DE102018211589B4 - Refrigerant collector with three connections for a refrigeration system with heat pump function, refrigeration system and motor vehicle with refrigeration system - Google Patents

Abstract

Refrigerant collector (22) for a refrigeration system (10) with heat pump function of a motor vehicle, in particular an electrically driven motor vehicle, with a collector housing (32) in which, based on an installed position in a refrigeration system (10), gaseous refrigerant and liquid refrigerant (40) can be collected in a lower region (38), three connections (26, 28, 30) arranged on the collector housing (32), a first connection (26) being designed to supply refrigerant bidirectionally to the refrigerant collector (22). to direct or to direct away from this, a second connection (28) is designed to direct refrigerant unidirectionally towards the refrigerant collector (22), and a third connection (30) is designed to direct refrigerant unidirectionally away from the refrigerant collector (22). conduct, each connection (26, 28, 30) being connected to the collector housing (32) at a respective connection point (46, 48, 50), characterized in that the second connection (28) is inside the collector housing (32). is set up so that refrigerant is directed into the upper area (44) of the collector housing (32).

Description

The invention relates to a refrigerant collector for a refrigeration system with a heat pump function of a motor vehicle, in particular an electrically driven motor vehicle, a refrigeration system with a heat pump function with such a refrigerant collector and a motor vehicle with such a refrigeration system.

Heat pump (HP) systems with exclusive use of a so-called chiller as a heat source can be designed either with an integrated high-pressure collector on a refrigeration system condenser and an integrated high-pressure collector on a heat pump condenser or with a common, separate high-pressure collector. If the refrigeration system condenser is also used as a heat source, a complex refrigerant line connection including a correspondingly large number of switching valves is required in order to be able to use a common, separate high-pressure collector with usually two connections, ie one for refrigerant inlet and one for refrigerant outlet. An example of such a refrigeration system with a heat pump function is, for example, from DE 10 2011 118 162 A1 known.

Due to the high complexity of line routes and switching valves, both the component technology and the control system effort in such a refrigeration system is very high.

In order to reduce this effort, a high-pressure collector is required that has at least three connections, at least one of which has a bidirectional flow, ie the bidirectional connection is used for both the inlet and outlet of the refrigerant. Schematic examples of such a connection are from DE 10 2010 042 127 A1 known. Furthermore, this also shows DE 601 04 786 T2 a refrigerant collector with three connections.

The object underlying the invention is to provide a refrigerant collector whose internal structure is optimized with regard to the desired function.

This task is solved by a refrigerant collector with the features of patent claim 1, by a refrigeration system with the features of claim 12 and by a motor vehicle with the features of patent claim 13. Advantageous embodiments with useful further developments are specified in the dependent patent claims.

A refrigerant collector for a refrigeration system with a heat pump function of a motor vehicle, in particular an electrically driven motor vehicle, is therefore proposed with a collector housing in which, based on an installed position in the refrigeration system, gaseous refrigerant can be collected in an upper area and liquid refrigerant can be collected in a lower area, with three connections arranged on the collector housing, where
a first connection is set up to direct refrigerant bidirectionally towards or away from the refrigerant collector,
a second connection is designed to direct refrigerant unidirectionally to the refrigerant collector, and
a third connection is designed to direct refrigerant unidirectionally from the refrigerant collector path,
wherein each connection is connected to the collector housing at a respective connection point.

It is provided that the second connection inside the collector housing is set up so that refrigerant is directed into the upper area of the collector housing.

The second connection (unidirectional refrigerant supply) thus opens into the area of the refrigerant collector in which the refrigerant is in the gas phase. If liquid refrigerant is conveyed into the refrigerant collector through the second connection, it can fall or drip down through the upper area filled with refrigerant gas, so that it can be collected in liquid form in the lower area. Since the second connection is only intended for the introduction of refrigerant, its mouth can easily be arranged in the upper area because both liquid and gaseous refrigerant can be introduced via the second connection, but no gaseous refrigerant can escape or be undesirably sucked into the refrigerant circuit can be.

The first connection can be set up inside the collector housing so that refrigerant is directed into the lower region of the collector housing. Furthermore, the first connection and the third connection inside the collector housing can be set up so that liquid refrigerant can be removed from the lower region of the collector housing.

The bidirectional first connection therefore directs refrigerant into the lower area in which the refrigerant is stored in liquid form in the refrigerant collector. Accordingly, it can happen that at least refrigerant is released through the first connection at least some of it is also introduced in gaseous form. This gaseous refrigerant then rises in the form of bubbles within the liquid refrigerant towards the upper region of the refrigerant collector.

The arrangement of the first and third connections in the lower area also ensures that only liquid refrigerant is removed from the refrigerant collector.

1. a) alle Anschlussstellen im oberen Bereich oder
2. b) alle Anschlussstellen im unteren Bereich oder
3. c) die erste Anschlussstelle im oberen Bereich und die zweite und dritte Anschlussstelle im unteren Bereich oder
4. d) die zweite und dritte Anschlussstelle im oberen Bereich und die erste Anschlussstelle im unteren Bereich oder
5. e) die erste und zweite Anschlussstelle im oberen Bereich und die dritte Anschlussstelle im unteren Bereich oder
6. f) die erste und dritte Anschlussstelle im oberen Bereich und die zweite Anschlussstelle im unteren Bereich oder
7. g) die dritte Anschlussstelle im oberen Bereich und die erste und zweite Anschlussstelle im unteren Bereich oder
8. h) die zweite Anschlussstelle im oberen Bereich und die erste und dritte Anschlussstelle im unteren Bereich.

The first connection point for the first connection, the second connection point for the second connection and the third connection point for the third connection can be arranged on the collector housing as follows:

1. a) all connection points in the upper area or
2. b) all connection points in the lower area or
3. c) the first connection point in the upper area and the second and third connection points in the lower area or
4. d) the second and third connection points in the upper area and the first connection point in the lower area or
5. e) the first and second connection points in the upper area and the third connection point in the lower area or
6. f) the first and third connection points in the upper area and the second connection point in the lower area or
7. g) the third connection point in the upper area and the first and second connection points in the lower area or
8. h) the second connection point in the upper area and the first and third connection points in the lower area.

• - Der erste Anschluss (bidirektional) weist einen Leitungsabschnitt auf, der sich im Inneren des Kältesammlers von oben nach unten erstreckt und dessen Mündung im unteren Bereich (im flüssigen Kältemittel) befindet;
• - Der zweite Anschluss (unidirektionale Kältemittelzuführung) weist einen Leitungsabschnitt auf, der sich im Inneren des Kältesammlers von unten nach oben erstreckt und dessen Mündung im oberen Bereich (im gasförmigen Kältemittel) befindet.

Depending on the location of the respective connection point, the connection in question has a line section running inside the refrigerant collector, the mouth of which is then arranged in the corresponding upper or lower area of the refrigerant collector. For case c mentioned above as an example, this means, for example:

• - The first connection (bidirectional) has a line section that extends from top to bottom inside the cold collector and whose mouth is in the lower area (in the liquid refrigerant);
• - The second connection (unidirectional refrigerant supply) has a line section that extends from bottom to top inside the cold collector and whose mouth is in the upper area (in the gaseous refrigerant).

The connection points can be arranged in a cover or a base or also laterally in a side wall of the cold collector.

In the lower region of the collector housing, a deflection element which projects inwards from a bottom section of the collector housing and influences the flow of the refrigerant can be arranged. The deflection element serves in particular to influence the flow conditions in the refrigerant so that refrigerant (gas bubbles) introduced in gaseous form into the lower region is reliably guided along the deflection element in the direction of the upper region.

The deflection element can be set up to deflect gaseous coolant introduced in the lower region of the refrigerant collector towards the upper region, so that gaseous coolant collects in the upper region.

The deflection element can be a wall section which is designed such that a first refrigerant removal area and a second refrigerant removal area are formed in the lower region of the refrigerant collector.

At least one opening can be formed in the wall section, which provides a fluid connection between the first refrigerant removal area and the second refrigerant removal area.

Furthermore, the wall section can be dimensioned such that a slot-like flow area is formed between an end face of the wall section and the inside of the collector housing, through which the first refrigerant removal area and the second refrigerant removal area are in fluid communication.

As an alternative to a wall section with at least one opening, a type of grid or net can also be used. The mesh size of the grid or net can be chosen so that gas bubbles are deflected through the grid or net while. liquid refrigerant can pass through the grid or network.

In addition to the deflection element, in addition to an arrangement of the connections outside the refrigerant collector, the internal arrangement of mouth sections of the respective connections relative to one another can also be taken into account. become. The deflection element and the respective installation position of the mouth areas of the connections within the refrigerant collector also serve to separate the refrigerant compressor oil from the liquid refrigerant, so that a balanced refrigerant-oil ratio is achieved. Mixture can be sucked out of the refrigerant collector. In particular, the opening provided in the wall section, which is preferably arranged at a lowest point, serves to ensure that the liquid refrigerant and the refrigerant oil are well distributed on both sides of the wall section.

The first connection (bidirectional) can be assigned to the first refrigerant extraction area and the third connection (unidirectional refrigerant extraction) can be assigned to the second refrigerant extraction area or vice versa. This ensures that liquid refrigerant is removed through the third connection (unidirectional refrigerant extraction) with no or only a minimal proportion of gaseous refrigerant.

The refrigerant collector described above can be installed or installed on the high pressure side in a refrigeration system with heat pump function.

For the sake of completeness, it should be noted that in the case of refrigerant collectors that have outlets (connections with refrigerant extraction) at the bottom, it should be noted that any oil leakage into the refrigeration system system can be prevented by design. For example, a retaining device can be provided in an outgoing connection path, for example in the form of a siphon, so that the oil is held in the refrigerant collector.

The above-mentioned task is also solved by a refrigeration system with a heat pump function
a compressor connectable or connected to a primary train and a secondary train; and
a refrigerant collector connected to the primary line and the secondary line, which is designed in accordance with the above statements,
wherein the primary line comprises a bidirectional flow-through heat exchanger as a refrigeration system condenser or as a heat pump evaporator, and an evaporator with an expansion element arranged upstream, and wherein the secondary line comprises a heating condenser.

In this refrigeration system with heat pump function, the first connection of the refrigerant collector can be connected to the heat exchanger of the primary train, the second connection of the refrigerant collector can be connected to the heating condenser of the secondary train, and the third connection of the refrigerant collector can be connected to the evaporator of the primary train. As a result, the heat exchanger of the primary line can be flowed through bidirectionally and, accordingly, refrigerant can flow from the heat exchanger to the refrigerant collector or vice versa.

The invention also relates to a motor vehicle, in particular an electrically driven motor vehicle, with a refrigeration system with a heat pump function described above.

• 1 ein schematisches Diagramm eines Beispiels einer Kälteanlage mit Wärmepumpenfunktion und einem Kältemittelsammler mit drei Anschlüssen;
• 2 zwei schematische Bauformen von Kältemittelsammlern;
• 3 in den Teilfiguren a) bis h) acht mögliche Anordnungen von jeweils drei Anschlüssen an dem Kältemittelsammler;
• 4 in den Teilfiguren A) bis C) den Kältemittelsammler mit einem im unteren Bereich angeordneten Umlenkelement unterschiedlicher Ausgestaltung.

Further advantages, features and details of the invention emerge from the patent claims, the following description of preferred embodiments and the drawings. This shows:

• 1 a schematic diagram of an example of a refrigeration system with heat pump function and a refrigerant receiver with three connections;
• 2 two schematic designs of refrigerant collectors;
• 3 in subfigures a) to h) eight possible arrangements of three connections each on the refrigerant collector;
• 4 in the partial figures A) to C) the refrigerant collector with a deflection element of different designs arranged in the lower region.

1 shows a schematic circuit diagram of a refrigerant system 10 with heat pump function. The refrigerant system 10 includes a compressor 12, to which a valve device 14 is connected. By means of the valve device 14, refrigerant can be directed to a primary line (to the left in the diagram) and/or a secondary line (to the right in the diagram), depending on the desired operating mode of the refrigeration system 10.

The primary line includes a bidirectional flow-through heat exchanger 16 and an evaporator 18. A so-called chiller 20 is shown parallel to the evaporator 18. In the diagram shown, the primary line is guided from above into a refrigerant collector 22. The secondary line includes a heating condenser 24 and is led into the refrigerant collector 22 from the left in the diagram shown.

Possible positions at which pressure/temperature sensors can be arranged are marked with pT1 to pT5, whereby the number of corresponding sensors and their exact positioning can also be adapted to other configurations.

A1 or AE1 to AE4 denote shut-off elements or expansion elements which are used in a manner known per se in such a refrigeration system 10 are arranged. R3 and R4 are two examples of check valves marked.

The refrigerant collector 22 has three connections in the refrigeration system 10 shown. A first connection 26, which is drawn in the diagram from above to the refrigerant collector 22, is a bidirectional connection in which in refrigeration operation (AC operation) refrigerant flows from the heat exchanger 16 into the refrigerant collector 22 and in heat pump operation refrigerant flows out of the refrigerant collector 22 in the direction of the heat exchanger 16 is conducted.

A second connection 28 to the refrigerant collector 22 is shown on the left of the refrigerant collector 22 in the diagram. The second port is a unidirectional port through which refrigerant is supplied to the refrigerant collector 22.

A third connection 30 to the refrigerant collector 22 is drawn on the right of the refrigerant collector in the diagram. The third connection 30 is a unidirectional connection through which refrigerant is directed from the refrigerant collector 22 in the direction of the evaporator 18 and/or in the direction of the chiller 20.

In the AC mode, for example, refrigerant is conveyed from the compressor 12 to the heat exchanger 16, which works as a condenser. The refrigerant then reaches the refrigerant collector 22 via the shut-off device AE2 via the first connection 26. From there, the refrigerant is passed to the evaporator 18 via the third connection 28. The refrigerant then flows back to the compressor 12 via the check valve R3.

In a heat pump mode, for example an air heat pump mode, the valve unit 14 is switched so that the refrigerant conveyed by the compressor 12 is conveyed into the secondary line and to the heating condenser 24. The refrigerant flows from the heating condenser 24 via the shut-off device A1 into the refrigerant collector 22. From the refrigerant collector 22, the refrigerant is directed to the heat exchanger 16 via the bidirectional connection 26 (first connection). From there it reaches the check valve R4 via the correspondingly switched valve unit 14 and back to the compressor 12.

With the illustrated refrigeration system 10 with heat pump function, other operating modes known per se are also possible, such as water heat pump mode and reheat mode, which will not be discussed specifically here.

The refrigeration system 10 shown here is characterized by the refrigerant collector 22, which has three connections 26, 28, 30 and the structure of which is described in more detail below.

2 shows in two simplified and schematic representations how a refrigerant collector 22 is usually designed. The refrigerant collector 22 has a substantially cylindrical collector housing 32. The collector housing can have a bottom section 34 that is concavely curved inwards. Alternatively, the bottom section 34 can also be straight, which is shown on the left. The cover section 36 can be straight, which is shown in both the left and right illustrations. The cover section 36 can also be curved, as shown in dashed lines on the left.

In the 2 It can also be seen that liquid refrigerant 40 collects in a lower area 38 of the refrigerant collector 22, which is indicated by its schematic level 42. Gaseous refrigerant is usually located in an upper region 44 of the collector housing 32. The designation lower area 38 or upper area 44 of the collector housing 32 or the refrigerant collector 22 can be understood in particular to mean the lower and upper halves, or approximately 50% of the volume, of the collector housing 32 or the refrigerant collector 22 which is indicated by the imaginary dividing line TL50. However, the lower area 38 and the upper area 44 can only make up approximately 25% to 35% of the volume of the refrigerant collector 22, starting from a base section 34 or a cover section 36, which is indicated purely qualitatively by the further dividing lines TL25 .

In 3 Various combinations of the three connections 26, 28, 30 are shown schematically and in simplified form in subfigures a) to h). The first connection 26, which enables a bidirectional flow of refrigerant into and out of the refrigerant collector 22, is shown on the left. The second connection 28, which enables a unidirectional introduction of refrigerant into the refrigerant collector 22, is drawn in the middle. The third connection 30, which enables unidirectional removal of refrigerant from the refrigerant collector 22, is shown on the left. It should be noted that the arrangement of the three connections 26, 28, 30 is not limited to the sequence from left to right shown schematically here.

For everyone in the 3 The following similarities can be seen in the options shown for positioning the three connections 26, 28, 30. The first connection 26 (bidirectional) has a mouth illustrated by the corresponding arrowhead or removal opening 26a, which is always arranged in the lower region of the collector housing 32 or the cold collector 22. The second connection 28 (unidirectional) has an opening 28a, illustrated by the arrowhead, which is always arranged in the upper region of the collector housing 32 or the refrigerant collector 22. The third connection 30 (unidirectional) has a removal opening 30a which is always arranged in the lower region of the collector housing 32 or the refrigerant collector 22.

Each connection 26, 28, 30 has a corresponding connection point 46, 48, 50, at which the connection 26, 28, 230 is connected to the collector housing 32 or passes through the collector housing 32.

1. a) alle Anschlussstellen 46, 48, 50 im oberen Bereich (oberhalb der Linie TL50, siehe 2) oder
2. b) alle Anschlussstellen 46, 48, 50 im unteren Bereich (unterhalb der Linie TL50, siehe 2) oder
3. c) die erste Anschlussstelle 46 im oberen Bereich und die zweite und dritte Anschlussstelle 44, 50 im unteren Bereich oder
4. d) die zweite und dritte Anschlussstelle 48, 50 im oberen Bereich und die erste Anschlussstelle 46 im unteren Bereich oder
5. e) die erste und zweite Anschlussstelle 46, 48 im oberen Bereich und die dritte Anschlussstelle 50 im unteren Bereich oder
6. f) die erste und dritte Anschlussstelle 46, 50 im oberen Bereich und die zweite Anschlussstelle 48 im unteren Bereich oder
7. g) die dritte Anschlussstelle 50 im oberen Bereich und die erste und zweite Anschlussstelle 46, 48 im unteren Bereich oder
8. h) die zweite Anschlussstelle 48 im oberen Bereich und die erste und dritte Anschlussstelle 46, 50 im unteren Bereich.

The first connection point 46 for the first connection 26, the second connection point 48 for the second connection 28 and the third connection point 50 for the third connection 30 can be in accordance with 3 so be arranged on the collector housing as follows:

1. a) all connection points 46, 48, 50 in the upper area (above the line TL50, see 2 ) or
2. b) all connection points 46, 48, 50 in the lower area (below line TL50, see 2 ) or
3. c) the first connection point 46 in the upper area and the second and third connection points 44, 50 in the lower area or
4. d) the second and third connection points 48, 50 in the upper area and the first connection point 46 in the lower area or
5. e) the first and second connection points 46, 48 in the upper area and the third connection point 50 in the lower area or
6. f) the first and third connection points 46, 50 in the upper area and the second connection point 48 in the lower area or
7. g) the third connection point 50 in the upper area and the first and second connection points 46, 48 in the lower area or
8. h) the second connection point 48 in the upper area and the first and third connection points 46, 50 in the lower area.

Due to the position of its mouth or removal opening 26a, 28a, 30a specified for each connection 26, 28, 30 within the collector housing 32 and depending on the position of the corresponding connection point 46, 48, 50, the connections in certain exemplary embodiments have a respective one in the collector housing 32 extending line section 26b, 28b, 30b, which extends both through the lower area and in the upper area of the collector housing, see in particular examples a) to g), in each of which at least one such line section for one of the connections 26, 28, 30 is available.

Even if in the schematic representation of the 3 the connection points are each shown in the cover section 36 and base section 34 (Fig: 2), the connection points 46, 48, 50 can also be arranged in the side wall. The side wall or side walls are those areas of the collector housing which connect the cover section 36 and the base section 34 to one another. With regard to the concept of the refrigerant collector with three connections presented here, it should only be noted that a connection point, which is provided in the side wall, is also arranged in the upper area 44 or the lower area 38.

4 shows at A) the collector housing 32 of the refrigerant collector 22 in a simplified sectional view in two mutually essentially orthogonal sectional planes. From the left representation of the 4A a deflection element 52 can be seen. The deflection element 52 is arranged in the area of the bottom section 34 of the collector housing 32. The deflection element 52 extends from the bottom section 34 into the interior of the collector housing 32.

In the 4A On the left, the first connection 26 (bidirectional) and the third connection 30 (unidirectional removal) are also shown in simplified form by corresponding arrows. Two removal areas 54, 56 are formed in the lower area of the collector housing by the deflection element 52. In the present example, the mouth 26a of the first connection 26 is arranged in the first removal area 54. The removal opening 30a of the third connection 30 is in the second removal area 56 arranged. The deflection element 52 serves in particular to deflect gas bubbles 58 formed upwards towards the upper region of the collector housing when at least partially gaseous refrigerant is introduced through the first (bidirectional) connection 26. The aim is to prevent gas bubbles 58 arising in the first removal area 54 from reaching the second removal area 56, from which liquid refrigerant should be removed using the third connection, if possible without gas bubbles.

In order to ensure circulation of liquid refrigerant between the two removal areas 54, 56, the deflection element 52 can have at least one opening 60. The at least one opening should be in the area if possible a lowest point of the collector housing 32 or the deflection element 52 can be arranged. Instead of just one opening 60, several possibly smaller openings can also be present in the deflection element. According to 4A the deflection element is designed as a type of wall section that protrudes upwards from the bottom section 34.

According to a modification, the deflection element 52, which is designed as a wall section, cannot extend laterally as far as the collector housing 32, which is shown, for example, in 4B) is shown. The gap 62 formed between the collector housing 32 and the deflection element, which is in particular designed like a slot, in this case enables the circulation of liquid refrigerant between the two removal areas 54, 56. In other words, between an end face 53 of the wall section and the inside of the collector housing 32 a slot-like flow area 62 is formed, through which the first refrigerant removal area 54 and the second refrigerant removal area 56 are in fluid communication. In this embodiment of the deflection element 52, it is not mandatory, necessary, but still possible for at least one further opening to be provided on the deflection element.

A further embodiment of the deflection element 52 is shown in 4C shown. Here the deflection element 52 has a grid-like or net-like structure. The grid or network is designed in such a way that introduced gas bubbles are deflected upwards without them being able to pass through the holes in the grid or network. However, the grid or network allows liquid refrigerant to pass through, so that exchange can take place between the two removal areas 54, 56.52.

For everyone in the 4 In the examples shown of a deflection element 52, it should also be noted that a height HU of the deflection element 52 measured starting from the bottom section 34 can be selected. The height HU of the deflection element 52 can be approximately 25% to 75% of the internal height. HI of the collector housing 32 correspond. Furthermore, it should be noted that the mouth 26a of the first (bidirectional) connection 26 is, if possible, aligned so that introduced, at least partially gaseous refrigerant does not flow directly in the direction of an opening 60 or the grid ( 4C ) is guided, but is introduced, for example, essentially parallel to the deflection element 52. In the case of a deflection element 52 that is not laterally connected to the collector housing 32 ( 4B) For example, the mouth 26a can be aligned centrally and in the direction of the deflection element 52, so that incoming refrigerant flows out in the direction of the deflection element 52.

Finally, it should be noted that the connections shown can be formed from several interconnected tube-like pieces or hoses. These can be straight or curved and are designed appropriately depending on the installation position of the refrigerant collector in a refrigeration system.

Claims (14)

Refrigerant collector (22) for a refrigeration system (10) with heat pump function of a motor vehicle, in particular an electrically driven motor vehicle, with a collector housing (32) in which gaseous refrigerant is stored in an upper region (44) relative to an installed position in a refrigeration system (10). and liquid refrigerant (40) can be collected in a lower region (38), three connections (26, 28, 30) arranged on the collector housing (32), a first connection (26) being designed to supply refrigerant bidirectionally to the refrigerant collector (22 ) towards or away from it, a second connection (28) is designed to direct refrigerant unidirectionally to the refrigerant collector (22), and a third connection (30) is designed to direct refrigerant unidirectionally from the refrigerant collector (22 ) away, each connection (26, 28, 30) being connected to the collector housing (32) at a respective connection point (46, 48, 50), characterized in that the second connection (28) is inside the collector housing ( 32) is set up so that refrigerant is directed into the upper area (44) of the collector housing (32). Refrigerant collector Claim 1 , characterized in that the first connection (26) inside the collector housing (32) is set up so that refrigerant is directed into the lower region (38) of the collector housing (32). Refrigerant collector Claim 1 or 2 , characterized in that the first connection (26) and the third connection (30) inside the collector housing (32) are set up so that liquid refrigerant (40) can be removed from the lower region (38) of the collector housing (32). Refrigerant collector according to one of the preceding claims, characterized in that the first connection point (46) for the first connection (26), the second connection point (48) for the second connection (28) and the third connection point (50) for the third connection (30) are arranged on the collector housing (32) as follows: all connection points (46, 48, 50) in the upper area or all connection points (46, 48, 50) in the lower area or the first connection point (46) in the upper area and the second and third connection points (48, 50) in the lower area or the second and third connection points (48, 50) in the upper area and the first connection point (46) in the lower area or the first and second connection points (46, 48) in the upper area and the third connection point (50) in the lower area or the first and third connection point (46, 50) in the upper area and the second connection point (48) in the lower area or the third connection point (50) in the upper area and the first and second connection points (46, 48) in the lower area or the second connection point ( 48) in the upper area and the first and third connection points (46, 50) in the lower area. Refrigerant collector according to one of the preceding claims, characterized in that in the lower region of the collector housing (32) a deflection element (52) which projects inwards from a bottom section (34) of the collector housing (32) and influences the flow of the refrigerant is arranged. Refrigerant collector Claim 5 , characterized in that the deflection element (52) is designed to deflect gaseous coolant introduced in the lower region (38) of the refrigerant collector (32) towards the upper region (44), so that gaseous coolant collects in the upper region (44). . Refrigerant collector Claim 6 , characterized in that the deflection element (52) is a wall section which is designed such that a first refrigerant removal area (54) and a second refrigerant removal area (56) are formed in the lower area (38) of the refrigerant collector (32). Refrigerant collector Claim 7 , characterized in that at least one opening (60) is formed in the wall section (52), which provides a fluid connection between the first refrigerant removal area (54) and the second refrigerant removal area (56). Refrigerant collector Claim 7 , characterized in that the wall section (52) is dimensioned such that a slot-like flow area (62) is formed between an end face (53) of the wall section and the inside of the collector housing (32), through which the first refrigerant removal area (54) and the second refrigerant removal area (56) are in fluid communication. Refrigerant collector according to one of the Claims 7 until 9 , characterized in that the first connection (26) is assigned to the first refrigerant removal area (54) and the third connection (30) is assigned to the second refrigerant removal area (56) or vice versa. Refrigerant collector according to one of the preceding claims, characterized in that the refrigerant collector (32) can be installed or is installed on the high-pressure side in a refrigeration system (10) with heat pump function. Refrigeration system (10) with heat pump function a compressor (12), which has a primary line and a. Secondary strand is connectable or connected; and a refrigerant collector (22) connected to the primary line and the secondary line according to one of the preceding claims, wherein the primary line comprises a bidirectional flow-through heat exchanger (16) as a refrigeration system condenser or as a heat pump evaporator, and an evaporator (18) with an expansion element (AE2) arranged upstream, and wherein the secondary strand comprises a heating capacitor (24). Refrigeration system with heat pump function Claim 12 , characterized in that the first connection (26) of the refrigerant collector (22) is connected to the heat exchanger (16) of the primary line, the second connection (28) of the refrigerant collector (22) is connected to the heating condenser (24) of the secondary line, and the third connection (30) of the refrigerant collector (22) is connected to the evaporator (18) of the primary line. Motor vehicle, in particular an electrically powered motor vehicle, with a refrigeration system (10) with a heat pump function Claim 12 or 13 .

Images