DE202023106429U1 - Compact charging connector for an electric vehicle - Google Patents

Abstract

Charging connector (1) for an electric vehicle, consisting of a body (2), a contact carrier (3) and a cable clamping part (7), the contact carrier (3) being arranged at one end of the body (2), which is arranged in a plug-in direction ( SR) can be inserted into a charging socket, with the cable clamping part (7) being arranged at the other end of the body (2), which serves to fix a charging cable (8) inserted into the body counter to the cable outlet direction (KR), the plug-in direction (SR ) and the cable outlet direction (KR) of the body (2) include an angle (α) that is 110° or smaller.

Description

The invention is based on a charging connector for an electric vehicle according to the preamble of independent claim 1. The invention further relates to a system in which such a charging connector is used, according to the preamble of claim 14.

Such charging connectors are used for charging electric vehicles, especially for charging electric cars in private environments.

State of the art

Charging cables, which are used particularly in private environments to charge electric vehicles, usually consist of an electrical charging cable, the ends of which are each connected to a charging connector. To charge the electric vehicle, a plug connector is plugged into a charging socket of a charging station, for example a home wallbox, and the other plug connector is plugged into a charging socket of the electric vehicle. Instead of in a wallbox, the connector can also be plugged into a socket on an external charging station or charging column. A corresponding charging current for the battery of the electric vehicle is then provided via the charging cable. The DE 10 2017 119 056 A1 shows a charging connector that can be used, for example, for such a charging process.

Due to the high charging currents, the charging cables and the conductors they contain have a large cross section. For easy handling and routing of the charging cable, charging connectors are angled. However, the cables often protrude far from the wallbox or charging station, which creates tripping hazards. This can not only result in injuries, but also damage to the charging station and the cable, namely if a charging connector is accidentally torn out of the socket when you stumble. Last but not least, this well-known charging situation causes passage restrictions, which are highly undesirable, especially in urban environments.

Task

The object of the invention is to provide a charging connector that enables charging in confined spaces and at the same time reduces the risk of damage to the charging infrastructure.

The task is solved by the subject matter of the independent claims.

Advantageous embodiments of the invention are specified in the subclaims and the following description.

The charging connector according to the invention is intended for charging an electric vehicle and in particular for charging a car with an electric motor and battery (electric car).

The charging connector has a particularly hollow cylindrical body, a contact carrier and a cable clamping part. The contact carrier is arranged at one end of the body. The contact carrier can be plugged into a charging socket of a wallbox and/or a charging column or charging station in the plugging direction (SR). The terms charging column and charging station are also used synonymously below.

The cable clamping part is arranged at the other end of the body. The cable clamping part is used to fix a cable inserted into the body in the opposite direction to the cable outlet direction.

According to the invention, the body is designed in an arc shape, whereby the plug-in direction and the cable outlet direction enclose an angle of 110° or smaller. This means that the charging cable runs as steeply as possible to the ground, i.e. flat along the wall (device wall of the wallbox or charging station or a carport, house or garage wall). This means there are no tripping hazards and the electric vehicle can be parked closer to the wall. The latter is a big advantage, especially in urban environments, for example in parking garages with charging facilities.

The plug-in direction and the cable outlet direction preferably run perpendicular to one another. This further increases the advantages mentioned above.

Advantageously, the contact carrier is at least partially arranged in a first opening in the body. A part of the contact carrier is arranged inside the body and another part of the contact carrier is located outside the body. The part located outside the body can be plugged into a charging socket, at least in some areas.

A flat seal is preferably arranged on the contact carrier. The flat seal is located on the part of the contact carrier located in the body. The flat seal protects the charging connector on the plug-in side from media ingress.

Advantageously, the contact carrier has screw openings that run parallel to the insertion direction (axially). These plug openings are correct with screw-in openings or metal screw-in sleeves that are attached or formed inside the body. This allows the contact carrier to be reversibly fixed to the body.

At the other end of the body, the cable clamping part is arranged in a second opening. The cable clamping part can have screw openings that run parallel to the plugging direction (axially). These plug-in openings correlate with screw-in openings or metallic screw-in sleeves in the body. This allows the cable clamping part to be reversibly fixed to the body. When screwed on, the seal is compressed, which means that the cable is clamped and sealed, especially for strain relief.

The contact carrier and the body advantageously consist of different materials. The body can, for example, be made of a robust but inexpensive plastic material, for example polypropylene, while the contact carrier is made of another plastic material, for example polycarbonate, which meets the necessary electrical boundary conditions.

The cable clamping part and the body preferably consist of different materials. The body can, for example, be made of a robust but inexpensive plastic material, for example polypropylene, while the cable clamping part is made of another plastic material that has suitable elasticity and does not damage the cable jacket of the connected cable.

A body designed according to the invention leads directly to a compact design of a charging connector. With this compactness of the charging connector, charging processes can be carried out better in tight spaces. However, the manageability of such a charging connector decreases because the area for the user to touch is reduced. It therefore makes sense that this charging connector is primarily used for plugging into wall boxes. Here the charging connectors are not permanently plugged in and unplugged, but often remain in the socket for longer periods of time or over several charging processes. At the other end of the charging cable, it can definitely make sense to use a charging connector known from the prior art, which offers a larger grip area.

Advantageously, the contact carrier and the cable clamping part can consist of different materials. The cable clamping part can be formed, for example, from a polyamide. The choice of material will depend on the respective area of application, contact carrier according to electrical constraints and cable clamping part according to mechanical constraints.

Overall, it is advantageous to pay attention to the design and material choice of the charging connector so that it can be recycled later. The components are fixed to one another in such a way that they can be separated from one another. Individual components can be exchanged, reused and/or recycled.

The invention further relates to a system consisting of two charging connectors, a charging cable, with one charging connector being connected to one end of the electrical charging cable, and a charging station, with at least one charging connector being designed according to the invention. The charging connector designed according to the invention is inserted into a socket of the charging station in order to ensure a tight cable routing along the wall.

The second charging connector is plugged into a charging socket on the electric vehicle. The second charging connector in this system is advantageously not according to the invention, but, for example, as in DE 10 2017 119 056 A1 , educated. With the second charging connector, the body does not have a 90° bend. This means that the cable does not come into contact with the electric vehicle and cannot cause damage to the paintwork. In addition, such a charging connector known from the prior art offers a larger grip surface or even a separate handle and improves the manageability of the entire charging system.

Embodiment example

• 1 eine perspektivische Darstellung eines erfindungsgemäßen Ladesteckverbinders,
• 2 eine perspektivische Darstellung eines erfindungsgemäßen Ladesteckverbinders mit extrahiertem Kontaktträger,
• 3 eine perspektivische Darstellung eines erfindungsgemäßen Ladesteckverbinders mit extrahiertem Kabelklemmteil und
• 4 eine seitliche Darstellung eines erfindungsgemäßen Ladesteckverbinders im Vergleich zu einem Korpus eines Ladesteckverbinders, der aus dem Stand der Technik bekannt ist.

An exemplary embodiment of the invention is shown in the drawings and is explained in more detail below. Show it:

• 1 a perspective view of a charging connector according to the invention,
• 2 a perspective view of a charging connector according to the invention with the contact carrier extracted,
• 3 a perspective view of a charging connector according to the invention with the cable clamping part extracted and
• 4 a side view of a charging connector according to the invention compared to a body of a charging connector that is known from the prior art.

The figures contain partly simplified, schematic representations. In some cases, identical reference numbers are used for identical but possibly not identical elements. Different views of the same elements could be scaled differently. Directional information such as “left”, “right”, “up” and “down” are to be understood with reference to the respective figure and can vary in the individual representations compared to the object shown.

The 1 shows a perspective view of a charging connector 1 according to the invention. The charging connector 1 can be plugged into a charging socket of an electric vehicle. Likewise, the charging connector 1 is also suitable for plugging into a charging socket of a charging station and/or wallbox. The latter can be found particularly in private households in garages or carports for charging electric vehicles via the home network. Space is often limited here in particular, as such wallboxes are often retrofitted. There is often not much space between the wallbox and the electric vehicle. This makes it difficult to route the charging cable, which for technical reasons has a large cross-section and therefore a limited bending radius.

The charging connector 1 has a hollow cylindrical and curved body 2. The bending angle in this exemplary embodiment is 90°. This will be discussed in more detail below. The body 2 is preferably formed in an injection molding process and designed in one piece.

The charging connector 1 has a contact carrier 3. The contact carrier 3 is in 2 shown in perspective separately from body 2. The contact carrier 3 contains the contact elements (not shown) for transmitting the charging current and further contact elements for transmitting signals for communication between the charging electronics of the electric vehicle, wallbox and/or charging station. The contact carrier 3 has a substantially cylindrical shape and is arranged approximately halfway through a first opening of the hollow cylindrical body 2.

The contact carrier 3 has screw openings 5 running parallel to the plug-in direction SR, i.e. axially. These plug-in openings 5 correlate with screw-in sleeves 6, which are formed within the body 2, preferably in an injection molding process. This allows the contact carrier 3 to be reversibly fixed to the body 2.

The charging connector 1 has a cable clamping part 7, which in 3 is shown separated from the charging connector 1. When assembling the charging connector 1, the conductors (not shown) of the charging cable 8 are first connected to the contact elements (not shown) of the charging connector 1. This can be achieved, for example, using a crimp connection. The charging cable 8 is then pushed into the body 2 on the connection side. A seal 9, preferably a radial seal made of polyurethane, is provided around the jacket of the charging cable 8 within the body 8. The connection-side end of the body is closed via the cable clamping part 7. The cable clamping part 7 can be screwed to the body 2 using a thread, for example. In particular, the cable strain relief for the charging connector 1 is provided via the cable clamping part.

The charging connector 1 is inserted into a charging socket in the SR plug-in direction. The plugging direction SR is in 1 marked by a dashed arrow and is directed to the right here.

The charging cable 8 protrudes from the body 2 in the cable outlet direction KR. The cable outlet direction KR is in 1 marked by a dashed arrow.

The plug-in direction SR and cable outlet direction KR are in 1 shown once again coherently within its level below the connector 1. The vectors of the plug-in direction SR and cable outlet direction KR enclose an angle α, which according to the invention is 110° or smaller and in this exemplary embodiment, within sensible design options and manufacturing tolerances, exactly 90°.

In 4 a charging connector 1 according to the invention can be seen in comparison to a body SdT-2 known from the prior art. The cable outlet direction SdT-KR, which is provided by such a body SdT-2, is compared to the cable outlet direction KR according to the invention in a vector diagram below the charging connector 1 in 4 shown.

The vectors of the cable outlet direction SdT-KR known from the prior art and the plug-in direction SR include an angle β which is approximately 130°. It can be clearly seen that the known angle β is significantly larger than the angle α according to the invention. In the prior art, the charging cables protrude far from the wall in question and form tripping hazards, especially in spatially confined situations. Thanks to the charging connector 1 according to the invention, the charging cables run close to the wall and therefore offer significant space savings.

Reference symbol list

1

Charging connector

2

Hollow cylindrical body

3

Contact carrier

4

Flat gasket

5

Screw opening

6

screw sleeve

7

Cable clamping part

8th

Charging cable

9

poetry

S.R

Plugging direction

KR

Cable exit direction

α

angle

β

angle

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

• DE 102017119056 A1 [0003, 0023]

Claims (15)

Charging connector (1) for an electric vehicle, consisting of a body (2), a contact carrier (3) and a cable clamping part (7), wherein at one end of the body (2) the contact carrier (3) is arranged, which can be inserted into a charging socket in a plug-in direction (SR), wherein at the other end of the body (2) the cable clamping part (7) is arranged, which serves to fix a charging cable (8) inserted into the body counter to the cable outlet direction (KR), wherein the plug-in direction (SR) and the cable outlet direction (KR) of the body (2) enclose an angle (α) that is 110° or smaller. Charging connector (1) Claim 1 characterized in that the angle (α) lies in an interval of 95° and 85°, with the edge areas being included in the interval. Charging connector (1) Claim 1 characterized in that the plug-in direction (SR) and the cable outlet direction (KR) run perpendicular to one another. Charging connector (1) according to one of the preceding claims, characterized in that the body (2) is hollow cylindrical. Charging connector (1) according to one of the preceding claims, characterized in that the body (2) is curved or angled. Charging connector (1) according to one of the preceding claims, characterized in that the body (2) is formed in one piece or in several parts, in particular from two half-shells. Charging connector (1) according to one of the preceding claims, characterized in that the contact carrier (3) is at least partially arranged in a first opening in the body (2). Charging connector (1) according to one of the preceding claims, characterized in that the cable clamping part (7) is arranged in a second opening in the body (2). Charging connector (1) according to one of the preceding claims, characterized in that the contact carrier (3) and the body (2) consist of different materials. Charging connector (1) according to one of the preceding claims, characterized in that the cable clamping part (7) and the body (2) consist of different materials. Charging connector (1) according to one of the preceding claims, characterized in that the contact carrier (3) and the cable clamping part (7) consist of different materials. Charging connector (1) according to one of the preceding claims, characterized in that a flat seal (4) is arranged on the contact carrier (3), which protects the charging connector (1) from penetration of media on the plug-in side. Charging connector (1) according to one of the preceding claims, characterized in that the contact carrier (3) has screw openings (5) running parallel to the plug-in direction (SR), via which the contact carrier (3) can be reversibly fixed to the body (2). System consisting of two charging connectors (1), a charging cable (8), with one charging connector (1) being connected to one end of the charging cable (8), and a charging station, with at least one charging connector (1) designed according to one of the preceding claims is. System according to the preceding claim, characterized in that exactly one charging connector (1) according to one of the above Claims 1 until 12 is trained.

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