EP0923167A1 - Plug connection with automatic ejection - Google Patents

Abstract

The plug-in connection comprises a plug (1,11) and a counter-plug (2,12), in which the two parts are fully pushed into one another and releasably locked together. A spring element (3,13) acts between the two pluggable parts and ejects the counter plug from the plug in the event of a faulty electrical connection between the two plug parts. A spring-gate arrangement (4) is used for guiding the spring element providing a non-linear characteristic curve of the spring, more specifically a digressive characteristic with two linear sections.

Description

The present invention relates to a connector, in particular for vehicle electronics, according to the preamble of the claim 1.

Plug connections of this type are well known and one for example, connector described in US Pat. No. 5,591,042 comprises two plug-in parts, i.e. one plug and one Mating connector that is used to produce a perfect electrical Connection both completely pushed into each other and are releasably locked together, a spring element 6 (There Figures 1A to 1D) is provided, which between the both plug-in parts works and which one in the event of a faultless electrical connection the mating connector from the Ejects plug.

The known connectors work according to the so-called "go / no-go" principle, i.e. that if the connector is not is completely locked, by means of the spring force of a spring element the two plug-in parts pushed apart again or the mating connector is ejected from the connector.

In the prior art, however, it is neglected that Overcoming this spring or ejection force a high actuation force is to be used on the one hand when plugging together the plug-in parts of the plug connection felt uncomfortable and which, on the other hand, will cause damage due to its height the plug-in parts:

It is therefore the object of the present invention, a To create a connector of the type mentioned in the the operation is simplified, as well as the risk of damage the plug-in parts is reduced.

This problem is solved by a plug-in connection, which Features according to the characterizing part of patent claim 1 having.

According to the invention, a spring-link arrangement for the management of the above Spring element provided, these Spring-link arrangement causes a non-linear spring characteristic.

The spring force is preferably at the beginning of the insertion process (Mating connector in connector) stronger than to a later one Time just before the end of the insertion. In the diagram on page 6 a spring characteristic is shown as an example, that reflects this fact. At the beginning of the insertion, if the electrical contacts in the two plug-in parts are still have no contact, the spring force is relatively high, so that in the event of a termination of the insertion into one another, the two plug parts be pushed apart again. In the further course of the Inserting, namely when the electrical contacts in Come into contact with each other and as a result of the friction an increase in the insertion force is brought about, the insertion force To keep low, the increase in overall strength is too this time by changing the spring characteristic to keep, so that overall the lowest possible counterforce must be overcome when inserting, but is included the spring force is always sufficiently large or strong enough to Plug-in parts if the plug-in condition is not perfect push apart and thus indicate to the user that the connection is not correct.

Advantageous further developments of the plug connection according to the invention are specified in subclaims 2 to 15.

Fig. 1 eine erste Ausführungform anhand mehrerer Querschnittansichten zeigen, wobei in der Figur 1(a) der Zustand vor dem Zusammenstecken der Steckteile gezeigt ist und in der Figur 1(d) der Zustand der ineinander gesteckten Steckteile dargestellt ist; in den Figuren 1(b) und 1(c) sind Zwischenschritte des Zusammensteckens dargestellt;

Fig. 2 die erste Ausführungsform in einer Draufsichtdarstellung zeigen, wobei diese beiden Darstellungen einer Ansicht von rechts in der Figur 1 entsprechen;

Fig. 3 eine schematische Darstellung der Feder-Kulissen-Anordnung in zwei Zuständen zeigen;

Fig. 4 eine zweite Ausführungform anhand mehrerer Querschnittansichten zeigen, wobei in der Figur 4(a) der Zustand vor dem Zusammenstecken der Steckteile gezeigt ist und in der Figur 4(d) der Zustand der ineinander gesteckten Steckteile dargestellt ist; in den Figuren 4(b) und 4(c) sind Zwischenschritte des Zusammensteckens dargestellt;

Fig. 5 eine dritte Ausführungform anhand mehrerer Querschnittansichten zeigen, wobei in der Figur 5(a) der Zustand vor dem Zusammenstecken der Steckteile gezeigt ist und in der Figur 5(c) der Zustand der ineinander gesteckten Steckteile dargestellt ist; in der Figur 5(b) ist ein Zwischenschritt beim Zusammenstecken dargestellt, während in der Figur 5(d) ein Zwischenschritt dargestellt ist, der vor dem Auseinanderziehen bzw. Lösen der Steckverbindung erfolgt; und

Fig. 6 eine perspektivische Ansicht der dritten Ausführungsform im ungesteckten Zustand zeigen.

The invention will be explained in the following using several exemplary embodiments, in conjunction with the associated drawings, which are shown in:

1 shows a first embodiment using several cross-sectional views, FIG. 1 (a) showing the state before the plug-in parts are plugged together and FIG. 1 (d) showing the state of the plug-in parts plugged into one another; in Figures 1 (b) and 1 (c) intermediate steps of putting together are shown;

FIG. 2 shows the first embodiment in a top view, these two representations corresponding to a view from the right in FIG. 1;

Fig. 3 shows a schematic representation of the spring-link arrangement in two states;

4 shows a second embodiment on the basis of several cross-sectional views, FIG. 4 (a) showing the state before the plug-in parts are plugged together and FIG. 4 (d) the state of the plug-in parts plugged into one another; in Figures 4 (b) and 4 (c) intermediate steps of putting together are shown;

5 shows a third embodiment on the basis of several cross-sectional views, FIG. 5 (a) showing the state before the plug-in parts are plugged together and FIG. 5 (c) showing the state of the plug-in parts plugged into one another; FIG. 5 (b) shows an intermediate step when plugging together, while FIG. 5 (d) shows an intermediate step that takes place before the plug connection is pulled apart or released; and

Fig. 6 show a perspective view of the third embodiment in the unplugged state.

The first embodiment is shown in FIGS. 1 and 2. With 1 the plug is designated, while with the reference symbol 2 the mating connector is designated. The mating connector 2 is inserted into the opening on connector 1 until a driver 2a, for example in the form of a paragraph, with a Spring element 3 comes into contact. The spring element 3 is in Connection with Figure 3 will be described in detail. With a further insertion of the mating connector 2, the Spring element 3 is subjected to a force F and compressed or deformed. A state is shown in FIG. 1 (b), in which the mating connector 2 is about 2/3 in the connector 1 is inserted. If the mating connector 2 is now released, so presses the spring element 3 under tension the mating connector 2 out of connector 1 again. Will the mating connector 2, on the other hand, is inserted further, so that a bridge part 3d of the spring element 3 by means of a deflection device 5 the connector 1 deflected down and can along the Relax underside of driver 2a.

After this relaxation of the spring element 3 is a state reached, which is shown in Figure 1 (d), the mating connector 2 complete and with a perfect connection in the connector 1 is inserted. The spring element 3 serves here with its bridge part 3d as security against an unintended Pull out the mating connector 2. This is the bridge part 3d between the mating connector 2 and a holding section 6 arranged on the connector 1 so that without an active shift of the bridge part 3d the mating connector 2 is not from the Plug 1 can be pulled out.

The driver 2a causes the pull-out Spring is pressed down and a spring force builds up, which counteracts the removal of the mating connector 2. Becomes overcome this force, the mating connector 2 is due to the Acceleration pulled out of connector 1. The peeling process interrupted, the mating connector slips due to the spring force (inclined contact surface of the holding section 6 and of paragraph 2b) back into plug 1.

2 (a) shows the state according to FIG. 1 (d), it can be seen that the spring element 3 with its bridge part 3d lies in front of the mating connector 2. In the FIG. 2 (b), on the other hand, shows the state in which a Disconnect the connector. The bridge part 3d the spring element 3 is by hand in the middle push down to bridge part 3d around paragraph 2b to lead around. As soon as paragraph 2b of the mating connector 2 is not the mating connector can encompass more of the spring element 3 2 are pulled out of plug 1.

The spring element 3 used in this first embodiment is essentially U-shaped and schematic in Figure 3 shown. This spring element 3 is in the connector 1 after the figure 1 arranged so that the bridge part 3d in Cross section can be seen, which is preferably circular is.

The spring-backdrop arrangement according to the invention, consisting of the spring element 3 and a backdrop 4, is in Figures 3 (a) and 3 (b) shown in two states, wherein in Figure 3 (a) relaxed spring element 3 is shown while in the figure 3 (b) a spring element 3 deformed under the action of force F. is shown.

The spring element 3 has at the end of two legs 3a and 3b are arranged on both sides of the bridge part 3d, end regions 3c on that bent almost L-shaped upwards (in Figure 3) are. Due to the rounding in the end region 3c of the spring element 3, which rests there against the backdrop 4 becomes a uniform one Ensured along the backdrop 4.

The backdrop 4 has in this embodiment on both sides two guide surfaces 4a and 4b, which are at an angle to each other run, which is shown by way of example at about 30 °, and these two guide surfaces 4a and 4b go at a kink K into each other.

Befinden sich die Endbereiche 3c des Federelementes 3 im Bereich der Führungsflächen 4a, so ist die Federkennlinie FK im Bereich 0A, d.h. im Bereich der steileren Linie, während, wenn sich die Endbereiche 3c im Bereich der Führungsflächen 4b befinden, die Federkennlinie FK dann im Bereich AB liegt.If a force F (FIG. 3 (b)) is applied to the unloaded spring element 3 in the central region of the bridge part 3d, the spring element 3 deforms in the manner shown. The bridge part 3d deforms into an arcuate section and the two legs 3a and 3b are bent outwards, so that a W-shaped design of the spring element 3 results. The end regions 3c on the two legs 3a and 3b migrate outwards on the guide surfaces 4a and finally reach the kink or the kink point K - from there the end regions 3c then slide along the guide surfaces 4b. As a result of this spring-link arrangement, a degressive spring characteristic FK of the spring element 3 results, as is shown schematically or idealized in the following diagram:

If the end regions 3c of the spring element 3 are in the region of the guide surfaces 4a, the spring characteristic FK is in the region 0A, ie in the region of the steeper line, while if the end regions 3c are in the region of the guide surfaces 4b, the spring characteristic FK is then in the region AB lies.

a) Geometrie der Feder, d.h. Schenkellänge der Schenkel 3a und 3b, sowie Winkel der Schenkel 3a und 3b relativ zu dem Brückenteil 3d, und Länge des Brückenteils 3d;

b) Werkstoff der Feder; und

c) Geometrie der Kulisse, d.h. Länge der Führungsflächen 4a und 4b, sowie Winkel w der Führungsflächen zueinander.

The spring characteristic curve FK can be set in a particularly simple manner using the following parameters, options a) and c) preferably being used:

a) geometry of the spring, ie leg length of the legs 3a and 3b, and angle of the legs 3a and 3b relative to the bridge part 3d, and length of the bridge part 3d;

b) material of the spring; and

c) geometry of the link, ie length of the guide surfaces 4a and 4b, and angle w of the guide surfaces to one another.

In principle, the spring-link arrangement according to the invention is intended at the beginning of the compression of the spring Spring force rise sharply to a level at which the Spring force is large enough, the mating connector 2 from the connector 1 push out. Because this spring force is the actual mating process counteracts and thus complicates the plugging, the Spring force no longer increase as much in the further course, since in the further course of the plugging the friction between the electrical contacts must also be overcome. Consequently can insert the required force for full insertion the plug-in parts are kept relatively low overall.

The advantages of the connector according to Figures 1 to 3 are to be seen in the fact that the spring element 3 is unstressed and therefore there is no danger of the plastic creeping there is no relaxation of the spring. About that in addition, as already mentioned above, the insertion forces are low to hold because of setting a corresponding spring characteristic is.

FIG. 4 shows the second embodiment of the invention Plug connection shown. Same or equivalent Components have the same reference numerals as for the characterized in the first embodiment.

The spring link arrangement 3, 4 is located in the connector 11 left in the housing, the mating connector 12 in this second Embodiment has a lever 14 which at the beginning of the insertion is pressed down (can be seen in FIG. 4 (b)) and which has an opening 14b at its distal end 14a, which engages with the spring 13. As soon as the Lever 14 is pressed down, the opening 14b with the spring 13 is engaged and the end 14a under the housing part 11a "Plunges", the mating connector 12 can be inserted into the connector 11 be, against the spring force of the spring 13, analog the first embodiment.

The lever 14 can be pressed down manually, or, as shown in FIG. 4, preferably automatically be done by providing two bevels, one at the distal end 14a of the lever 14 and the other at the end of the Housing part 11a, these two bevels lying opposite one another and when inserting the mating connector 12 in the Slide connector 11 past each other.

The backdrop 4 is also in accordance with this second embodiment 3 executed and not shown in Figure 4. The substantially U-shaped spring 13 is in the Connector 1 also arranged horizontally and in cross section preferably round.

4 (c) shows the state in which the mating connector 12 not fully inserted into the connector 11 is. If the insertion process were interrupted here, would the tensioned spring 13 the mating connector 12 from the Slide out plug 11.

If the mating connector 12 is pushed further into the connector 11, so an engagement state is achieved, as in the Figure 4 (d) is shown. The lever 14 then reaches one Position in which it moves due to its own elasticity shifted above and an undercut 14c with a projection 11b engaged. The spring 13 with moved upward as shown by arrow D.

The spring 13 is in this embodiment, in contrast the first embodiment, under tension, is supported however only in the housing of the plug 11 and loaded the mating connector 12 is not. So that is the electrical Connection without spring load 13.

The mating connector 12 is removed by the lever 14 is pressed down on the actuator 14d until the Undercut 14c disengages from protrusion 11b arrives so that the spring force of the spring 13 the mating connector 12th pushes out of the connector 11.

The advantages of the second embodiment can be seen in that on the one hand the mating connector 12 even when pulled out the connector 11 ejected by the spring force of the spring 13 is required, and on the other hand only low insertion forces are to make the plug connection, according to the invention the spring characteristic FK is adaptable and according to the first Embodiment is adjustable.

The third embodiment is described below with reference to the figures 5 and 6 will be explained. Similar to previous embodiments Components are again defined with the same reference numerals.

In Figure 6 it can be seen that the plug 21 is essentially a T-shaped recess 21a into which the lever 14 engages. The mating connector 22 is in this third embodiment Can only be inserted into the plug 21 when the lever is actuated 24 is pushed up to the catch 25 (see Figure 5 (a)) and the lever 14 is pressed down, as shown in Figure 5 (b). Otherwise it works Latch 25 as a plug-in inhibitor.

As soon as the mating connector 22 is inserted into the connector 21, the distal end 14a of the lever 14 enters with the spring 23 Intervention and the further insertion or insertion of the Mating connector 22, the spring 23 is deformed. This will make the Desired ejection force built up in the spring 23, as in the previous embodiments.

If the mating connector 22 is fully inserted into the connector 21, as shown in Figure 5 (c), the Move lever 14 upwards due to its own elasticity, the detent 25 comes in with the T-shaped recess 21a Engagement, and the spring 23 presses the lever actuator 24, in an area 24a so that it is shifted to the right becomes.

The two plug-in parts are locked together and in terms of the general advantages (no relaxation, etc.) when plugging or during the plugging process is based on the earlier embodiments referred.

The specific advantages of this third embodiment are in that there is no spring force K on the connection when the two plug-in parts are completely inserted that through the Location of the spring 23 is given an unlocking protection that only by fully advancing lever actuation 24, in Direction of the latch 25, can be canceled, and that it is not possible to use the lever 14 (accidentally or unintentionally) to push down without lever actuation 24 to operate.

The plug connection is pulled apart by the Lever actuation 24 all the way in the direction of the latch 25 (in the The embodiment shown preferably consists of two locking lugs 25 consisting) is moved, then the lever 14 by means of the lever actuation 24 is pressed down, and then through the spring 23 so biased the mating connector 22 from the Plug 21 is pressed out.

The connector according to the invention works according to the known "go / no-go" principle, however, is done with very simple means realized, so that an overall very user-friendly Solution is available.

The present invention is described in detail by the Execution forms are not limited, but is limited by related claims defined. Also combinations of the above described embodiments or parts thereof possible.

A plug connection, especially for vehicle electronics, consists of two plug-in parts, namely one plug and one a mating connector, being used to produce a flawless electrical connection the two plug-in parts completely into each other pushed and releasably locked together, and a spring element is provided, which between the two Plug-in parts work and which one in the event of a faulty one electrical connection the mating connector from the connector automatically ejects, with a spring-backdrop arrangement for the guide of the spring element is provided, which is a non-linear Spring characteristic causes. The spring force is preferably stronger at the beginning of the insertion process than at a later one Time just before the end of the insertion. At the beginning of Insertion when the electrical contacts in the two The plug-in parts have no contact yet, is the spring force relatively high, so that when the insertion is broken off the two plug-in parts are pushed apart again. To im further course of insertion, namely when the electrical Contacts come into contact with each other and thereby due to the friction causes an increase in the insertion force the overall insertion force is as low as possible hold is the increase in spring force at that point kept lower by changing the spring characteristic, so that overall the lowest possible counterforce when inserting is to be overcome, however, the spring force is always sufficiently large or strong enough to hold the plug-in parts at one to push the incorrect plug-in condition apart and thereby indicate to the user that the connection is not is correct.

Claims (15)

Plug connection, in particular for vehicle electronics, consisting of two plug-in parts, namely a plug (1; 11; 21) and a mating plug (2; 12; 22), the two plug-in parts being pushed completely into one another and to produce a perfect electrical connection are releasably locked together, and a spring element (3; 13; 23) is provided which acts between the two plug-in parts and which, in the event of a faulty electrical connection, removes the mating plug (2; 12; 22) from the plug (1; 11; 21) ejects
characterized in that
a spring-link arrangement (4) for guiding the spring element (3; 13; 23) is provided, which causes a non-linear spring characteristic (FK). Connector according to claim 1,
characterized in that
the spring characteristic (FK) is provided degressively, preferably by at least two linear sections (0A, AB). Plug connection according to claim 1 or 2,
characterized in that
the spring-link arrangement (4) comprises an essentially U-shaped spring element (3; 13; 23) and a link (4), the link (4) having at least two guide surfaces (4a, 4b) for the respective legs ( 3a, 3b) of the spring element (3). Connector according to claim 3,
characterized in that
the spring element (3; 13; 23) is bent at an end region (3c) of each leg (3a, 3b), preferably in the form of an essentially J- or L-shaped bend. Connector according to claim 4,
characterized in that
when the spring element (3; 13; 23) is actuated, the end regions (3c) are guided through the guide surfaces (4a, 4b) and that the end regions (3c) of the spring element (3; 13; 23) are in contact with the guide surface ( 4a, 4b) move. Plug connection according to one of claims 3 to 5,
characterized in that
the spring characteristic (FK) is determined by the geometry of the spring element (3; 13; 23) and / or the geometry of the link (4), preferably the length of the legs (3a, 3b) and / or the length of the guide surfaces (4a , 4b) and / or the angle (w) between the guide surfaces (4a, 4b) is decisive. Plug connection according to one of claims 1 to 6,
characterized in that
the link (4) is provided in a housing of the plug (1; 11; 21). Plug connection according to one of claims 1 to 7,
characterized in that
the spring element (3; 13; 23) is provided in a housing of the plug (1; 11; 21). Plug connection according to one of claims 1 to 8,
characterized in that
a driver (2a) is provided on the mating connector (2; 12; 22) and is inserted into the connector (1; 11; 21) on the spring element (3; 13; 23) when the mating connector (2; 12; 22) is inserted ) acts and deforms it. Plug connection according to one of claims 1 to 9,
characterized in that
a deflection device (5) is provided on the plug (1) which at least partially deflects the spring element (3) when it is fully deformed and brings it into the starting position. Plug connection according to one of claims 1 to 10,
characterized in that
A holding section (6) is provided on the plug (1), which, alone or in cooperation with the spring element (3), fixes the mating plug (2) to the plug (1) when the electrical connection is in perfect condition. Plug connection according to one of claims 1 to 11,
characterized in that
a lever (14) is provided on the mating connector (12; 22) and has a latching element (14c; 25) which serves to lock the plug connection. Plug connection according to claim 12,
characterized in that
the locking element is an undercut (14c) which interacts with a projection (11a) on the plug (11) or is a locking lug (25) which interacts with a recess (21a) on the plug (21). Plug connection according to claim 12 or 13,
characterized in that
A lever actuation (14d; 24) is provided on the lever (14), wherein the plug connection can only be unlocked after the lever actuation (14d; 24) has been actuated beforehand. Plug connection according to one of claims 12 to 14,
characterized in that
the spring element (23) locks the lever (14) in the locked position and that it (23) is relaxed.

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