DE102022124644A1 - Connector part for mechanical and electrical connection with a mating connector part - Google Patents

Abstract

The invention relates to a connector part for mechanical and electrical connection to a mating connector part, in particular a motor vehicle charging socket (1) for coupling to a charging plug as part of an electrical charging infrastructure for electric or hybrid motor vehicles, or vice versa. For this purpose, a housing (2, 3) and at least one electrical contact element (4) arranged in the housing (2, 3) are provided. In addition, a passively cooled heat line (7), which is connected at one end (7a) to the contact element (4) and has a liquid cooling module (8) at its other end (7b). According to the invention, the heat line (7) passes through a housing opening (2a, 3a) and is equipped outside the housing (2, 3) with the liquid cooling module (8) arranged there.

Description

The invention relates to a connector part for mechanical and electrical connection to a mating connector part, in particular a motor vehicle charging socket for coupling to a charging plug as part of an electrical charging infrastructure for electric or hybrid motor vehicles, or vice versa, with a housing made of plastic and at least one arranged in the housing electrical contact element, and with a preferably passively cooled heat line, which is connected to the contact element at one end and has a liquid cooling module at its other end.

The connector part is generally a charging socket in a motor vehicle, which can be coupled to an associated charging plug that is present, for example, on an electric charging station. In the course of the coupling, an electrical and at the same time mechanical connection is achieved and brought about between the charging socket and the charging plug. The charging plug, like the charging socket, is part of the electrical charging infrastructure, with the help of which the rechargeable energy storage devices or accumulators of electric or hybrid motor vehicles can be charged. In principle, the connector part on the motor vehicle can also be a charging plug instead of a charging socket. In this case, the charging station is equipped with an associated charging socket. As a rule, however, the electric or hybrid motor vehicle has the charging socket with several electrical contact elements arranged in the housing, into which the charging plug connected to the charging station is inserted for electrically charging the motor vehicle in question.

In order to be able to supply high electrical outputs of the electric motors present in the motor vehicle in question with the required electrical energy on the one hand and to provide sufficient range on the other hand, high-voltage batteries or accumulators are now used, which typically use high-voltage direct voltage Loading. In addition to such DC charging processes (direct current), most electric or hybrid motor vehicles also allow the possibility of charging via an alternating voltage in the sense of an AC charging process (alternate current). At this point, however, low currents and long charging times are usually used, whereas in the DC charging process described above, high voltages and high currents and the resulting short charging times are observed. Particularly in DC charging processes, due to the high current intensity of up to several tens of amperes or more, there is the fundamental problem that the electrical contact elements used at this point become increasingly warm. This increases their resistance, which hinders the electrical charging process and the desired rapid charging.

For this reason, the state of the art works according to the EP 3 446 372 B1 already with a heat pipe, which is connected at its first end to a metal connector. In addition, a heat sink is provided which serves to dissipate heat from the at least one contact element.

However, the previously known teaching is aimed at the design of a charging plug and not a charging socket. In any case, the heat loss from the electrical contact element can only be inadequately dissipated via the heat conduction to the heat sink via the heat sink arranged in the housing. This can be attributed, among other things, to the fact that the housing of the charging plug is completely closed because such charging plugs are installed as components of the charging infrastructure in the area of electric charging stations, which in turn are generally exposed to the weather and in particular rain without protection.

Although there is further prior art according to the DE 20 2019 102 461 U1 or according to the DE 10 2015 013 296 A1 There are already attempts to intensify cooling with a fan. However, this does not change the fundamental problem of heat dissipation from the housing.

The previously known teachings of the EP 4 000 989 A1 and EP 4 000 992 A1 In this case, too, the heat sink is located inside the housing, whereby, due to the housing, a heat build-up can possibly be observed at this point depending on the heat loss that occurs.

The invention is based on the technical problem of further developing such a connector part in such a way that the overall heat dissipation is improved compared to the prior art.

To solve this technical problem, the invention proposes, in the case of a generic connector part for mechanical and electrical connection to a mating connector part, that the heat conduction passes through a housing opening and outside the housing, i.e. in an external area, with which at least one liquid cooling module arranged there is equipped.

The invention therefore initially relies on at least one particularly passively cooled heat pipe or a “heat pipe” used at this point. This heat conduction in the form of a preferably metallic tube is now connected at one end to the electrical contact element in a heat-conducting manner. At the other end, the liquid cooling module is provided, so that a total heat conduction connection is available from the electrical contact element via the heat conduction to the liquid cooling module. For this purpose, the liquid cooling module is also connected in a heat-conducting manner to the heat pipe or the metallic pipe provided at this point.

Advantageously, the at least one liquid cooling module has a metal with good thermal conductivity, in particular aluminum and/or copper, or a ceramic material, in particular aluminum oxide and/or aluminum nitride.

Liquid cooling uses in particular water, preferably distilled or demineralized water, to transport heat. For this purpose, the cooling liquid, in particular water, is supplied to the liquid cooling module through at least one connection element and removed again via at least one further connection element. The connection elements are preferably screw connections, grommets or plug-in connections. Lines for the coolant are connected to the connection elements. The lines preferably have polyurethane, polyvinyl chloride, Tygon or Norprene.

The lines are therefore used to transport the coolant within a cooling circuit. This cooling circuit preferably has at least one pump, at least one radiator and/or an expansion tank. The radiator particularly advantageously has a plurality of fins, in particular made of copper or aluminum. The radiator can also preferably have a fan that cools the radiator with an air flow. It can also be advantageous if there is a pre-chamber (i.e. a gap between the fan and the radiator) between the fan and the radiator. This can prevent the dead center above the fan hub. The air swirls through such a pre-chamber and is guided evenly through the radiator everywhere. This can increase the cooling performance.

Liquid cooling by means of the liquid cooling module according to the invention enables particularly efficient cooling of the heat conduction and thus the contact elements of the charging socket.

Of particular inventive importance is the further circumstance that the at least one heat line passes through a housing opening, i.e. is guided outside the housing. The liquid cooling module arranged or attached there is then found in this external area. As a result, heat generated on or in the electrical contact element can be dissipated particularly effectively via the heat conduction to the liquid cooling module, which in turn is arranged outside the housing and can therefore release the resulting heat particularly effectively.

The invention is based on the knowledge that such connector parts in the form of a charging socket are typically installed in the area of a body opening on or in a motor vehicle. The body opening can be found, for example, in a front or rear fender, above or even in a wheel arch. At this point, there is generally not only enough installation space available for the connector part or the charging socket, but at the same time it is also guaranteed that the liquid cooling module provided outside the housing can easily communicate with, for example, ambient air. At the same time, the liquid cooling module is also protected from rain or stone chips because it is usually found in the wheel arch behind a wheel cover. In any case, this provides particularly intensive heat dissipation and phenomena such as possible heat build-up due to a closed housing, as in the prior art, can be avoided from the outset and due to the design. This is where the main advantages can be seen.

It is also conceivable that a plurality (i.e. more than one) of heat lines, preferably between 2 and 5 heat lines, connect the contact element to the liquid cooling module at least in a heat-conducting manner.

As part of a further advantageous embodiment, the at least one heat line has electrical insulation at least in the outside area and in relation to the liquid cooling module provided there. The electrical insulation usually extends through the housing opening into the interior of the housing. The invention is based on the knowledge that the heat conduction, as already explained, is preferably a metallic tube. The metallic tube can z. B. also enclose a hermetically encapsulated volume. The volume is in turn filled with a working medium for heat transport, for example water.

In any case, heat is transported overall starting from the electrical contact element as a heat source via the at least one, preferably passively cooled heat line (Heat pipe) to the liquid cooling module as a heat sink. Since the electrical contact element as well as the liquid cooling module are preferably made of metal and the heat conduction is advantageously the metallic tube already described, electrical insulation of the liquid cooling module and the area of the heat conduction in the external area, ie outside the housing, is advantageous. This is ensured by the electrical insulation in the outside area and in relation to the liquid cooling module provided there. That is, the liquid cooling module is electrically insulated from heat conduction using insulation. For this purpose, the electrical insulation extends through the housing opening into the interior of the housing, so that both the liquid cooling module and the heat conduction outside carry no voltage or current. The electrical insulation can be a plastic coating on the metallic pipe in the desired area. In principle, the electrical insulation can also be designed as a shrink tube or other plastic covering for the metallic tube.

The electrical insulation in the area of the housing opening may also act as a seal for the housing opening. In principle, an additional seal can also be provided in the area of the housing opening.

In order to further intensify the cooling effect and thus the heat transport from the electrical contact element via the heat conduction to the liquid cooling module, the liquid cooling module can be equipped with at least one additional coolant. Then there is an active cooling of the heat conduction. The coolant is usually at least one electrically driven fan and/or a previously described radiator. This allows the cooling effect of the liquid cooling module to be additionally increased through convection. For this purpose, the at least one fan may be controlled by a control unit, at least during the electrical charging process. In principle, the coolant, especially the fan, can be operated for a certain time even after the charging process has ended. A fan according to the invention can preferably be designed as an axial or radial fan. In addition, it is conceivable that two or more fans are provided. It is also conceivable that fans of different dimensions or designs (axial or radial fans) are provided. In particular if the liquid cooling module and/or the radiator has a plurality or plurality of fins, it is particularly preferred that the at least one fan is arranged on the liquid cooling module and/or the radiator in such a way that the generated air flow flows around the fins, so that the cooling capacity can be further increased. Furthermore, it is conceivable that the fan is integrated at least in sections in the liquid cooling module and/or radiator.

Particularly preferably, the fan and/or the control unit can be connected to at least one sensor for monitoring the temperature and/or the fan speed and/or the air flow of the fan. The control unit is in particular designed such that the fan can be controlled and/or regulated depending on the temperature. The fan speed can also be adjusted accordingly. This can particularly improve acoustic comfort.

Furthermore, it is conceivable that the fan has at least one damping means to reduce vibration. In particular, the fan can be attached to the liquid cooling module and/or the radiator, for example with decoupler pins. This avoids direct contact of the fan or fan housing with the particularly metallic liquid cooling module and/or radiator. Alternatively or additionally, a support frame can be provided for the fan, which is arranged between the fan and the liquid cooling module and/or radiator and also avoids direct contact between the fan and the liquid cooling module and/or radiator. The base frame or the decoupler pins are preferably made of rubber or at least have rubber.

As already described in the introduction, the preferably passively cooled heat line is connected at one end to the contact element. This is usually done in such a way that the relevant end of the heat conduction is inserted into the contact element. Here, an embodiment has proven to be advantageous in which the heat conduction predominantly runs perpendicular to the longitudinal extent of the contact element.

That is, the heat conduction or the metallic tube provided at this point extends regularly perpendicular to the longitudinal extent of the contact element and consequently also to a plugging direction of the mating connector part, with which the mating connector part is electrically and mechanically connected to the plug connector part. As a result, the liquid cooling module provided outside the housing of the connector part can easily be placed above or below the housing and can communicate there with the ambient air during an electrical charging process of the motor vehicle, as already described in the introduction.

In this context, it is advantageous to proceed in such a way that the heat line dips in an arc shape into an upper opening of a connection piece of the contact element. This means that the arrangement of the heat line predominantly perpendicular to the longitudinal extension of the contact element requires a curved guide of the heat line for the heat-conducting connection with the electrical contact element, namely in such a way that the heat line dips in an arc shape into the upper opening of the connection piece.

In principle, the heat conduction can also extend straight or predominantly straight into the top opening of the connecting piece in question and in this way form the desired heat-conducting connection with the connecting piece and thus the contact element.

In both cases, the connecting piece is in turn electrically and thermally connected to the contact element. For this purpose, the connecting piece can be coupled to the contact element or otherwise, for example, by a plug connection. A one-piece design of a connecting piece on the one hand and a contact element on the other is also possible.

The top opening in the connecting piece is typically a half-cylinder opening if the heat conduction is curved in this area. This is because the connecting piece, like the contact element, is generally cylindrical. In the event that the heat conduction is predominantly connected to the connecting piece, the top opening in the connecting piece is typically designed as a cylinder bore.

Either way, the heat conduction is first received in a hollow hole in the connecting piece of the contact element and held therein and then leaves the connecting piece in question via the arch or predominantly straight via the top opening of the connecting piece, and then in the predominantly vertical course in comparison to the longitudinal extent of the contact element to be able to move over or to maintain this vertical course. As a result, a particularly favorable heat conduction is provided and achieved because one end of the heat conduction is immersed in the associated hollow bore in the connecting piece and the connecting piece with the hollow bore encloses the said end of the heat conduction.

Here there is intimate thermal contact between the connecting piece and the heat pipe. In addition, since the connecting piece is electrically and thermally conductively connected to the contact element, any heat loss generated at the contact element is transferred particularly effectively to the heat line, which in turn transports the resulting heat all the way to the liquid cooling module.

Since the electrical insulation already mentioned is usually provided at this point between the other end of the heat line and the liquid cooling module, it is important to use electrical insulation that is electrically insulating but at the same time heat-conducting. Here, thermoplastics have proven to be favorable, which are designed as plastic injection molded parts or are suitable for overmolding the metallic pipe in the relevant area. Such thermoplastics such as PP (polypropylene), PA (polyamide), PBT (polybutylene terephthalate), PE (polyethylene) etc. typically have thermal conductivities that are, for example, 0.23W/(m x K) for polypropylene (PP) or for polyamides up to 0.35W/m x K). In connection with polyethylene (PE), values of approx. 0.5W/(m x K) are observed.

To increase thermal conductivity while still maintaining electrical insulation, the plastics mentioned above can also be equipped with embedded fillers. In this context, fillers that are electrically insulating and at the same time thermally conductive have proven to be particularly favorable. These include, for example, aluminum compounds or drilling compounds, particularly preferably aluminum oxide or boron nitride.

This allows the thermal conductivity of the plastic in question to be increased by at least a factor of 3.

As a result, a connector part for mechanical and electrical connection to a mating connector part is provided and realized, which has significantly improved heat transport compared to the prior art. This can essentially be attributed to the fact that the liquid cooling module has been moved along the heat line to the outside of a housing, preferably made of plastic, so that particularly effective convection with, for example, ambient air is observed at this point. This is where the main advantages can be seen.

• 1 das erfindungsgemäße Steckverbinderteil in einer perspektivischen Rückansicht,
• 2 das Steckverbinderteil nach der 1 teilweise aufgebrochen in einer perspektivischen Seitenansicht.
• 3 eine abgewandelte Ausführungsform vergleichbar der 2.

The invention is then explained in more detail using a drawing that only shows an exemplary embodiment; show it:

• 1 the connector part according to the invention in a perspective rear view,
• 2 the connector part after the 1 partially broken away in a perspective side view.
• 3 a modified embodiment comparable to that 2 .

The figures show a connector part for mechanical and electrical connection to a mating connector part. In fact, the connector part in the exemplary embodiment is according to the 1 and 2 around a vehicle-side charging socket 1. The charging socket 1 is set up for coupling with a charging plug, which is not shown in detail. The charging plug and the charging socket 1 each represent part of an electrical charging infrastructure for electric or hybrid motor vehicles. For this purpose, the charging plug (not shown) is inserted into the charging socket 1 in the direction of the in the 2 indicated arrow S is inserted, which represents the relevant plugging direction S at this point to unite charging socket 1 and charging plug.

The charging socket 1 is equipped with a housing 2, 3, which consists of a front cover 2 and a rear cover or back cover 3 that can be connected to it, which can be seen in particular in the rear view according to 1 can recognize. Several electrical contact elements 4 are then arranged and provided in the housing 2, 3, which are contact elements 4 for a DC charging process. For this purpose, the electrical contact elements 4 are each electrically and thermally coupled to a connecting piece 5, which can be seen in particular based on the illustration in the 2 can understand. The respective electrical contact elements 4 and the connecting piece 5 can in principle also be designed in one piece; in any case, according to the exemplary embodiment - as described - they are electrically and thermally coupled to one another.

In addition to the electrical contact elements 4 for the DC charging process already mentioned, further contact elements 6 are also implemented, which are required for an AC charging process, but are of no importance for the subsequent considerations. Rather, the electrical contact elements 4 are considered for the DC charging process because this involves a high electrical current.

Additionally and essentially, a passively cooled heat pipe 7 is also implemented, which according to the exemplary embodiment is a “heat pipe” or a metallic tube already described at the beginning, which preferably has the already described hermetically coupled volume inside and a working medium for the Has heat transport. For this purpose, the metallic tube or heat pipe 7 has a defined length and is closed at both ends. For heat transport, the relevant heat line 7 is thermally coupled at one end 7a to the contact element 4 or the connecting piece 5. The other end 7b of the passively cooled heat line 7 is thermally coupled to a liquid cooling module 8. According to the exemplary embodiment, two electrical contact elements 4 are implemented (DC charging process), which are each thermally coupled to the one common liquid cooling module 8 via associated and also two heat lines 7. This provides a thermal connection from the relevant electrical contact element 4 or the associated connecting piece 5 via the passively cooled heat line 7 to the liquid cooling module 8. For this purpose, the liquid cooling module has at least the two connecting elements 8.1 shown, whereby the coolant can be diverted back and forth (or passed through), so that the coolant circulates in the cooling circuit. In particular, the coolant is transported by a pump in the cooling circuit and pumped between a radiator, an expansion tank and the module 20.

Of particular importance is the fact that, according to the invention, the heat conduction 7 passes through a housing opening 2a, 3a. In fact, the housing opening 2a in question is found on the one hand in the front housing or the front cover 2 and on the other hand as a further housing opening 3a in the rear housing or the back cover 3, as can be seen when comparing the 1 and 2 can understand. Of course, this only applies as an example and is in no way restrictive. In any case, the design is made in such a way that the heat conduction 7 passes through the relevant housing opening 2a, 3a and as a result the liquid cooling module 8 can be arranged in the outside area, ie it is arranged outside the housing 2, 3. In this outer area of the housing 2, 3, the liquid cooling module 8 can release heat to the ambient air particularly effectively through convection, as already described in the introduction.

Since the heat line 7 in the exemplary embodiment is designed as a metallic tube and is heat-conducting and therefore also electrically connected to the contact element 4 or the connecting piece 5 electrically connected thereto, an additional electrical insulation 9 is provided, at least in the outside area and in relation to the liquid cooling module provided there 8. According to the exemplary embodiment, the electrical insulation 9 is a sheathing of the heat conduction 7 or the metallic raw material res made of plastic, which can be applied to the pipe in question in connection with a plastic injection molding process. In any case, the electrical insulation 9 is located in the outside area and opposite the liquid cooling module 8 provided there and extends through the housing opening 2a, 3a into the interior of the housing 2, 3. This can be seen particularly from the 2 , from which it can be seen that the electrical insulation 9 extends several millimeters up to 1 cm or even more into the interior of the housing 2, 3 through the relevant opening 2a, 3a. In this way, the electrical insulation 9 made of plastic also functions as a seal for the housing opening 2a, 3a, so that the housing 2, 3 is designed to be splash-proof.

The electrical insulation 9 is made of a plastic, which has already been referred to and described in the introduction, and is therefore designed to be electrically insulating and at the same time heat-conducting. For this purpose, the plastic in question can be equipped with appropriate fillers, which are also described in the introduction. In any case, the electrical insulation 9 as a whole ensures that the relevant heat line 7 in the outer area of the housing 2, 3 does not carry any voltage and no current can flow through it, but at the same time the required heat conduction is still possible starting from the electrical contact element 4 via the heat line 7 up to to the liquid cooling module 8 is observed.

It can be seen that one end 7a of the heat line 7 is inserted into the contact element 4 or the associated connecting piece 5, namely into a corresponding hollow bore in the connecting piece 5 that is adapted to the heat line 7. The heat line 7 runs inside the housing 2, 3 predominantly perpendicular to the longitudinal extent of the contact element 4 and thus also of the connecting piece 5. Consequently, the heat pipe 7 in question also has a predominantly vertical arrangement in comparison to the previously described plug-in direction S.

As a result of this, the heat conduction 7 in the exemplary embodiment according to the 2 arcuately inserted into a top opening 5a of the connecting piece 5 of the contact element 4 and dips into this top opening 5a. Since, according to the exemplary embodiment, both the connecting piece 5 and the contact element 4 are each cylindrical, the top opening 5a is in the variant according to 2 designed as a half cylinder opening. Of course, this only applies as an example and is in no way restrictive.

Because with the variant according to the 3 The procedure is such that the heat conduction 7 predominantly dips straight into the top opening 5a of the connecting piece 5 of the contact element 4, which is also realized in this case. The top opening 5a in question is designed in this case as a cylinder bore or hollow cylinder bore because the heat pipe 7 is tubular or cylindrical according to the exemplary embodiment. In both cases, the heat line 7 is thermally coupled to the connecting piece 5 and thus to the contact element 4 in this way.

Reference symbol list

1

charging socket

2

Front cover

2a, 3a

Case opening

2, 3

Housing

2

Front cover

3

Back cover 3

4

Contact elements

5

Connector

5a

opening

6

Contact elements

7

Heat conduction

7a

End

7b

End

8th

Liquid cooling module

8.1

Liquid cooling module

9

insulation

10

coolant

10

Fan

S

arrow

S

Plugging direction

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 3446372 B1 [0004]
• DE 202019102461 U1 [0006]
• DE 102015013296 A1 [0006]
• EP 4000989 A1 [0007]
• EP 4000992 A1 [0007]

Claims (10)

Connector part for mechanical and electrical connection to a mating connector part, in particular a vehicle-side charging socket (1) for coupling to a charging plug as components of an electrical charging infrastructure for electric or hybrid vehicles, with a housing (2, 3) and at least one in the housing (2, 3) arranged electrical contact element (4), and with at least one preferably passively cooled heat line (7), which is connected at one end (7a) to the contact element (4) and at its other end (7b) a liquid cooling module (8) has, characterized in that the at least one heat line (7) passes through a housing opening (2a, 3a) and is equipped outside the housing (2, 3) with the liquid cooling module (8) arranged there. Connector part Claim 1 , characterized in that the heat line (7) has electrical insulation (9), in particular outside the housing (2, 3) and relative to the liquid cooling module (8) provided there. Connector part Claim 2 , characterized in that the electrical insulation (9) extends through the housing opening (2a, 3a) into the interior of the housing (2, 3). Connector part according to one of the Claims 1 until 3 , characterized in that the liquid cooling module (8) is equipped with an additional coolant (10). Connector part Claim 4 , characterized in that the coolant (10) is designed as, for example, an electrically driven fan and/or radiator. Connector part according to one of the Claims 1 until 5 , characterized in that the heat pipe (7) is designed as a metallic tube, in particular that the tube encloses a hermetically encapsulated volume. Connector part Claim 6 , characterized in that the volume is filled with a working medium for heat transport, for example water or ammonia. Connector part according to one of the Claims 1 until 7 , characterized in that the heat line (7) is inserted at one end (7a) into the contact element (4) or a connecting piece (5) electrically connected thereto. Connector part according to one of the Claims 1 until 8th , characterized in that the heat conduction (7) runs predominantly perpendicular to the longitudinal extent of the contact element (4). Connector part according to one of the Claims 1 until 9 , characterized in that the heat conduction (7) dips arcuately or predominantly straight into a top opening (5a) of the connecting piece (5) of the contact element (4).

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