DE10149201C1 - Electrical connector for motor vehicle has elastically-deformable element which deforms when electrical connection is made, and separates contacts when securing device is released - Google Patents

Abstract

An elastically deformable element (15) and a securing device (13,31) are provided for securing the electrical connection to prevent unintentional release. The elastically deformable element is arranged so that it is deformed when the electrical connection is made, and when the securing device is released, the stored elastic energy is released, to drive one electric contact (5) so that it separates from another electric contact (23).

Description

The invention relates to an electrical connector, ins especially for an electrical system of a motor vehicle, to establish and release an electrical connection between two electrical wires. The connector has one first and a second connector part on each other are separable and by joining them electrical contact contacts and the electrical connection is established the.

Future electrical systems in motor vehicles will be used for a supply voltage of 42 volts. If between Connector parts such high DC voltages exist when establishing and releasing an electrical connection, the Ge drive an arc. This applies in particular to the high currents that can occur in motor vehicles NEN. Possible consequences of an arc are fires, injuries people by sparks or electric shock and be damage or destruction of electrical connector parts.

An electronic control unit has been proposed to be provided before the manufacture or release of an electri connection at least one of the connector parts of the Power supply disconnects. The control unit can be connected to the Leading contacts provided provided actuated who the. However, such solutions are expensive.  

From WO 00/46881 A1 an electrical connector with the features of The preamble of claim 1 is known.

DE 88 06 272 U1, DE 199 52 023 A1 and FR 2 778 502 A1 are electrical Connectors known in which the respective connector parts only after Overcoming a joining resistance can come into contact.

EP 0 773 602 A2 describes a connector in which the two ends of the Contacts can be inserted into each other and the surface of one is in Section extending portion of both or one of the two Contacts is formed by an electrically insulating material.

The object of the present invention is to provide an electrical connector Specify the type mentioned at the outset, which, with little production effort Prevents the generation of an arc.  

US 5,110,302 describes an electrical connector of the initially mentioned type with a joining resistance, which the together resistance of the connector parts to where when attacking a sufficiently large joining force, the counter is overcome and the first and second connector part be put together.

It is now proposed to derar such a connector tig to design that he ver the formation of arcs can hinder. For this, the first electrical contact is the second electrical contact and the joining resistance in such a manner orders that when merging the first and second verbs the first and the second electrical contact only after overcoming resistance electrically contacting each other ren.

The fact that a correspondingly large joining force applied the must to overcome the resistance, the two e electrical contacts within a short time in electrical con be brought together in time. In particular, the plug connector be designed so that the joining force up to the time must overcome the point of overcoming resistance. In this Fall therefore also applies at least part of the joining force immediately after overcoming resistance and gently a quick closing of the electrical contacts. By the quick closing of the contacts will ignite one Arc effectively prevented. In any case, one can Feel the person who put the two connector parts together, when the resistance is overcome and the electrical contact close quickly. Would the electrical contacts closed before overcoming resistance in particular, an arc is ignited if the two connector parts are not together in the correct way be added, for example tilted and / or jammed become.  

In particular, the first or second electrical contact can Contact body with a free end that when joining gene of the first and second connector part in a corresponding Opening of one contact body holder on the other Connector part is introduced, as is the case with plug connect with a plug and a socket is the case. In this case, at least the surface is preferably one extending portion of the contact in the insertion direction body formed by an electrically insulating material. Alternatively or additionally, at least the upper is preferred area on the edge of one into the contact body receptacle extending portion of the contact body receptacle from one electrically insulating material is formed.

In this case, the insertion of the contact body (for Example of the connector pin) in the contact body holder (for Example the socket) before the resistance is overcome. on However, due to the electrically insulating material no electrical contact between the contact body and the Contact body recording made and there can be no arc arise between opposing surfaces.

It is further preferred that the contact body receptacle and the Contact body are dimensioned so that when inserting the Contact body and before the first electrical contact second electrical contact electrically contacted, the con tactile body and the wall of the contact body receptacle in the section of the electrically insulating material touch each other. The Contact body can even be around in this section NEN outer circumference or at least on opposite Sides or on several sides of its outer circumference the wall of the Touch the contact body holder. Touching can prevent be changed that ge by the insulating material did not form an arc between surface of the opposing contact surfaces.  

In particular, the insulating material of the contact body and / or the contact body receptacle can be elastically compressed his. For example, the Kon tactile body in at least one, transverse to the insertion direction of the Contact body oriented direction wider than a correspond area of the contact body receptacle that the insulating Material of the contact body when inserting or removing of the contact body or the insulating material has on the wall of the contact body receptacle. At least in in this area the contact body is therefore close to the wall the contact body holder.

It is advantageous if the insulating surface is covered by a soft material is formed. PTFE is particularly suitable (Polytetrafluoroethylene), which has a low coefficient of friction ent owns. However, the insulating material can also be a ke ram material.

The insulating material can also have the property under Swelling heat, that is, its outer dimensions gene to enlarge. Especially with sparks and after Zün arc, but also in other situations, in to whom the insulating material heats up, the isolie swells material. This deprives and / or displaces it insulating material any air in areas in which can be ignited or have already ignited have been.

Furthermore, an actively arc-extinguishing material can be provided on the contact body receptacle and / or on and / or in the contact body. For example, sulfur hexafluoride (SF ₆ ) is suitable for this. Materials that are known or suitable as flame retardants, ie that complicate and / or prevent the course of combustion reactions and / or interrupt combustion reactions, are also suitable for this purpose. At least some such materials, for example zinc borates, can be easily dispersed in other materials, in particular plastics, and can therefore be added easily, for example to the insulating material of the contact body and / or the contact body holder. In some of the flame retardants, the respective material that the flame retardant has is thereby even leakage current and / or arc resistant. An example of this are polyamides that contain zinc borates as flame retardants.

The connector can have an elastically deformable element have as well as a safety device to secure the elect connection against accidental loosening. That elastic deformable element is arranged so that it is during manufacture the electrical connection is deformed elastically and that by releasing the safety device the stored e elastic energy is released and the first electrical Contact and drives the second electrical contact apart and thereby electrically isolates.

Because of the spreading of the electrical contacts can welding of the contacts can be prevented. Preferably the elastically deformable element is designed so that the electrical contacts quickly and far enough apart be driven to prevent the ignition of an arc or, at most, only a short-time burning arc or allow sparking.

In particular, the elastic element can also be with the above measure combined, according to the one section the surface of a contact body and / or a contact body peraufnahme of insulating material is formed and / or ge according to the active arc extinguishing material provided is. In this way, a possibly ignited arc is opened deleted due to the insulating material.  

In a further, preferred embodiment, the first electrical contact, the second electrical contact and the foot resistance arranged such that the joining resistance after the Unlock the safety device and after the apart drive the first and second electrical contacts the first and second connector part mechanically holds together, and wherein by overcoming one applied by the joining resistance Isolation resistance of the first and second connector part from each other that are separable. The joining resistance thus prevents un intentional separation of the two connector parts.

The elastic element preferably secures in the holding state the first electrical contact and the second electrical Contact against unintentional electrical contact. This can be achieved, for example, by the elas table element arranged on one of the two connector parts is and that the other connector part only against the elastic Forces of the element are brought back into one position can in which the electrical contacts contact each other.

Embodiments of the present invention will now become apparent hand described in the accompanying drawing. The individual figu show the drawing:

Fig. 1 is a schematic sectional view of a connector zweiteili gene in the non-connected state,

Fig. 2 of the connector of FIG. 1 when making the electrical connection and

Fig. 3 of the connector of FIGS. 1 and 2 in the connected state.

Fig. 1 shows a two-piece connector having a female part 1 and a male part 3. By inserting a contact pin 23 of the plug part 3 into an opening 7 of the socket part 1 , an electrical connection between the connection line 29 connected to the plug part 3 and the connection line 21 connected to the socket part 1 can be provided.

The plug part 3 has a fork-like holder 27 which holds the contact pin 23 . At the free, from the holder 27 th end of the contact pin 23 is an end piece 25 made of an electrically insulating material. At least the section from the contact pin 23 , which extends from the holder 27 to the end piece 25 , consists of an electrically conductive material and is used for electrical contacting of a socket contact 5 of the socket part 1 . The connecting line 29 is electrically connected to this section of the contact pin 23 .

The fork-like holder 27 has two fork arms 33 which extend in the insertion direction of the contact pin 23 beyond the free end of the contact pin 23 . On the mutually facing inner sides of the fork arms 33 , a projection 28 is provided, which has a triangular profile in the cross section shown in FIG. 1. The projections 28 form elevations on the surface of the respective fork arm 33 , the elevation being the highest in its center, ie having a peak which is the greatest distance from the base of the elevation.

On their outer sides facing away from each other, the fork arms 33 each have a grid extension 31 , which is also formed by a triangular cross section with a peak. The grid extensions 31 serve to snap the fork arms 33 , and thus the plug part 3 , into corresponding receptacles on the socket part 1 .

The socket part 1 has a housing 4 , the element 6 Kontaktele receives. The socket contact 5 is part of the Kontaktele element 6 and is electrically connected to the connection line 21 via a connector. On its inside it has a contact surface 9 , via which it is in electrical contact with the contact pin 23 when it is fully inserted.

The housing 4 has two short housing arms 11 which extend in the insertion direction of the contact pin 23 . Each at its free end, the housing arms 11 have an inward locking lug 13 pointing towards the socket contact 5 .

The dimensions of the plug part 3 and the socket part 1 are dimensioned such that the fork arms 33 can be snapped between the housing arms 11 by joining the connector part 3 and the socket part 1 , so that the elevations formed by the raster extensions 31 form the respective assigned detent 13 engage behind. Fig. 3 shows the locked state . By snapping the connection between the socket part 1 and the plug part 3 is secured against unintentional loosening.

When latching, a latching resistance must be overcome, since in the mechanically unloaded state the distance between the two peaks of the grid extensions 31 is greater than the distance between the two latching lugs 13 . By elastic deformation of the holder 27 and / or the housing 4 , the two peaks can pass through the locking lugs 13 . To disengage a corresponding de elastic deformation is required, which is achieved, for example, by the fact that the two fork arms 33 are moved towards one another. As can be seen from FIG. 3, there is sufficient space for this between the fork arms 33 and the central part of the housing 4 .

At the open end of the socket contact 5 , the latter has an end region 19 which is formed from an insulating material and which forms the opening 7 for inserting the contact pin 23 .

The central part of the housing 4 , which closes the socket contact 5 , has a joining resistance 17 on its outer sides pointing in the direction of one of the latching lugs 13 . The joining resistors 17 are similar to the projections 28 and the grid extensions 31 by an elevation of the surface gebil det, which has a triangular profile with a protruding summit 18 . The operation of the joining resistors 17 when assembling the socket part 1 and the plug part 3 is described in more detail with reference to FIG. 2.

The housing arms 11 attach to the central part of the housing 4 and initially extend transversely to the insertion direction of the contact pin 23 . With this section you form a stop for the fork arms 33 (see Fig. 3). A spring 15 , in particular a leaf spring, is provided on the housing 4 on both sides of the central part. In their relaxed state stood the springs 15 from the housing arms 11 , in such a way that when they are joined together by the fork arms 33 they are stretched until the fork arms 33 engage.

Fig. 2 shows the connector in the partially inserted state of the contact pin 23rd If the contact pin 23 is inserted into the opening 7 from the position shown in FIG. 1, the insulating end piece 25 of the contact pin 23 and the insulating end region 19 of the socket contact 5 lie opposite one another transversely to the insertion direction. There is therefore no electrical contact between the contact pin 23 and the socket contact 5 .

If the assembly is continued, the free ends of the fork arms 33 abut the springs 15 . At approximately the same time, the projections 28 also bump with their inclined surface facing forward in the insertion direction on the inclined surface of the respectively assigned joining resistance 17 oriented in the opposite direction to the insertion direction. As a result, the joining resistors 17 oppose further resistance to joining. In this Relativpositi on of the socket part 1 and the plug part 3 , there is still no electrical contact between the socket contact 5 and the contact pin 23 . Although is transverse to the direction of insertion of the contact surface 9 of the socket contact 5 already a part of the contact pin 23 opposite. However, as shown in FIG. 2, the sections of the contact pin 23 and the socket contact 5 formed from the insulating materials still overlap one another, that is to say the insulating end region 19 of the socket contact 5 is still partially opposite the insulating end piece 25 of the contact pin 23 , The overlap and / or the distance between the isolating materials facing one another are dimensioned such that no spark or arc can occur between the socket contact 5 and the contact pin 23 .

If a sufficiently large joining force is brought up in the insertion direction, the socket part 1 and / or the plug part 3 deforms elastically, so that the tops of the projections 28 pass the summit 18 of the joining resistors 17 in the insertion direction. Due to the fact that the resistance caused by the joining resistors 17 is suddenly overcome, at least part of the joining force is still attacking and causes the assembly to continue rapidly. The resistance and the clamping forces of the springs 15 are designed so that the joining force required to overcome the resistance is greater than the sum of the force required to fully tension the springs 15 and the force required for latching. The joining force required is preferably a multiple, preferably at least twice, the sum. In this way, the fork arms 33 and the housing arms 11 are accelerated towards one another in the insertion direction immediately after overcoming the resistance, so that a large area overlap of the contact surface 9 and the electrically conductive section of the contact pin 23 is quickly achieved. The critical time period during which there is only a slight overlap and therefore large electric field strengths can lead to the ignition of an arc is therefore short.

The assembly continues until the fork arms 33 engage as described above. The state shown in FIG. 3 is thus achieved.

The elastic deformation required to overcome the resistance when assembling can be done in various ways. The deformation can be limited locally to the area of the projections 28 and / or the joining resistors 17 . Al ternatively or additionally, the housing 4 and / or the holder 27 can be elastically deformable overall.

When the connection between the socket part 1 and the plug part 3 is released, the fork arms 33 are disengaged, for example, as described above. As a result, the tensioning forces of the springs 15 are released and quickly drive the socket contact 5 and the contact pin 23 apart until their electrically conductive regions are no longer opposite one another. The relative movement of the socket part 1 and the plug part 3 is stopped, however, by the fact that the projections 28 meet with their inclined surfaces directed against the insertion direction on the inclined surfaces oriented in the insertion direction of the joining resistors 17 . In this position, which is not shown in the figures, there is no longer any electrical contact between the socket contact 5 and the contact pin 23 . Furthermore, the surfaces formed by the insulating materials of the socket contact 5 and the contact pin 23 already overlap to such an extent that no arc can burn. If an arc was ignited during the separation process, this is interrupted due to the insulating end region 19 and / or due to the insulating end piece 25 and is therefore extinguished.

The joining resistors 17 thus oppose the complete separation of the socket part 1 and the plug part 3, a separation resistance, but the electrical contact is already separated. This has the advantage that neither of the two connec derteile 1 , 3 can solve uncontrollably. The separation resistance can be overcome by applying a correspondingly large separation force.

Claims (8)

1. Electrical connector for establishing and releasing an electrical connection between two electrical lines ( 21 , 29 ), with:
a first and a second connector part ( 1 , 3 ) which are separable from one another and by joining them together a first electrical contact ( 5 ) on the first connector part ( 1 ) a second electrical contact ( 23 ) on the second connector part ( 3 ) contacted and the electrical connection is made, and
at least one joining resistance ( 17 ), which opposes the joining together, a resistance being overcome when a sufficiently large joining force is attacked and the first and second connector parts ( 1 , 3 ) are joined together, and
the first electrical contact ( 5 ), the second electrical contact ( 23 ) and the joining resistor ( 17 ) are arranged such that when the first and second connector parts ( 1 , 3 ) are joined together, the first and the second electrical contact ( 5 , 23 ) only make electrical contact with each other after overcoming the resistance,
marked by
an elastically deformable element ( 15 ) and a securing device ( 13 , 31 ) for securing the electrical connection against unintentional loosening, the - elastically deformable element ( 15 ) being arranged such that it is elastically deformed when the electrical connection is made and that by releasing the safety device ( 13 , 31 ) the stored elastic energy is released and drives the first electrical contact ( 5 ) and the second electrical contact ( 23 ) apart and thereby electrically separates them. 2. Plug connector according to claim 1, wherein the first or second electrical contact ( 23 ) is a contact body with a free end, which when joining the first and second connector parts ( 1 , 3 ) into a corresponding receiving opening ( 7 ) of a contact body the other connector part ( 1 ) is inserted, and wherein at least the surface of an extending portion of the Kontaktkör pers is formed by an electrically insulating material. 3. Connector according to claim 1 or 2, wherein the first or second electrical contact ( 23 ) is a contact body with a free end, which when joining together the first and second connector parts ( 1 , 3 ) in a corresponding receiving opening ( 7 ) of a contact body is inserted peraufnahme on the other connector part ( 1 ), and wherein at least the surface at the edge of an extending into the contact body receptacle section from the contact body receptacle is formed by an electrically insulating material. 4. Connector according to one of claims 2 or 3, wherein the contact body receptacle and the contact body are dimensioned such that, when inserting the contact body and before the first electrical contact ( 5 ) electrically contacts the second electrical contact ( 23 ), the contact body and the wall of the contact body receptacle in section from the electrically insulating material touch each other. 5. Connector according to claim 1, wherein the first electrical contact ( 5 ), the second electrical contact ( 23 ) and the joining resistor ( 17 ) are arranged in such a way that the joining resistor ( 17 ) after unlocking the securing device ( 13 , 31 ) and after driving the first and second electrical contacts ( 5 , 23 ) together mechanically holds the first and second connector parts ( 1 , 3 ) together, and by overcoming a separation resistance applied by the joining resistor ( 17 ), the first and second resistances Connector part ( 1 , 3 ) are separable from each other. 6. Connector according to claim 5, wherein the elastic element ( 15 ) in the holding state secures the first electrical contact ( 5 ) and the second electrical contact's ( 23 ) against unintentional electrical contact. 7. Connector according to one of claims 1 to 6, wherein the joining resistance ( 17 ) is formed by an elevation of the upper surface of the first connector part ( 1 ) and on the second connector part ( 3 ) a counterpart ( 28 ) is seen, which at Assembling the connector parts ( 1 , 3 ) on the joining resistor ( 17 ) abuts and thereby opposing the resistance is opposed. 8. Connector according to claim 7, wherein when attacking the sufficiently large joining force of the first and / or second connector part ( 1 , 3 ) is elastically deformed ver and thereby the resistance is overcome.