DE60213371T2 - Collector dryer - Google Patents

Abstract

In a receiver drier R for an automotive air-conditioning system charge D of desiccant material is placed in the receiver drier casing 2 adjacent to a port-free end part 1 outside of the direct refrigerant flow path. The charge D is secured in place by a first strainer 4 constituting a separation between the charge D and a refrigerant flow deflection chamber C inside the casing 2. <IMAGE>

Description

The The present invention relates to a drying container for the air conditioning system a vehicle according to the preamble of claim 1.

Of the dry container the air conditioning system of a vehicle (or generally a Cooling Systems) has the task, all in the coolant to extract contained water, a predetermined amount of the refrigerant while of the operation of the system to store and impurities from the through the drying container flowing coolant filter out. The water is by means of at least one cartridge extracted with a desiccant, this cartridge within of the housing is arranged. Impurities are from a filter structure collected.

In the from the document DE 36 06 029 A known drying container, the desiccant is disposed directly in the flow path of the coolant, within the housing and between two mutually remote walls of a screen, each of these walls is firmly attached to the inner wall of the housing. All coolant that enters the dryer tank must pass through the cartridge.

In the from the document DE 39 710 638 U known drying container, the desiccant is contained in a permeable bag which is arranged on a bell-shaped sieve, said sieve is firmly connected to the free end of a central coolant tube. The filter structure is located inside the screen. The entire coolant flowing into the drying container must pass the desiccant.

One Disadvantage of the conventional dry container is that the whole coolant flow flow through the desiccant must, over time, be a flow obstacle with a significant flow resistance forms one undesirable caused strong pressure drop. During operation, the tending Diameter of the drying container to remove and the spaces between the desiccant beads become clogged gradually. The density of the cartridge increases, which results in an increase in the flow resistance and the pressure drop has, so finally the function of the whole cooling system impaired can be. Furthermore, the cartridge occupies a considerable volume in the drying container, but in that a great usable free volume desirable would. Arranging the cartridge in the drying container is laborious and expensive because of several installation steps and additional structural measures required are.

In the from the document EP 0 276 943 A known drying container, the cartridge is contained in an axially insertable cartridge for the processing of the coolant, in an upper region of the housing. The cartridge is penetrated by an outlet tube and is divided into two compartments separated by a sieve. The lower surface of the cartridge is also formed by a permeable screen. Only part of the coolant flowing through the dryer tank must flow through the cartridge.

The desiccant cartridge from the document DE 36 01 342 A known drying container consists of a mixture of the active desiccant and a binding substance, which is pressed directly into the lower part of the housing. The mixture is cured in an oven so that it sticks to the inner wall of the housing.

Further prior art is from the documents JP 10073346 A . US 2,893,563 A . US 5,038,582 A . US 5,910,165 A . EP 0 816 779 A . JP 07043049 A and JP 02287066 A known.

Of the present invention is based on the object, a drying container of to create the above type, which is manufactured at low cost who allows it while the preparation convenient to arrange the desiccant cartridge and that helps the reliability of the system by a low pressure drop in the coolant flow to improve.

These The object is solved by the features of claim 1.

The desiccant cartridge is located outside the direct flow path of the coolant and occupies only a portion of the volume of the housing. The cartridge fulfills its function, so to speak, at a static level and has no adverse effect on the pressure drop in the coolant flow. The only pressure drop that must be overcome by the coolant flow is caused by the cross sections of the flow devices and the filter structure. Preferably, the cartridge is disposed directly in the end portion of the housing which is closed by an outlet-free end portion. No bag is needed to enclose the cartridge; Nevertheless, a permeable bag can be used if desired. The desiccant can be filled in the simplest way directly into the housing before the sieve is inserted and the cartridge - preferably under slight pressure - includes, in a predetermined manner outside the direct flow path of the coolant. No further elaborate installation steps are required. The accommodation of Trockenmit Cartridge ensures that only a portion of the coolant contained in the dryer vessel enters the cartridge in a static manner, even when the direct coolant flow is vigorous and strong. The arrangement of the cartridge outside the direct flow path is consistent with the recognition that the desiccant inherently exerts a very strong attraction on all of the water contained in the coolant and reliably extracts the water from the coolant, even if the coolant is only static Contact with the desiccant has. The cartridge is enclosed in an end portion of the housing which is far away from the inlet and outlet ports. Thus, only a small part of the volume of the drying container is occupied. The remaining volume may preferably be used to improve the subcooling effect of the drying container.

Out physical and thermal reasons, the volume of the changes Drying material during the operation of the system. For that reason, it is useful Keep the cartridge under a slight pressure, allowing it can expand and contract. Conveniently, the sieve with Help a sliding contact attached to the inner housing wall, so that it can move together with the cartridge when this expands or contracts. A compression spring loads the sieve and presses the cartridge together by means of the sieve. advantageously, the compression spring sits in the position holding device.

It is an advantage, a coolant flow diverter between the filter structure and the screen. In this Chamber develops with an advantageous dynamic state turbulent flow, if the coolant looking for his way to the outlet connection, which causes the entire water reliable is extracted from the cartridge.

Conveniently, are the inlet / outlet ports arranged together in an end portion of the housing, wherein the Diverter chamber with an axial distance to the one equipped with a connection End part is arranged. A substantially central coolant tube extends from a port of the one equipped with a port Partly in the diverting chamber. The filter structure is either on or near the free end of the coolant tube arranged. The filter structure is the only significant flow obstacle while The cartridge of the drying material does its job on a static Way fulfilled.

There it is arranged separately, needed the filter structure a prop. Preferably, the filter structure is at a position holding device attached, which is attached either at the free end of the coolant tube or from the inner housing wall is held.

Around the assembly of the drying container To simplify, is the coolant tube by an adapter part of the end part equipped with a connection of the drying container stabilized. By the adapter part is the of the position holding device and / or exerted by the sieve Reaction force damped from the end part of the housing.

One cup-shaped Sieve can be easily inserted into the housing and is through its contact with the inner wall of the drying container well guided.

When additional or alternative structure may be a layer of a gap-filling Material between the screen and the cartridge and / or between the cartridge connection-free end part of the cartridge can be arranged. This layer must be permeable, when placed on the wire. At the connection-free end part must this layer will only be elastic. Volume changes of the cartridge will be damped by this layer or compensated. The cartridge remains under a fairly constant Pressure and therefore occupies only the minimum volume in the dryer.

advantageously, can the coolant pipe, the position holding device and by the compression spring with the Position holding device connected sieve a prefabricated unit form, the comfortable in the housing can be used. The structural unit can even through the cartridge and / or be completed with the adapter part.

Further embodiments The present invention will be described below with reference to FIGS Figures closer explained. In the figures shows:

1 a longitudinal sectional view of a drying container;

2 a longitudinal sectional view of a welded embodiment of a drying container;

3 a longitudinal sectional view of another embodiment of a drying container, which is integrated in a capacitor; and

4 a schematic view of a capacitor housing, with a drying container or with the in 3 combined drying container is combined.

The in 1 illustrated drying container R has a substantially cylindrical, relatively slim housing 2 on, wherein this housing made of aluminum or steel material. The housing 2 is at the left end by an integrated end part 1 and at the opposite open end portion by an inserted and firmly connected end portion 3 completed. The end part 3 is a so-called connection head H, which serves to form a fluid-tight connection with a connection structure, not shown, to which the drying container must be attached. The drying tank R is operated, for example, in a position in which the connection head H is oriented downward.

The left end of the case 2 contains a cartridge D of a drying material. The material can be poured directly through the open housing end into the housing. The cartridge D is passed through a sieve 4 in position and in contact with the inner housing wall and the end part 1 held. The sieve 4 is cup-shaped and has a perforated bottom wall 9 and a circumferentially continuous guide wall 10 on. The guide wall 10 can be connected to the inner housing wall by a sliding contact. Removed from the sieve 4 and in contact with the inner wall is a position holding device 7 arranged. The holding device 7 is cup-shaped and has an either perforated or partially open pot bottom wall, which has a net filter structure 11 and a peripheral guide wall 12 carries, with this peripheral guide wall 12 may be in contact with the inner wall of the housing. The drying tank R is provided with a central, longitudinally extending central tube 13 equipped by an adapter port A in the terminal equipped with a terminal 3 is used and up to the position holding device 7 extends. The position holding device 7 can have a central, tubular projection 14 have, in the free end region of the coolant tube 13 is used. The position holding device 7 defines flow paths 6 for a coolant that circulates through the drying tank R.

The coolant flows through an inlet port 15 in the end part 4 , the adapter part A and further through the coolant tube 13 into the drying tank R, from which it reaches a coolant flow diverting chamber C, from the sieve 4 and the position holding device 7 is defined. A part of the coolant in the chamber C also flows into the cartridge D. The cartridge D extracts all the water contained in the coolant. From the chamber C, the coolant flows through the net filter structure 11 and then into the rest of the case 2 until there is the drying tank R through an outlet port 16 leaves. The chamber C and the remaining free space in the housing 2 Provide a relatively large volume, which is desirable to an efficient subcooling effect of the drying container. to achieve.

The connector head H, which is the terminal part equipped with a terminal 3 is in the free end area of the housing 2 used and is with the housing 2 by a radially inwardly directed deformation 18 , For example, a circular envelope of the housing wall, firmly connected. The connection area between the connector head H and the housing 2 is additionally by O-rings 17 sealed. Other suitable solutions for this purpose can also be used.

A compression spring 5 is between the sieve 4 and the position holding device 7 used, so that the sieve 4 is pressed lightly against the cartridge D. The part of the coolant that flows into the cartridge D is indicated by the arrow 8th shown. The compression spring 5 allowed the sieve 4 to move axially if the volume of the cartridge D should decrease, eg due to a sedimentation effect, or increase from other causes. In all these operating conditions, however, the cartridge D remains under a slight axial bias, that of the first wire 4 and from the compression spring 5 is exercised.

The coolant tube 13 , the position holding device 7 and that with the position holder 7 screen connected by the compression spring 4 can be prefabricated as a structural unit that fits comfortably in the housing 2 can be used after the cartridge D has been filled. The structural unit may even be attached in advance to the connector head H, so that it can be attached with an installation step when the connector head H is inserted.

The structure described above makes it possible to reduce the manufacturing and assembly costs of the drying vessel compared to the costs associated with conventional drying vessels and substantially improves the operating functionality of the system by reducing the pressure drop in the flow of refrigerant. For example, cartridge D, which may form a molecular sieve, is at a static level near the top of the housing, for example, when the dryer vessel is operated in an upright position in the system. During operation and over time, the diameter of the drying container tends to decrease. Therefore, the pressure difference in the coolant flow between the inlet port and the outlet port significantly increases, so that the performance of the drying tank and the whole system may be impaired. After several hours of operation of the drying tank in the air conditioning system, the risk of flow clogging increases proportional to the reduction of the diameter, because also the cross-sectional area for the filter function decreases. In the arrangement described above, the filter structure is separated from the water-absorbing cartridge. This is beneficial not only to drying vessels installed in the freestanding system, but also to drying vessels that are integrated either with or in the condenser of the system. The integration into the condenser does not cause any problems, because the cartridge of the drying material can withstand temperatures of up to 750 ° and more, for example, when the condenser and the drying container are simultaneously soldered. The quality, bead size, volume and the like of the cartridge D can be easily adapted to the requirements of customers using the drying container. The same applies to the filter structure. The end part equipped with a connection 3 can also be held in position by welding or the like.

The in 2 shown drying container is similar to the in 1 illustrated constructed. The cartridge D of the drying material is in the closed end portion of the housing 2 in direct contact with the integrated end part 1 arranged. Between the sieve 4 , which is guided along the inner housing wall, and the cartridge D is a layer 19 arranged from a gap-filling material, which is permeable to the coolant, but not for the desiccant, and compensates for any change in volume of the cartridge D. The middle coolant tube 13 is with the end part 3 (With the connector head H) firmly connected by the adapter part A and abuts on the bell-shaped in this case position holding device 7 standing on a ledge of the sieve 4 is arranged on. The open end region of the holding device 7 is with the net filter structure 11 fitted. The chamber C is partially defined within the fixture. In this case, the coolant pipe 13 with the outlet port 16 be connected. The connector head H is connected to the housing 2 welded by the adapter part A.

The in 3 shown drying container R is intended to be in a capacitor housing 20 (please refer 4 ) of the system. The tubular, cylindrical housing 2 is at both end areas by bolt or plug-shaped end parts 1 . 3 completed. The cartridge D of the drying material is directly in through the end part 1 closed end of the housing 2 contain. At both end regions of the cartridge D are layers 19 arranged a gap-filling material. The sieve 4 with its perforated bottom wall 9 is arranged on the inner housing wall by a sliding contact. The position holding device 7 is at an axial distance from the screen 4 arranged and carries the net filter structure. The coolant flow diverting chamber C is between the sieve 4 and the position holding device 7 Are defined. In the area of the chamber C is an inlet port 15 formed in the housing wall, while the outlet port 16 in the housing wall, centrally between the position holding device and the other end part 3 is made. The operating position of the drying container R can be selected so that the cartridge D is at the top.

In 4 is the drying container of 3 such on the side of the capacitor housing 20 arranged that the drying tank R from the housing 20 is supported and that the inlet and outlet connections 15 . 16 the necessary flow connections with the interior of the housing 20 provide.

Claims (8)

Drying container (R) for the air conditioning system of a vehicle, comprising: a substantially cylindrical housing ( 2 ) with end parts ( 1 . 3 ) terminating respectively both end portions of the housing, inlet / outlet ports ( 15 . 16 ), a cartridge (D) of a desiccant, fixed inside the housing ( 2 ), and a filter structure ( 11 ) located in a direct flow path located inside the housing (FIG. 2 ) from the inlet port ( 15 ) to the outlet port ( 16 ), wherein the cartridge (D) of the desiccant outside the direct flow path of the coolant in an end portion of the housing ( 2 ) remote from the inlet / outlet ports ( 15 . 16 ) is arranged, characterized in that the cartridge of the desiccant from the direct flow path through a permeable sieve ( 4 ), which holds the cartridge (D) in position, that the filter structure ( 11 ) is separated from the cartridge (D) that the sieve ( 4 ) is arranged on the inner housing wall by a sliding contact, and that a compression spring ( 5 ) between one at the free end of a coolant tube ( 13 ) mounted position holding device ( 7 ) and the sieve ( 4 ) is inserted, thus yielding the cartridge (D) through the sieve ( 4 ). Drying container according to claim 1, characterized in that the filter structure ( 11 ) and the sieve ( 4 ) together define a coolant flow diverter chamber (C) directly connected to the inlet port (C). 15 ) communicates indirectly through the filter structure ( 11 ) with the outlet port ( 16 ) communicates, and whereby this chamber through the sieve ( 4 ) communicates with the housing part containing the cartridge (D). Drying container according to claim 2, since characterized in that the inlet / outlet ports ( 15 . 16 ) in an end part ( 3 ) of the housing ( 2 ) are arranged such that the Stromumleitekammer (C) with an axial distance from the end portion equipped with terminal ( 3 ) is arranged, that the substantially middle coolant tube ( 13 ) from a connection ( 15 . 16 ) of the part equipped with connection ( 3 ) extends into the Stromumleitekammer (C), and that the filter structure ( 11 ) either at or near the free end of the coolant tube ( 13 ) is arranged. Drying container according to at least one of the preceding claims, characterized in that the filter structure ( 11 ) with the position holding device ( 7 ), which device is either supported by the inner housing wall or at the free end of the coolant tube ( 13 ) is attached. Drying container according to claim 1, characterized in that the coolant tube ( 13 ) by an adapter part (R) of the terminal equipped end part ( 3 ) is stabilized. Drying container according to at least one of the preceding claims, characterized in that the sieve ( 4 ) cup-shaped and a perforated bottom wall ( 9 ) and a peripheral guide wall ( 10 ) having. Drying container according to at least one of the preceding claims, characterized in that a layer ( 19 ) between the sieve ( 4 ) and the cartridge (D) and / or between the connection-free end part ( 1 ) and the cartridge (D), said layer being of a material which is liquid-permeable and gap-filling. Drying container according to at least one of the preceding claims, characterized in that the coolant tube ( 13 ), the sieve ( 4 ) and the position holding device ( 7 ) and the compression spring ( 5 ) form a prefabricated, structural unit.