet port communicates with a subcooling pass of the tube bundle.

  It is therefore essential that the filter can be maintained in a selected axial position in the tank to be able to properly perform its filtration function.

  When the tank is closed by a removable cap, the filter can be integrated in this cap, which ensures correct axial positioning of the filter when the cap is in place. However this solution is possible only in the case of a tank whose cap is provided to close the tank at a defined end, for example a lower end for a vertical tank. This also requires that the filter can be placed near the cap.

  In other cases, that is to say, when the filter is not secured to a removable cap or when the tank is closed by any plug, hold the filter in position. This is done most often via a connecting member, for example a plastic rod.

  As a result, there is the need to use an additional piece whose length must be adapted to that of the tank in question, hence a large number of part numbers.

  Another possible solution is to maintain the filter by localized deformation of the tubular wall, but this at the cost of an additional manufacturing operation.

  The object of the invention is in particular to overcome the aforementioned drawbacks.

  To this end, the invention proposes a filter of the type defined in the introduction, in which the holding means comprise at least one spring leaf integral with the filter body and suitable for being arranged in a flexed prestressing configuration, in which the leaf spring is clean to come against the inside of the tubular wall.

  Because the leaf spring is bent, it abuts against the inside of the tubular wall by holding the filter in a chosen position. It is therefore no longer necessary to use an additional piece, such as a connecting rod, to maintain the filter in its position of use. A single filter reference is then sufficient, regardless of the length of the tank.

  The filter can be set in position using a simple tooling, for example of the clamp type. It is no longer necessary to use deformation or machining of the reservoir to maintain the filter. This considerably simplifies the operations of manufacturing and mounting the filter in the tank.

  In a preferred embodiment of the invention, the spring blade is adapted to be arranged transversely in the flexed prestressing configuration, in which two opposite ends of the spring blade come to bear against the inside of the tubular wall.

  According to another characteristic of the invention, the spring blade has, in a flat configuration at rest, a length, between its two opposite ends, which is greater than the transverse internal dimension of the tubular wall of the tank.

  By this measurement, it ensures a filter retention by buttressing the spring blade against the tubular wall of the tank. The spring blade may be made of a spring steel. Of course, this material must be compatible with the fluid contained in the reservoir.

  In one embodiment of the invention, the holding means comprise a connecting member coming from the filter body and adapted to be secured to an attachment region of the spring blade located substantially midway between two opposite ends. blade spring. In one embodiment, this connecting member is in the form of an axial extension against which a plurality of teeth cut in the spring blade and directed radially inwards are provided by providing an opening for the introduction in force of the liaison body.

  These teeth are preferably formed in an enlarged, bowl-shaped central region of the leaf spring.

  In an alternative embodiment, the connecting member is integrally molded with the filter body. In another embodiment of the invention, the holding means comprise two holes arranged diametrically opposite in a cylindrical wall of the filter body, these holes being adapted to be traversed freely by the spring blade in the vicinity of two ends. opposite of the blade spring.

  In another aspect, the invention relates to a tubular wall filter tank adapted to receive a filter in a selected axial position, the filter being as defined above.

  In one application of the invention, this tank is arranged to be connected to an air conditioning condenser and to contain a refrigerant fluid.

  In the description which follows, made only by way of example, reference is made to the appended drawings, in which:

  Figure 1 is a partial sectional view of a tubular tank wall containing a filter according to the invention, the holding means of which is in accordance with a first embodiment of the invention; partially in section and in perspective corresponding to Figure 1 also showing the manifold of a heat exchanger associated with the reservoir; FIG. 3 is a plan view of the leaf spring of the filter of FIGS. 1 and 2; - Figure 4 is an enlarged sectional view of the leaf spring along the line IV-IV of Figure 3; and - Figure 5 is a partial sectional view of a filter equipped with a spring blade in a second embodiment of the invention.

  Referring first to Figure 1 which shows a filter 10 housed inside a tubular wall 12 of a reservoir 14. In the example, the tubular wall 12 is a cylindrical wall in the form of a revolution around of an axis XX. The tubular wall 12 has an open end 16 through which the filter 10 is introduced in the axial direction.

  The tubular wall 12 is advantageously made of a metallic material, for example an aluminum alloy, and it has two bosses 18 and 20 on the outside which respectively delimit a fluid inlet orifice 22 and a fluid outlet orifice 24. The orifices 22 and 24 are offset in the axial direction defined by the axis XX and they communicate respectively with an upstream zone and a downstream zone of the reservoir. The fluid to be filtered enters (arrow Fi) into the reservoir through the orifice 22, is then filtered by the filter 10 and leaves the reservoir through the outlet 24 (arrow F2). The filter 10 must therefore be placed in a well-defined axial position to perform its filtration function.

  The filter 10 comprises a filter body 26 made in one piece by molding a plastic material and comprising an annular ring 28 and a circular flange 30 spaced axially and interconnected by four connecting arms 32. The annular ring 28 forms an annular sealing lip cooperating with the inside of the tubular wall 12.

  Each of the link arms 32 includes a centering guide 34 for guiding the filter in the reservoir. With the flange 30 is integrally molded a connecting member 36 consisting here of an axial extension which extends in the direction of the axis XX and which extends the filter body on the side of the opening 16 of the tank. This axial extension is centered relative to the filter body 26 and has the shape of a circular cylindrical rod of defined outer diameter and terminated by a rounded end.

  The connecting member 36 is provided to cooperate with holding means comprising a spring blade 38 arranged transversely in a flexed prestressing configuration in which two opposite ends 40 of the leaf spring come to bear against the inside of the wall tubular. We see in Figure 1 that the blade is bent to allow its two ends 40 to abut against the inside of the tubular wall.

  The spring blade 38 is disposed between the open end 16 of the tubular wall 12 and the filter body 26 and is also located between the open end 16 and the outlet orifice 24. In other words, the spring blade is located below the outlet orifice 24 when the tubular wall 12 is vertical with the open end 16 facing downwards.

  In the embodiment of Figures 1 and 2, the leaf spring 38 is bent so that it turns its concavity upwards, so to the filter body 26. However, it is conceivable to ensure that its concavity is facing downward, so opposite the filter body 26.

  The spring blade is, for example, made of a spring steel compatible with the fluid to be filtered. It is secured to the filter body by cooperation with the connecting member 36, as will be seen later.

  The leaf spring has at rest a planar configuration shown in Figure 3, namely a rectangular general shape having a length L, defined between its two ends 40, which is greater than the transverse inner dimension (inner diameter) of the tubular wall. The leaf spring comprises an enlarged central region 42, located at a distance from the ends 40, in which are cut a plurality of teeth 44, the radially inward ends of which delimit a central opening 46. The ends of the teeth circumscribe a circle whose diameter must be smaller than the diameter of the connecting member 36. In the example the teeth 44 are four in number and mutually offset by an angle of 90.

  As seen in the sectional view of Figure 4, the enlarged central region 42 has a cup shape so that the teeth 44 are slightly inclined relative to the general plane defined by the leaf spring.

  To secure the leaf spring to the filter body, the connecting member 36 is engaged in the central opening 46 defined at the end of the teeth 44. This introduction is effected by force, the ends of the teeth coming into contact with each other. to push in the material of the connecting organ.

  The filter body is made of a relatively rigid plastic material, for example of the polyamide type, loaded. The ends of the teeth are jerked by possibly penetrating into the material of the connecting member, thus achieving a permanent connection between the filter body and the leaf spring. It is then sufficient to introduce the filter, previously equipped with the spring blade, through the orifice 16 of the reservoir to the chosen position.

  This introduction is effected for example with a suitable tool, in particular a clamp, which keeps the leaf spring bent. Once the filter has arrived in position, the ends 40 of the spring blade are bent against the tubular wall 12 to immobilize the filter in a defined axial position. The annular ring 28 and the flange 30 press against the inner wall, the annular ring forming a seal. Of course, the filter body also comprises a filter cloth (not shown).

  Referring now to Figure 2 which shows the reservoir of Figure 1 associated with a manifold 48 formed of two half-shells 50 and 52. The half-shell 50 has slots 54 for the insertion of exchange tubes heat (not shown). The half-shell 52 has two openings 56 and 58 communicating respectively with the orifices 22 and 24 of the bosses 18 and 20.

  The manifold 48 is one of two manifolds of a heat exchanger, in particular an air conditioning condenser. The inlet orifice 22 is then connected to the last condensation pass of the condenser tube bundle, while the outlet orifice 24 is connected to a sub-cooling pass of this bundle. The condensed fluid, therefore essentially in the liquid state, enters the upstream zone of the reservoir, is then filtered by the filter, reaches the downstream zone, and is then sent to the supercooling pass where the superheated fluid is cooled.

  In this particular application, the reservoir may furthermore contain a drying cartridge (not shown) which makes it possible to dehydrate the cooling fluid.

  As seen in Figure 2, the end 16 of the tank is closed permanently by means of a plug 60 which can be bonded by brazing or gluing with the tubular wall of the tank.

  In the embodiment of Figure 5, which is now referred to, the body 26 of the filter 10 is extended by a cylindrical wall or skirt 62 having two diametrically opposed holes 64, which are traversed freely by a spring blade 66 in the vicinity two opposite ends 68 thereof. The spring blade is made here in the form of a single elongated blade of constant width and having in its flat configuration at rest a length L, as defined above.

  The invention is not limited to the embodiments described above as examples and extends to other variants. In particular, other forms of the leaf spring and other modes of connection between the leaf spring and the filter body are conceivable, as long as these connecting means offer sufficient possibilities of bending the leaf spring for they can cooperate by arching with the inside of the tubular wall of the tank.

  Also, although the invention has been described with particular reference to a tank arranged to be connected to an air conditioning condenser and contain a refrigerant, it can be applied to other types of tanks.

Claims (12)

claims   A clean filter to be installed within a tubular wall container (14) and comprising a filter body (26) and holding means arranged to hold the filter in an axial position selected from the reservoir, characterized in that the holding means comprise at least one leaf spring (38; 66) integral with the filter body (26) and adapted to be arranged in a bent prestressing configuration, in which the leaf spring is clean to come lean against the inside of the tubular wall {12).   2. Filter according to claim 1, characterized in that the spring blade (38; 66) is adapted to be arranged transversely in the bent prestressing configuration, in which two opposite ends (40; 68) of the spring blade come into position. press against the inside of the tubular wall (12).   3. Filter according to claim 2, characterized in that the leaf spring (38; 66) has in a flat configuration at rest a length (L), between its two opposite ends (40; 68), which is greater than the internal dimension of the tubular wall (12) of the reservoir (14).   4. Filter according to one of claims 1 to 3, characterized in that the spring blade (38, 66) is made of a spring steel. 12   5. Filter according to one of claims 1 to 4, characterized in that the holding means comprise a connecting member (36) from the filter body (26) and adapted to be secured to an attachment region (42). ) of the leaf spring (38) located substantially midway between two opposite ends (40) of the leaf spring.   6. Filter according to claim 5, characterized in that the connecting member (36) is in the form of an axial extension against which are j-bouter a plurality of teeth (44) cut in the spring blade and directed radially inwardly by providing a central opening (46) for force introduction of the connecting member.   The filter of claim 6, characterized in that the teeth (44) are formed in an enlarged central region (42) of the spring blade (38) which has a cup shape.   8. Filter according to one of claims 5 to 7, characterized in that the connecting member (36) is integrally molded with the filter body (26).   9. Filter according to one of claims 1 to 4, characterized in that the holding means comprise two holes (64) arranged diametrically opposite in a cylindrical wall (62) of the filter body, these holes being adapted to be freely traversed by the spring blade (66) in the vicinity of two opposite ends (68) of the leaf spring.   10. Tubular wall fluid reservoir, characterized in that it comprises a filter (10) according to one of claims 1 to 9 and in that said filter is in a selected axial position.   11. Fluid tank according to claim 10, characterized in that it is arranged to be connected to an air conditioning condenser and contain a coolant.   12. Heat exchanger characterized in that it comprises a fluid reservoir according to one of claims 10 or 11.