DE19753641A1 - Condenser with integral container, esp. for air conditioning circuit in motor vehicle - Google Patents

Abstract

The condenser has a bundle of tubes between collector boxes (2,3). The second box is divided by a vertical wall into two parts. The first box and the first part of the second are divided into three chambers by horizontal walls. The first and third chambers of the second box are connected to the upper and lower parts of the second part. The coolant flows upwards from the second chamber of the first box to the first chamber of the second box and then downwards via the second part of the second box to the third chamber of the first box. The second part (13) of the second box (3) is divided into first (17) and second (18) chambers by a horizontal wall (23) with a through hole (2) and a channel (24) whose cross-section equals the hole diameter and which connects the first and second chambers.

Description

The invention relates to air conditioning circuits, for example air conditioning systems for motor vehicles, and in particular capacitors with integrated loading containers used in such systems.

The condensers with an integrated container contain a so-called "condensation part", the task of which is to cool a refrigerant that comes from a pre-stored part of the air conditioning circuit, so that it is brought to a condensation temperature T _C , and a so-called "subcooling part" , the task of which is to lower the temperature of the refrigerant below T _C before it is discharged into a downstream part of the air conditioning circuit.

These capacitors consist of a tube bundle, between the first and second collection boxes is brought up, which is in an approximately vertical Extend direction. The second collection box is through an approximately vertical partition into a he most and the second part. The first collecting box  most and the first part are each through approximately horizontal partitions tightly into a first, second and third chamber divided into this series follow one above the other from an upper part are net, the first and third chamber of the two th collecting box through a first (inlet) and second (outlet) opening with an upper or lower Part of the second part related to the Integrated container forms the connection between condensation and hypothermia section light.

The current air conditioning systems, which are equipped with such condensers, have a refrigerant volume that decreases considerably over time due to the aging of the refrigerant in question. This reduction enables a, generally gradual, reduction of the temperature difference ΔT between the condensation temperature T _C and the subcooling temperature T _S. It can be assumed that the capacitor remains efficient as long as ΔT is greater than approximately 10 ° C.

Depending on whether the refrigerant gets into an upper part or a lower part of the integrated container, the curve that shows the development of the temperature difference depending on the refrigerant volume circulating in the system is either an approximately monotonically increasing function (see Fig. 1) or an initially increasing, then closing approximately constant (paragraph) and then as the increasing function (see Fig. 2).

A step capacitor can therefore have a value of ΔT more than about 10 ° for longer periods than one Ensure the condenser with no real paragraph. Each the longer the sales, the longer the efficiency falls duration of the capacitor, or the longer  it works with a small amount of refrigerant, so the dimensions of its container accordingly can be reduced.

Heel capacitors with an integrated container through their upper part to the air conditioning circuit run connected, in contrast to the capacitors without paragraph, which are called capacitors with lead "from below "and by one, in space common lower part connected below are. It follows from this that these sales Condensers in certain air conditioning systems are not can be used.

Because of the very small distance between the one let and the outlet of your integrated container can NEN these known paragraph capacitors also Filter media only in a lower part of the container record that has a very small volume and is difficult to access in so far as the said filter medium from an upper part of this container be used.

A task of the invention is therefore: NEN condenser with integrated container ready ask, where the aforementioned disadvantages do not occur.

To this end, the invention proposes a capacitor with in tegrated container of the type defined in the introduction, in which the second part (integrated container) of the second collection box on the one hand in a first and second chamber by an approximately horizontal partition wall is divided with a passage with out Provided selected dimensions and preferably in about the same height as the horizontal dividing line wall between the first and second chamber of the two th collecting box is arranged, and on the other hand contains a channel whose cross section, based on  the smaller values, the same dimensions as the Passage and with a first and two end facing each other, said first end via the passage into the first chamber of the second part opens to a ver bond between the first and second chambers of the second part.

The applicant has found that more surprising demonstrate a solution to generate sales Capacitors with an integrated container that are equipped with an egg nem relatively distant inlet (first Opening) and outlet (second opening) are provided, consists in making the said inlet and outlet artificially to get closer to each other. Such is according to the invention Approximation possible thanks to the use of a channel the opposite ends include those in the upper or lower part of the container (second part) mün the.

The channel preferably extends inside the second chamber of the second part at least on the Half of its vertical extent.

The second end of the channel preferably opens out in the second chamber of the second part approximately in height he second opening (outlet of the container).

The applicant has found that the Ab sentence the longer the closer the second end is of the channel at the outlet (second opening) of the container is arranged. By performing the aforementioned Approaching apparently reduces the ratio nis between the volume of the refrigerant between two the inlet and outlet of the integrated container (second part) circulates, and the volume that is in the integrated container, outside the channel is cash. The condensed refrigerant in the Be container gets through its inlet, is then in the  Channel initiated and then at its output sucked through the outlet of the container, causing for the air conditioning circuit an operation with "ge closed circuit "is made possible, in which the referred to as "dormant" rest of the refrigerant in the parts of the container located outside the channel ters is saved.

In a special embodiment, firstly, that first end of the channel through a sealing cap closed while secondly the wall covering the above limited part of the second collection box, in height the first chamber of the second part a first opening tion with a shape adapted to the cover has to close its tight fuse in a past agreed position after inserting the channel in to allow said second part through the opening lichen, and thirdly, the first end of the Ka nals on one side, roughly opposite the has first opening, second openings around the Inlet of the refrigerant into the interior of the duct enable.

In this version, the cover is preferred wise with at least one seal that its sealing at the level of the first opening of it most chamber of the second part.

This means that a removable duct can be implemented.

According to another feature of the invention, the Ka nal, whether removable or not, filter with tel record that from funds for filtering Impurities and / or best desiccant hen. This allows the capacitor to have one or more take on additional functions.

In order to avoid the presence of filter media in the Duct-related pressure drops as low as possible  hold, these are preferably in the first end of Channel arranged in the first chamber of the two ten part is included.

If the filter media is distributed in the channel, it is also advantageous that its second end one includes a closed end part with third Openings are provided around the outlet of the refrigerant Allow from the channel. This can ver be prevented that the filter medium inside of the container and consequently in the entire condenser disperse.

In the following example spelling will refer to the accompanying drawings taken. The following show in detail:

Figure 1 is a diagram illustrating the development of the subcooling temperature difference depending on the volume of refrigerant, which circulates in a condenser with an integrated container and with "supply line from below" according to the prior art.

Fig. 2 is a diagram illustrating the development of the subcooling temperature difference as a function of the refrigerant volume, the ter in a condenser according to the invention with an integrated container and with "supply line from below"circulates;

FIG. 3 shows a schematic illustration for illustrating a capacitor according to the invention in a first embodiment; FIG.

Fig. 4 is a schematic representation of Veran an illustration of a capacitor according to the invention in a second embodiment.

In Fig. 3 is a capacitor of the invention is illustrated with an integrated container 1. Such a capacitor is, for example, part of an air conditioning circuit of an air conditioning system, for example for a motor vehicle. Such a capacitor consists of a first 2 and a second 3 collector boxes, which run approximately parallel to one another and are arranged in approximately vertical positions. The collecting boxes 2 and 3 are connected to one another via a plurality of tubes 4 , which run parallel to one another and are arranged in an approximately horizontal position.

This condenser 1 can be divided into two parts, in a first part 5 , which is referred to as "condensation part", and a second part 6 , which is referred to as "subcooling part". The first or condensation part 5 is intended to receive the cold by means of an upstream part of the air conditioning circuit (not shown) in order to cool it and to condense it at a condensation temperature T _C. The second or sub cooling part 6 is intended for lowering the temperature of the condensed refrigerant to a subcooling temperature T _S , which is preferably about 10 ° C (ΔT) below T _C. In other words: T _S = T _C - ΔT.

In the example illustrated in FIG. 3, the first header box 2 is divided by two approximately horizontal partition walls into a first 8 , second 9 and third 10 chamber, which are arranged one above the other, the first chamber 8 being located in the upper part of the condenser .

The second header box 3 is first divided into a first 12 and a second 13 part by a vertical partition 11 , the second part 13 forming the integrated container of the condenser. This second header box 3 is also divided in its first part 12 by two approximately horizontal partitions 7 into a first 14 , second 15 and third 16 chamber un, which are arranged one above the other, the first chamber 14 in the upper part of the capacitor 1st located.

The integrated container 13 is also divided into a by a partition 23 , which runs approximately horizontally and is preferably arranged at a height which corresponds in et wa to the height of the partition 7 , which delimits the first 14 and second 15 chambers of the first part first 17 and second chamber 18 divided, said chamber 17 is located in the upper part of the condenser 1 .

The first chambers 14 and 17 , which are formed in the upper part of the second collecting tank 3 , are connected to one another by a first opening 19 , which is incorporated in the vertical partition 11 . Likewise, the third chamber 16 of the first part 12 and the second chamber 18 of the second part 13 (integrated container) are connected to one another by a second opening 20 which is provided in the lower part of the condenser 1 .

The course of the refrigerant inside the capacitor is shown in Fig. 3 by the different arrows. The refrigerant that comes from the upstream part of the air conditioning circuit passes through an inlet connection 21 into the second chamber 9 of the first header box 2 . It then circulates in the tubes 4 , which open into the second chamber 9 of the first collecting tank or into the second chamber 15 of the first part 12 of the second collecting tank 3 . After it has entered this second chamber 15 , it flows through the tubes 4 , which open into said second chamber 15 or into the first chamber 8 of the most collecting box 2 . It then flows again through the tubes 4 , which open into the first chamber 8 or into the first chamber 14 of the first part 12 of the second header box 3 . It then passes through the first opening 19 into the first chamber 17 of the integrated container 13 .

In order to enable the connection between the first 17 and second 18 chambers of the integrated container 13 , the invention provides a passage 22 with selected dimensions in the horizontal partition 23 . This passage 22 is preferably located in a central position. It also provides for the invention a channel 24 in front of which includes a first end 25 which opens into the first chamber 17 of the integral container 13, and a second end 26 which opens before preferably in a lower part of the integrated Be hälters. 13 The first end 25 of the channel 24 is preferably fixedly connected to the horizontal partition 23 . Even if this is not shown in Fig. 3 Darge, the first end 25 of the channel 24 can of course protrude into the interior of the first chamber 17 of the inte grated container 13 .

This channel has a (vertical) longitudinal extent inside the second chamber 18 of the integrated loading container 13 , which is at least equal to half the height of this second chamber 18 . Preferably, the second end 26 opens approximately at the level of the second opening 20 , which enables the connection between the third chamber 16 of the first part 12 and the second chamber 18 of the loading container 13 .

The applicant has found that in this procedure, a condenser with an integrated container and supply line "from below" (based on the location of the inlet port 21 ) has a paragraph characteristic of the type described at the beginning with reference to FIG. 2 . He surprisingly gives the following finding: The closer the second end 26 of the channel 24 is to the second opening 20 , the longer the sales of the development curve of ΔT (subcooling temperature difference) depending on the refrigerant volume in the invention Capacitor circulates (as described initially with reference to FIG. 2).

The cooled and condensed refrigerant, which is located in the first chamber 17 of the integrated container 13 , flows through the channel 24 and enters the second chamber 18 of the integrated container 13 in the vicinity of the second opening 20 . Then it is sucked into the third chamber 16 of the first part 12 of the second Sam melkastens 3 , whereupon it flows through the tubes 4 , which open into this third chamber 16 and into the third chamber 10 of the first header box 2 . After it has entered this third chamber 10 , it returns via an outlet connection 27 to a downstream part of the air conditioning circuit (not shown in the figure).

In summary: The refrigerant arrives at a temperature T in the condenser, flows through the tubes 4 of the condensing part 5 , where it gradually cools and condenses, in order then to get into the first chamber 14 of the second part 12 of the second collecting tank 3 . The refrigerant has the condensation temperature T _C. It then circulates in the integrated container 13 , in which a separation of the gaseous and liquid phases takes place, whereupon it enters the third chamber 16 of the second part 12 of the second collecting tank 3 . It is then located in the subcooling part 6 of the condenser 1 , which enables its temperature to be reduced to a subcooling temperature T _S which is at least 10 ° below the condensation temperature T _C.

Referring now to FIG. 4, a Vari ante of the capacitor according to the invention described above to be described.

In this variant, all components of the condensate sators with the exception of the channel and the upper part of the integrated container with the be standing before written components identical.

In this variant, the integrated container 13 contains filter means 30 , which can be means for filtering out impurities and / or drying agents.

For this purpose, the channel 24 comprises a shaped first end 25 which has approximately the dimensions of the first chamber 17 of the integrated container 13 . This shaped first end 25 contains the filter means 14 and is sealed in its end part by a cover 28 . The cover is firmly connected to the first end 25 , which is preferably done by means of folding.

The wall 29 , which forms the upper end partition of the second collecting tank 3 , preferably contains a first opening 31 at the level of the upper part of the integrated container 13 in order to enable the insertion or removal of the filter 24 provided with the filter means 30 .

In order to ensure the sealing of the container 13 at the level of the first opening 31 , the closure cover advantageously comprises on the one hand a molded part with the dimensions of this first opening 31 and on the other hand at least one seal 32 , for example a round sealing ring. In addition, means for securing the closure cover in relation to the second collecting box 3 can be provided.

In order to enable the inlet of the refrigerant into the interior of the shaped first end 25 of the channel 24 and at the same time prevent the escape of the filter means 30 , one or more second openings (or calibrated bores) are also provided on a longitudinal surface of this first end 25 33 provided at selected places so that these calibrated holes are approximately opposite the first opening 19 after the channel 24 has been installed in the integrated container 13 . The cooled and condensed refrigerant can then get into the interior of the second end 25 , be filtered by the filter means 30 contained therein, flow into the central part of the channel 24 and through the second end 26 of this channel in the vicinity of the second opening 20 ge long.

In the example illustrated in FIG. 4, the filter means are contained exclusively in the first end 25 , specifically in the first chamber 17 of the integrated container 13 . For this purpose, a calibrated grid 36 (which forms calibrated third openings) is provided at the boundary 34 between the first end 25 and the central part of the channel 24 , which prevents the filter medium 30 from migrating into the central part of the channel 24 .

In a variant, filter means 30 could of course also be provided in the entire channel 24 or in another part of the channel than in its first end 25 . In this case, the calibrated grid 36 would be provided at the level of the end part 35 of the second end 26 of the channel 24 in order to prevent the migration of the Filtermit tel 30 into the interior of the capacitor.

The invention is not based on the above only as Example described embodiment limited, son because it extends to other variants,  the specialist in the context of the following claims could develop.

Thus, channel 24 illustrated in FIG. 3 can be a removable channel. In this case, as in the embodiment described with reference to FIG. 4, a first opening 31 in the wall 29 , which serves as the upper end partition for the second sam melkasten 3 , and closure means, such as the closure cover 28 described above, vorese will be.

In addition, filter means could be provided in channel 24 of the capacitor illustrated in Figure 3.

For the rest, a container has been described in which the partition 23 extends approximately at the same height as the partition 7 between the first 14 and second 15 chambers of the first part 12 of the second collecting tank 2 ; however, this partition 23 could of course also be arranged somewhat above or below said partition 7 .

Finally, with reference to FIG. 3, a channel 24 has been described which is fixedly connected at its end 25 to the partition wall 23 , but the partition wall and the channel could of course also be designed as a single molded part.

Claims (12)

A condenser for a cooling circuit, through which a refrigerant flows, comprising a tube bundle ( 4 ), which is attached between a first ( 2 ) and a second ( 3 ) header box, which extend in an approximately vertical direction, the second Collection box ( 3 ) is divided by a roughly vertical partition ( 11 ) into a first ( 12 ) and second ( 13 ), while the first collection box ( 2 ) and the first part ( 12 ) each by roughly horizontal partition walls ( 7 ) are tightly divided into first ( 8 ; 14 ), second ( 9 ; 15 ) and third ( 10 ; 16 ) chambers, which are arranged one above the other in this order from an upper part, the first ( 14 ) and third ( 16 ) chamber of the second collecting tank ( 3 ) via a first ( 19 ) and a second ( 20 ) opening with an upper ( 17 ) and lower ( 18 ) part of the second part ( 13 ) in connection, the refrigerant tel the second chamber ( 9 ) of the first collecting box least ( 2 ) to the first chamber ( 14 ) of the second collecting box ( 3 ) upwards and then flows down over the second part ( 13 ) of the second collecting box to the third chamber ( 10 ) of the first collecting box ( 2 ), characterized in that the second part ( 13 ) of the second collecting tank ( 3 ) in ei ne first ( 17 ) and second ( 18 ) chamber is divided by an approximately horizontal partition ( 23 ) which is provided with a passage ( 22 ) with selected dimensions, and includes a channel ( 24 ) whose cross-section, in relation to the smaller values, has the same dimensions as the passage ( 22 ) and which is provided with a first ( 25 ) and a second ( 26 ) end which are opposite one another, the said first end ( 25 ) via the passage ( 22 ) opens into the first chamber ( 17 ) of the second part ( 13 ) to enable a connection between the first ( 17 ) and second ( 18 ) chamber of the second part ( 13 ). 2. Capacitor according to claim 1, characterized in that the channel ( 24 ) inside the second chamber ( 18 ) of the second part ( 13 ) extends at least half of its vertical extent. 3. Capacitor according to claim 2, characterized in that the second end ( 26 ) of the channel ( 24 ) in the second chamber ( 18 ) of the second part ( 13 ) opens approximately at the level of the second opening ( 20 ). 4. Capacitor according to one of the preceding claims, characterized in that the first end ( 25 ) of the channel ( 24 ) is closed by a sealing cover ( 28 ) that the wall ( 29 ) covering the upper part of the second collecting tank ( 3 ) limited, at the level of the first chamber ( 17 ) of the second part ( 13 ) contains a first opening ( 31 ) with a shape adapted to the closure cover ( 28 ) in order to ensure its tight securing in a predetermined position after the insertion of the channel ( 24 ) in said second part ( 13 ) through the opening ( 22 ), and that the first end ( 25 ) of the channel ( 24 ) on a side surface, approximately opposite the first opening ( 19 ), second openings ( 33 ) contains to allow the inlet of the refrigerant into the interior of the channel ( 24 ). 5. A capacitor according to claim 4, characterized in that the closure cover ( 28 ) is provided with at least one seal ( 32 ) which seals it at the level of the first opening ( 31 ) of the first chamber ( 17 ) of the second part ( 13 ) can ensure. 6. Capacitor according to claim 5, characterized in that the first end ( 25 ) of the channel ( 24 ) by means of folding is firmly connected to the closure cover ( 28 ). 7. Capacitor according to one of claims 1 to 6, characterized in that the channel ( 24 ) contains filter means ( 30 ). 8. Condenser according to one of claims 4 to 6 in combination with claim 7, characterized in that the filter means ( 30 ) in the first end ( 25 ) of the channel ( 24 ) are arranged, which in the first chamber ( 17 ) of the second Part ( 13 ) is included. 9. Condenser according to one of claims 4 to 6 in combination with one of claims 7 and 8, characterized in that the second end ( 26 ) of the channel ( 24 ) in a closing part ( 35 ) contains third openings to the outlet to allow the refrigerant from the channel ( 24 ). 10. Capacitor according to one of claims 7 to 9, characterized in that the filter means ( 30 ) comprise means for filtering out impurities. 11. Condenser according to one of claims 7 to 10, characterized in that the filter means ( 30 ) comprise drying agents. 12. Condenser according to one of claims 1 to 11, characterized in that the partition ( 23 ) of the second part ( 13 ) is arranged at approximately the same height as the partition ( 7 ) which the first ( 14 ) and second ( 15 ) separates the chamber of the first part ( 12 ) of the second collecting tank ( 3 ).