CN209822948U - Plug accommodating device, dirt-proof ring, pin inserting device and plug accommodating system - Google Patents

Abstract

The utility model relates to a device and plug accommodation system are put into to plug accommodation device, antifouling circle, pin. The one-piece plug receptacle (105) has at least one mounting surface (120) and at least one bolt opening (125). The mounting surface (120) is flat, annular and is shaped for mounting the dirt protection ring (110). The peg holes (125) are shaped for: a pin (130) for receiving the dirt protection ring (110) arranged on the arrangement surface (120) in order to fix the dirt protection ring (110) on the plug receptacle (105).

Description

Plug accommodating device, dirt-proof ring, pin inserting device and plug accommodating system

Technical Field

The utility model relates to a plug accommodate device, be arranged in holding to the antifouling circle in the plug accommodate device of integral type, be arranged in holding to the pin in the plug accommodate device of integral type put into device, plug accommodate system and be used for making the method of plug accommodate system for the integral type of unit equipment.

Background

In order to supply an electrical vehicle drive unit of a vehicle with electrical energy, a plug receptacle of the vehicle drive unit is connected to a current plug.

SUMMERY OF THE UTILITY MODEL

Against this background, the present invention relates to an improved integrated plug receptacle for a unit, an improved dirt ring for receiving in an integrated plug receptacle, an improved pin insertion device for receiving in an integrated plug receptacle, an improved plug receptacle system and an improved method for producing a plug receptacle system according to the independent claims. Advantageous embodiments are derived from the dependent claims and the following description.

The advantages that can be realized with the proposed utility model lie in: the integrated plug receptacle is designed to simply and reliably receive the dirt ring and the pin insertion device.

An integrated plug receptacle for an assembly device, for example an electric vehicle drive unit, has at least one seating surface and at least one bolt opening. The seating surface is flat, annular and shaped for seating an anti-fouling ring. The peg holes are shaped to: the pins of the dirt ring, which are arranged on the mounting surface, are received in order to fix the dirt ring on the plug receptacle.

The seating surface is to be understood as a circumferential, annular seating surface. The peg holes may be shaped for: the pins are received in a form-locking and/or force-locking manner.

The one-piece plug receptacle proposed here can be produced quickly and simply, for example by injection molding, and is designed for: the dirt ring is accommodated and fastened in a loss-proof manner without additional components.

In order to provide a larger seating surface, the seating surface may be formed with seating surface protrusions extending from the annular seating surface at least one location.

The stud holes can extend into the seating surface projections in order to enable the fastening of the dirt ring outside the annular seating surface.

In order to also provide accommodation possibilities for the plug, it is advantageous: according to one embodiment, an annular plug flange extends from the inner edge of the seating surface. The plug flange can likewise extend circumferentially and project in the direction of the plug provided for receiving.

The seating surface can be arranged in a plane between the plug flange base of the plug flange and the plug flange tip of the plug flange. The plug flange base can be shaped to form the end of the plug flange opposite the plug flange tip. In this case, the plug flange base can be arranged essentially parallel to the seating surface.

The plug flange base of the plug flange can have a receptacle for receiving a pin insertion device which is formed for connection to a plug.

For example, the receiving means can have at least one receiving opening for receiving a screw and/or a receiving geometry for receiving a stabilizing element of the pin insertion device. The pin insertion device can thus be screwed to the plug receptacle by means of screws that can be received perpendicular to the base of the plug flange. The receiving geometry allows a form-locking reception of the stabilizing element, so that the pin insertion device can be inserted stably into the plug receiving device.

In one of the proposed variants, the dirt protection ring is shaped for receiving in an integrated plug receiving device. The dirt ring is configured to be placed on the placement surface and has at least one peg, which is configured to engage in at least one peg hole of the plug receptacle in order to fix the dirt ring in the plug receptacle. Such a dirt ring can be securely fastened to the plug receptacle and protected against dirt. The pegs may have a fir tree or mushroom shape.

The dirt ring can also have three or four pins, wherein at least one first pin of the three or four pins can be arranged on the side of the dirt ring opposite the other pins in order to establish a uniform connection between the dirt ring and the plug receptacle. If the anti-fouling ring has four pegs, the second of the four pegs may also be arranged on the opposite side. In this case, the distance between the first and second pegs may be different from the further distance between the other pegs.

In one of the proposed variants, the pin insertion device is formed for receiving in an integrated plug receiving device. For this purpose, the pin insertion device is configured to: is received in a receiving means at the bottom of the plug flange of the plug receiving means.

The pin insertion device can have at least one through-hole for the passage of the bolt or of a further bolt and/or at least one stabilizing element which is configured to: to the receiving geometry of the bottom of the plug flange. In this case, the screw can first be inserted through the through-hole of the pin insertion device and then screwed into the receiving hole in the base of the plug flange in order to securely fasten the pin insertion device in the integrated plug receiving device.

In order to stabilize the screw, the through-hole can be arranged in a metal bushing in the pin insertion device, in particular wherein the metal bushing can have a projection at the free end for insertion into a receiving opening of the one-piece plug receiving device for aligning the pin insertion device in the plug receiving device.

The plug receiving system has one of the proposed integrated plug receiving devices, one of the proposed anti-fouling rings and/or one of the proposed pin insertion devices. Such a plug-receiving system has only few components and can be produced simply. Advantageously, all components of the plug receiving system can be inserted onto the plug receiving device from one direction.

The method for producing a plug-receiving system has the following steps:

providing one of the proposed integrated plug receiving devices and one of the proposed anti-fouling rings and/or one of the proposed pin insertion devices; and also

The plug receiving system is established by inserting the anti-soiling ring and/or the pin insertion device into the plug receiving device, in particular wherein the anti-soiling ring and the pin insertion device are inserted into the plug receiving device from the same direction.

The method can be implemented, for example, in software or hardware or in a hybrid form of software and hardware, for example, in a control device.

A computer program product with a program code which can be stored on a machine-readable carrier, such as a semiconductor memory, a hard disk memory or an optical memory, and which, when the program is executed on a computer or a device, is used to carry out the method according to one of the above-described embodiments is also advantageous.

Drawings

Embodiments of the solution proposed herein are shown in the drawings and further elucidated in the following description. Wherein:

fig. 1a) shows a lateral cross-sectional view of a plug-receiving system with an integrated plug-receiving device, dirt ring and pin insertion device according to an exemplary embodiment;

fig. 1b) shows a perspective top view of a plug receiving system according to an embodiment;

fig. 1c) shows a lateral cross-sectional view of a plug receiving system according to an embodiment;

fig. 1d) shows a lateral cross-sectional view of a peg in a peg bore according to an embodiment;

fig. 1e) shows a lateral cross-sectional view of a peg in a peg bore according to an embodiment;

fig. 2a) shows a lateral cross-sectional view of a plug receiving system according to an embodiment;

fig. 2b) shows a perspective top view of the plug receiving system according to an embodiment;

fig. 2c) shows a lateral cross-sectional view of the plug receiving system according to an embodiment;

fig. 2d) shows a lateral cross-sectional view of a screw connection according to an embodiment;

fig. 3a) shows a perspective top view of a plug receiving system according to an embodiment;

fig. 3b) shows a perspective top view of the plug receiving system according to an embodiment;

fig. 3c) shows a perspective top view of the plug receiving system according to an embodiment;

fig. 3d) shows a perspective top view of the plug receiving system according to an embodiment;

fig. 3e) shows a perspective top view of a plug receiving system with a plug according to an embodiment;

fig. 4a) shows a perspective bottom view of the integrated plug receptacle with the dirt ring according to an exemplary embodiment;

fig. 4b) shows a perspective bottom view of the integrated plug receptacle with the dirt ring according to an exemplary embodiment;

fig. 4c) shows a lateral cross-sectional view of the integrated plug receptacle with the dirt ring according to an exemplary embodiment;

fig. 4d) shows a lateral cross-sectional view of a peg in a peg bore according to an embodiment; while

Fig. 5 shows a flow chart of a method for producing a plug-receiving system according to an embodiment.

In the following description of the preferred embodiments of the present invention, the same or similar reference numerals are applied to elements shown in different drawings and functioning similarly, and repeated description of these elements is omitted.

Detailed Description

If an embodiment comprises an "and/or" logical relationship between a first feature and a second feature, this is to be interpreted that the embodiment has not only the first feature but also the second feature according to the implementation, while either only the first feature or only the second feature according to another embodiment.

Fig. 1a) shows a lateral cross-sectional view of a plug receiving system 100 according to an exemplary embodiment, having an integrated plug receiving device 105, dirt ring 110 and pin insertion device 115.

According to this exemplary embodiment, the plug-receiving system 100 has an integrated plug-receiving device 105, dirt ring 110 and pin insertion device 115.

The one-piece plug receptacle 105 is arranged on the assembly or is formed for receiving on the assembly. The one-piece plug receptacle 105 has at least one seating surface 120 and at least one bolt hole 125. The seating surface 120 is flat, annular, and is shaped for seating the dirt ring 110. The peg holes 125 are shaped for: the pegs 130 of the dirt ring 110, which are arranged on the resting surface 120, are received in order to fix the dirt ring 110 on the plug receptacle 105.

The features of the integrated plug-receiving device 105 and plug-receiving system 100 described below are optional:

according to this embodiment, an annular plug flange 135 extends from the inner edge of the seating surface 120.

The seat surface 120 is arranged in a plane between the plug flange base 140 of the plug flange 135 and the plug flange tip 145 of the plug flange 135.

According to this exemplary embodiment, the pin insertion device 115 is accommodated on the integrated plug receptacle 105. In order to accommodate the pin insertion device 115, the plug flange base 140 of the plug flange 135 has an accommodation device. The receiving means comprise at least one receiving opening 150 according to this exemplary embodiment for receiving a screw 155 and/or a receiving geometry 160 according to this exemplary embodiment for receiving a stabilization element 165 of the pin insertion device 115. The pin insert 115 is secured in a receptacle in the base 140 of the plug flange. To this end, according to this embodiment, the pin inserting means 115 has at least one through hole 170 through which the bolt 155 penetrates; and/or at least has a stabilizing element 165, which is accommodated in the accommodating geometry 165 of the plug flange base 140. According to this exemplary embodiment, the pin insertion device 115 is fastened to the plug receptacle 105 by means of a plurality of screws 155 according to the above description.

The anti-fouling ring 110 is shaped to: is received by the integral plug receiving means 105. For this purpose, the dirt ring 110 is formed for placing on the resting surface 120 and has at least one peg 130 which is formed for engaging in at least one peg hole 125 of the plug receptacle 105 in order to fix the dirt ring 110 in the plug receptacle 105.

According to this embodiment, the anti-fouling ring 110 has a plurality of pegs 130. The plug receptacle 105 correspondingly has a plurality of peg holes 125 shaped to receive pegs 130.

In the following, an alternative expression again describes an embodiment of the solution presented here.

The one-piece plug receptacle 105 may also be referred to as a housing cover or a cast housing.

The integrated plug receptacle 105 provides an arrangement for fastening the dirt ring 110 and the pin insertion device 115 of a high-voltage direct-current plug connection (which is hereinafter referred to simply as "HV DC plug connection") to a cast housing of an electric vehicle drive unit.

The use of the plug receiving system 100 proposed here can be seen in the fact that the dirt ring 110 of the HV DC plug connection is fastened in a loss-proof manner in the plug receiving means 105 of the electrical drive unit in the region of the plug flange 135 from the outside via one or more holes in the form of bolt holes 125, the dirt ring 110 having bolts 130 which are pressed into these holes of the plug receiving means 105 during installation and are fixed there in a friction-locking (reibschl ü ssig) and/or form-locking (formschl ü ssig), see for this purpose the fir-tree-shaped part shown in fig. 1d) or the mushroom-shaped part shown in fig. 1e), the bolt holes 125 in the plug receiving means 105 being embodied as counterbored and/or through-and/or threaded holes.

The use of the plug-receiving system 100 proposed here can also be seen in the following aspects: the pin insertion device 115 of the HV DC plug connection is inserted from the outside into the plug flange 135 of the plug receptacle 105. In this way, a mechanical milling or drilling operation, such as a fitting hole, is advantageously possible on the plug receptacle 105 in the region of the plug flange 135.

Advantageously, due to the shaping of the integrated plug receptacle 105 proposed here for fastening the dirt protection ring 110, no undercuts on the plug flange 135 are required for holding the dirt protection ring 110 on the unit-side plug. Due to the narrow section of the screw eye for the cable-side plug, the production of such a lateral recess is only possible with a separately produced plug flange. The plug receptacle 105 proposed here does not require such additional components and the installation space remains small.

Advantageously, the pin insertion device 115 is inserted from the outside into the plug flange base 140 and is also fastened from the outside with screws 155. This has the following advantages over inserting the pin insertion device 115 from the opposite inner side: due to the accessibility, it is possible to machine the flat resting face with a corresponding milling or drilling tool.

In summary, in the case of the plug receiving system 100 proposed here for axially and loss-proof fastening of the dirt protection ring 110 by means of the plug flange 135, it is not necessary to machine undercuts. Furthermore, a complete machining of the pins for fastening the HVDC plug connection from the outside of the cast housing is possible.

As already described, the dirt protection ring 110 is equipped with pins 130, which are pressed axially into the bore of the casting housing and are fixed there in a friction-locking or form-locking manner. The pegs 130 on the anti-fouling ring 110 may be implemented as fir trees or mushrooms. In this way, the dirt ring 110 can be secured in a loss-proof manner in the bore of the casting shell.

Fig. 1b) shows a perspective top view of the plug receiving system 100 according to an embodiment. The plug receiving system 100 described in fig. 1 is referred to herein.

As can be seen in fig. 1 b): the seating surface 120 is formed at least one location, here three locations, with seating surface protrusions 175 extending from the annular seating surface 120. The peg holes 125, according to this embodiment three peg holes 125 each, extend into one of the seating surface protrusions 175.

Correspondingly, according to this embodiment, the dirt ring 110 has three pegs 130, wherein at least one first peg 180 of the three pegs 130 is arranged on the side of the dirt ring 110 opposite the other pegs 130.

It can also be seen in fig. 1 b): corresponding to the illustration carried out in fig. 1a), the pin insertion device 115 is fastened to the plug receptacle 105 by means of four screws.

Fig. 1c) shows a lateral cross-sectional view of the plug receiving system 100 according to an exemplary embodiment. The plug-receiving system 100 described in fig. 1a) and 1b) is referred to here, with the difference that: the anti-fouling ring 110 is accommodated in the integrated plug accommodating device 105. For this purpose, the pegs of the anti-fouling ring 110 are received in peg holes of the plug receiving means 105.

An embodiment of detail a of fig. 1c) is further illustrated in fig. 1d) and 1 e).

Fig. 1d) shows a lateral cross-sectional view of the peg 130 in the peg hole 125 according to an embodiment. The embodiment of detail a shown in fig. 1c) is referred to here. According to this embodiment, the pegs 130 are tree-shaped. According to this embodiment, the peg holes 125 are implemented as counter-bored or threaded holes.

Fig. 1e) shows a lateral cross-sectional view of the peg 130 in the peg hole 125 according to an embodiment. This relates to a further exemplary embodiment of detail a shown in fig. 1 c). According to this embodiment, the pegs 130 are mushroom-shaped. According to this embodiment, the peg holes 125 are implemented as through holes.

Fig. 2a) shows a lateral cross-sectional view of the plug receiving system 100 according to an exemplary embodiment. The plug-receiving system 100 described in fig. 1c) is concerned here, wherein the pin insertion device 115 is not yet received on the plug-receiving device 105.

The pin insertion device 115 has a plastic encapsulation 200. The through-holes 170 of the pin insertion device 115 are arranged in metal bushings 205 in the plastic encapsulation 200, in particular wherein the metal bushings 205 each have a projection 210 at a free end.

It can also be seen in fig. 2 a): the pin insertion device 115 has two stabilizing elements 165.

In other words, fig. 2a) shows the installation of the pin insertion device 115 of the HV DC plug connection from the outside into the plug flange of the casting housing by means of four bolts according to this embodiment.

Fig. 2b) shows a perspective top view of the plug receiving system 100 according to an embodiment. The plug receiving system 100 described in fig. 1a) is referred to in this case.

Fig. 2c) shows a lateral cross-sectional view of the plug receiving system 100 according to an exemplary embodiment. The plug-receiving system 100 described in fig. 2a) and 2b) is referred to in this case, wherein the pin insertion device is screwed onto the plug-receiving device as in fig. 1 c). The details a of the bolt connection are further shown in fig. 2 d).

Fig. 2d) shows a lateral cross-sectional view of the screw connection according to an exemplary embodiment. This relates to detail a shown in fig. 2 c). The boss of the metal bushing 205 is disposed in a boss receiving void 215 in the plug receiving device 105.

According to this exemplary embodiment, the metal bushing 205 is connected to the plastic encapsulation of the pin insertion device in a loss-proof manner. The bosses 215 of the at least two metal bushings 205, which fit precisely into the two counterbores on the casting housing, also enable precise alignment of the pin insertion device with the plug flange.

This has the following advantages: a completely mechanical machining of the casting shell can be achieved from the outside. There, there is a perfect accessibility for the required drilling and milling tools.

Fig. 3a) shows a perspective top view of the plug receiving system 100 according to an embodiment. The plug receiving system 100 described in one of the above figures is referred to here, wherein all individual components are shown exploded. Also shown is a plug 300 to be nested onto the plug receiving system 100. Fig. 3b) to 3e) show a possible installation sequence of the dirt protector and the pin insertion device on the integrated plug receptacle.

In other words, it can be seen that the essence of the solution proposed here is the specific arrangement and mounting of the dirt ring and the pins of the HV DC plug connection on the cast housing of the electric vehicle drive unit.

Fig. 3b) shows a perspective top view of the plug receiving system 100 according to an embodiment. The plug-receiving system 100 shown in fig. 1a) is concerned here, wherein the dirt ring has been inserted from the outside onto the one-piece plug-receiving device.

Fig. 3c) shows a perspective top view of the plug receiving system 100 according to an exemplary embodiment. The plug-receiving system 100 shown in fig. 1b) is concerned here, in which a pin insertion device has been inserted into the integrated plug-receiving device from the outside.

Fig. 3d) shows a perspective top view of the plug receiving system 100 according to an embodiment. The plug receiving system 100 shown in fig. 1c) is concerned here, in which four screws have been screwed into the one-piece plug receiving device from the outside in order to fasten the pin insertion device to the one-piece plug receiving device.

Fig. 3e) shows a perspective top view of the plug receiving system 100 with the plug 300 according to an embodiment. The plug-receiving system 100 shown in fig. 1d) is referred to in this case, wherein the plug 300 is plugged onto the plug-receiving system 100 from the outside.

Fig. 4a) shows a perspective bottom view of the integrated plug receptacle 105 with the dirt ring 110 according to an exemplary embodiment. One of the plug receptacles 105 can be provided with an anti-soiling ring 110, the anti-soiling ring 110 being described in one of the above figures with the difference that: the dirt ring 110 according to this exemplary embodiment has four pegs and the plug receptacle correspondingly has four peg openings. Two of the four pegs are arranged on one side of the dirt ring 110, while the other two of the four pegs are arranged on the side opposite to this side. In this case, the distance between two pegs on one side is different from the other distance between the other two pegs on the opposite side.

According to this embodiment, the four pegs of the anti-fouling ring 110 are shaped as a fir tree. By means of a greater number of pegs or connections, the loss-proof fastening of the dirt protector 110 to the plug receptacle 105 can be correspondingly improved. In this way, when the plug on the cable side is released: the dirt ring 110 is held securely in its position at the plug-in flange and is not entrained, for example, by adhering dirt or the like.

Fig. 4b) shows a perspective bottom view of the integrated plug receptacle 105 with the dirt ring 110 according to an exemplary embodiment. The plug receptacle 105 shown in fig. 4a) is provided with an anti-fouling ring 110, which is currently inserted into the plug receptacle 105.

Fig. 4c) shows a lateral cross-sectional view of the integrated plug receptacle 105 with the dirt ring 110 according to an exemplary embodiment. The plug receptacle 105 shown in fig. 4b) with the inserted dirt protection ring 110 is referred to in this case. The detail a of fig. 4c) is further illustrated in fig. 4 d).

Fig. 4d) shows a lateral cross-sectional view of the peg 130 in the peg bore according to an embodiment. This relates to detail a shown in fig. 4 c). According to this embodiment, the pegs 130 are tree-shaped.

Fig. 5 shows a flow chart of a method 500 for producing a plug-receiving system according to an embodiment. The method 500 comprises at least a providing step 505 and an inserting step 510. In a providing step 505, an integrated plug receiving device and anti-fouling ring and/or pin insertion device is provided.

In an insertion step 510, the anti-soiling ring and/or the pin insertion device are inserted into the plug receptacle in order to produce the plug receptacle system, in particular wherein the anti-soiling ring and the pin insertion device are inserted into the plug receptacle from the same direction.

The embodiments described and shown in the figures are selected by way of example only. The different embodiments can be combined with each other either completely or with respect to individual features. One embodiment may also be supplemented by features of another embodiment.

Further, the method steps set forth herein may be repeated and performed in a different order than that described.

Reference numerals

Details A

100 plug receiving system

105 integrated plug receptacle

110 antifouling ring

115 pin imbedding device

120 setting surface

125 stud hole

130 stud

135 inserting flange

140 plug flange bottom

145 plug flange tip

150 receiving hole

155 bolt

160 containment geometry

165 stabilizing element

170 through hole

175 set face protrusion

180 first stud

200 plastic injection molding part

205 metal bushing

210 convex part

215 boss receiving recess

300 plug

500 method for manufacturing a plug-receiving system

505 providing step

510 step of insertion

Claims (12)

1. An integrated plug receptacle (105) for a unit, wherein the plug receptacle (105) has at least the following features:

-a flat, annular seating surface (120) for seating an anti-fouling ring (110); and

-at least one peg hole (125) shaped for: a peg (130) for receiving a dirt protection ring (110) arranged on the arrangement surface (120) in order to fix the dirt protection ring (110) on the plug receptacle (105).

2. The unitary plug-receiving device (105) according to claim 1, wherein the seating surface (120) is formed at least one location with a seating surface protrusion (175) extending from the annular seating surface (120).

3. The unitary plug-receiving device (105) of claim 2, wherein the peg aperture (125) extends into the seating surface protrusion (175).

4. The unitary plug-receiving device (105) according to any one of the preceding claims, wherein an annular plug flange (135) extends from an inner edge of the seating surface (120).

5. The integrated plug receptacle (105) according to claim 4, wherein the seating surface (120) is arranged in a plane between a plug flange base (140) of the plug flange (135) and a plug flange tip (145) of the plug flange (135).

6. The integrated plug receptacle (105) according to claim 4, wherein the plug flange base (140) of the plug flange (135) has a receptacle for receiving a pin insertion device (115).

7. The integrated plug receptacle (105) according to claim 6, wherein the receptacle has at least one receiving opening (150) for receiving a fastening element, in particular a screw (155), and/or a receiving geometry for receiving a stabilization element (165) of the pin insertion device (115).

8. An anti-fouling ring (110) for being received into the one-piece plug receiving device (105) according to any one of the preceding claims, wherein the anti-fouling ring (110) is shaped for being seated onto the seating face (120) and has at least one peg (130) which is shaped for being inserted into at least one peg hole (125) of the plug receiving device (105) in order to fix the anti-fouling ring (110) in the plug receiving device (105).

9. The anti-fouling ring (110) according to claim 8, having three or four pegs (130), wherein at least one first peg (180) of the three or four pegs (130) is arranged on a side of the anti-fouling ring (110) opposite to the other pegs (130).

10. Pin insertion device (115) for insertion into an integrated plug receiving device (105) according to one of claims 1 to 7, wherein the pin insertion device (115) is configured to: is received in a receiving means of a plug flange base (140) of the plug receiving means (105).

11. The pin insertion device (115) according to claim 10, having at least one through-hole (170) for the passage of a bolt (155) and/or at least one stabilizing element (165) which is shaped for: is received in a receiving geometry (160) of the plug-in flange base (140), in particular wherein the through-opening (170) is arranged in a metal bushing (205) of the pin insertion device (115), in particular wherein the metal bushing (205) has a projection (210) at a free end.

12. Plug housing system (100) having an integrated plug housing device (105) according to one of claims 1 to 7, an anti-fouling ring (110) according to one of claims 8 to 9 and/or a pin insertion device (115) according to one of claims 10 to 11.