DE3923977A1 - Electric cable plug connector - has cable restraint clamped by sliding sleeve wen connector is assembled - Google Patents

Abstract

The connector has a connector body (10) incorporating a cable holder and contact elements (18) for the cable wires, fitted with an axially sliding sleeve (12). This is spring biased in the direction of the contact elements (18). The sliding sleeve (12) lies between the connector housing (10) and a fixed outer sleeve (14). The spring force is compensated by the force acting on the contact elements (18) when the connector is coupled to a counter-connector. The upper end (46) of the sliding sleeve (12) has an opening (48) for the cable (26) pressed against a cable fitting (24) at the end of the outer sleeve (14), to secure the cable. ADVANTAGE - Fixes cable against applied tension.

Description

The present invention relates to a connector Tear protection according to patent DE 38 03 962 C2 according to the Preamble of the main claim.

Electrical devices, such as household appliances, electrical tools and the like., are usually with Connectors that can be inserted into sockets to the Power supply connected. This is fixed Devices relatively easy, since the commonly used Connectors, such as Schuko plugs, due to long-term developments a high security standard exhibit. With moving electrical devices there is against connection problems that are not yet satisfactory could only be solved. So it happens z. B. at the Operation of vacuum cleaners, floor care devices, electrical Hand drills and the like. Often before that the operating staff did not notice when the power supply cable is already taut and, for example, dust suck a pull on the cable and the connected with it where connectors and sockets are exercised. At the Operation of vacuum cleaners can cause the train exerted by the moving vacuum cleaner becomes so strong that the power supply cable or the plug contact may be damaged or even be in the wall solidified socket is torn from the wall. Apart from the increased risk of accidents leads to unnecessary repairs structures and business interruptions.  

From AT 2 20 211 a plug connector with tear protection is known, which has a plug body 4 with contact members and a cable holder 2 firmly connected to it. A sliding sleeve 6 is guided axially displaceably on the plug body and is acted upon by a spring 1 which acts in the direction of the contact members and is supported on the cable holder. When coupling the connector with a mating connector, the sliding sleeve is pushed back against the spring force until the nose 11 arranged on a rod-shaped spring strip 7 snaps into a recess 14 in the sliding sleeve and locks it against the spring force. The spring strip 7 is connected at one end to the plug body and at its other end to the cable laid in a loop within the cable holder. If a stronger pulling force or pressure occurs on the cable in the plug-in direction of the connector or at an angle to it, the spring strip 7 stretches, causing the nose to disengage. As a result, the connector is pressed from the mating connector by means of the spring designed accordingly.

If the tensile forces act at an angle, this can occur Tilt connector. The to push out the plug forces required from the mating connector are relatively large.  

An electrical connector with tear protection, one Contains connector body with contact members and cable holder, whereby a sliding sleeve axially displaces on the plug body bar that is through a towards the contact members acting spring is applied in the patent application P 38 03 962.1. The sliding sleeve is between that Connector body and a fixed outer sleeve arranged, and the tension of the spring is such that it is which with a mated connector with a mating connector binder on the contact members existing holding forces com is pensiert, with an upper cover of the sliding sleeve with an opening for the passage of a cable between the plug body and the outer sleeve slidably held is that the cover in the coupled state of the plug ver binders movable into the area of one at the end of the outside sleeve arranged cable socket is sufficient, the lower edge directly or indirectly connected to it. When out practice one acting on the connector via the cable Traction that is not in the direction of the longitudinal axis of the contact the cable socket adjusts itself according to the Direction of traction on the cable is slanted, causing it to slide sleeve with the support of between sliding sleeve and outside sleeve arranged spring in the direction of the Gegensteckver binder pushes, which results in a correspondingly high, oblique attack fender pulling force of the connector axially from the mating connector connector is pressed.

Such a connector has an effective one Tear protection for stronger pulls, but it has been shown that with weak lateral tensile forces that are little of deviate in the direction of the longitudinal axis of the contact members, the forces pushing axially out of the mating connector are weak, which means that there is little space between the Contact members and the mating connector to a spark  education can come at the contact links. This will make the Safety of the connector endangered.

The object of the present invention is in training the connector of the patent application P 38 03 962.1-34 die To improve the tear protection so that a spark bil Avoidance and thus the safety of the connector can be increased.

This task is solved by an electrical connector binder according to the hallmark of the main claim. The sub claims relate to preferred configurations of the Er finding.

The present invention makes use of a slide sleeve, which is arranged around the plug body. Here the connector body is preferably cylindrical and the sliding sleeve surrounds the plug body in the shape of a cylindrical tube that moves along the connector body is. The sliding sleeve is acted upon by a spring which a pressure on the sliding sleeve towards the contact elements, for example towards the contact pins, exercises.

If a pull is exerted on the power supply cable, which is in at an angle to the axial direction of the connector grips, the one acting on the sliding sleeve is canted Cable socket at the appropriate angle, creating the lock link is released and by the pressure of the no longer locked spring-loaded sliding body and the additional The connector is pulled out of the cable Mating connector is pushed out.  

The cable socket is within the connector free to move towards a side Zugs adjust and thereby the sliding sleeve movement inhibiting locking member triggers, causing movement of the sliding sleeve leads.

An embodiment of the invention is described below of the drawings described by way of example.

Fig. 1 shows a section through an embodiment of the connector according to the invention.

The connector 1 consists of a connector body 10 , which is generally cylindrical in shape and made of an insulating material. On its front side, the plug body 10 contains contact members 18 , for example in the form of contact pins 36 or sliding contacts 38 , which come into current-conducting contact with contact elements in the socket. The arrangement of the contact members can vary locally. Around the plug body 10 around a slidable sliding sleeve 12 is arranged, the outer configuration of which is adapted to the shape of the plug body 10 . According to the cylindrical configuration of the plug body 10 , the sliding sleeve 12 is therefore formed in the form of a cylindrical tube which surrounds the connector body in a movable manner. Around the sliding sleeve 12 around an outer sleeve 14 is arranged which is fixedly connected to the plug body 10 . The fixed connec tion can be effected for example by a bolt 34 , but plug body 10 and outer sleeve 14 can also be made in one piece. The sliding sleeve 12 is displaceable between the plug body 10 and the outer sleeve 14 . For this purpose, the sliding sleeve 12 in the region of the bolt 34 contains a recess 41 in which the bolt 34 is guided and which can limit the displacement path of the sliding sleeve 12 . The outer sleeve 14 has at its upper end, that is, at the end opposite the contact members 18 , a cover 42 with an opening 44 for the lead-through of the cable 26 and the cable socket 24 . The cover 42 is net angeord at a distance from the plug body 10 , which corresponds at least to the path of movement of the sliding sleeve 12 . The sliding sleeve 12 also has an upper cover 46 with an opening 48 for the passage of the cable 26 .

Through the opening 44 in the cover 42 of the outer sleeve 14 , the cable socket 24 is passed such that a lower funnel-shaped part 50 of the cable socket 24 with its edge 28 abuts the upper cover 46 of the outer sleeve 14 when the sliding sleeve 12 is in its upper Position is, that is, in a position opposite the contact members. This position is then taken when the connector is plugged into a socket, the sliding sleeve 12 against the pressure of a spring 16 , which is arranged between the cover 42 of the outer sleeve 14 and the cover 46 of the sliding sleeve 12 and the sliding sleeve 12th applied, is pushed in the direction away from the contact members 18 .

The tension of the spring 16 is dimensioned such that it is compensated in this position by the holding forces existing when the connector is coupled with a mating connector on the contact members 18 . The spring 16 is designed, for example, as a spiral spring.

If a tensile force is exerted on the cable 26 , which acts at an angle to the longitudinal axis of the connector 1 , the cable socket 24 is rotated out of the longitudinal axis by the angle at which the tensile force acts on the cable. Such an angular rotation is indicated in FIG. 1 by a dashed representation of the cable socket 24 . Since the Kabelfas solution 24 at its lower edge 28 , which is bent into a U shape, is held on a projection 54 of the cover 42 on one side, the opposite edge 28 of the movable cable socket 24 moves downward and thereby presses the sliding sleeve 12 towards the contact pins 36 and against the mating connector (e.g. a socket).

The cable socket 24 and the sliding sleeve 12 are also in positive connection via a locking member 22 , which consists, for example, of a groove 58 and a nose 60 engaging in the groove 58 . If the projecting nose 60 engages in the groove 58 , the movement of the sliding sleeve 12 is blocked. If the cable socket 24 is tilted by a pull on the cable 26 by an angle, the lower edge 28 in the direction of the cable socket 24 moves downward and releases the locking member 22 . As a result, the locking of the sliding sleeve 12 is released by the locking member 22 and the sliding sleeve 12 acted upon by the spring 16 exerts a force on the mating connector. Depending on the spring tension, the connector 1 is thereby pressed out of the mating connector, possibly with the aid of the additional force exerted by the train.

In the embodiment of the locking member 22 shown in FIG. 1, the groove 58 is arranged on an extension of the sliding sleeve 12 and the nose 60 on the cable socket 24 .

When the connector 1 is reinserted into a mating connector, for example a socket, the sliding sleeve is pushed back again and the spring 16 is biased again. The locking member 22 snaps back into its locking position.

Claims (5)

1. Electrical connector with tear protection, containing a connector body with contact members and cable holder, wherein on the connector body, a sliding sleeve is axially displaceable, which is acted upon by a spring acting in the direction of the contact members, characterized in that
the sliding sleeve ( 12 ) between the plug body ( 10 ) and a fixed outer sleeve ( 14 ) is arranged, and the tension of the spring is dimensioned so that it is completely or by the existing with the plug connector with a mating connector on the contact members ( 18 ) holding forces is partially compensated or overcompensated, with an upper cover ( 46 ) of the sliding sleeve ( 12 ) with an opening ( 48 ) for carrying a cable ( 26 ) between the plug body ( 10 ) and the outer sleeve ( 14 ) so that it can be moved the cover ( 46 ) in the coupled state of the plug connector ( 1 ) extends into the region of a cable socket ( 24 ) arranged movably at the end of the outer sleeve ( 14 ), the lower edge of which is directly or indirectly connected to it,
and the tension of the spring ( 16 ) is compensated for by a locking member ( 22 ) acting on the cable mount ( 24 ) and the sliding sleeve ( 12 ), wherein when exerting a tensile force acting on the connector ( 1 ) via the cable, which is not in Direction of the longitudinal axis of the contact members ( 18 ) acts, the cable socket ( 24 ) is inclined according to the direction of the tensile force on the cable ( 26 ), whereby the locking member ( 22 ) is released and the sliding sleeve ( 12 ) by the spring ( 16 ) and the tensile force exerted in the direction of the contact members ( 18 ). 2. Electrical connector according to claim 1, characterized in that the locking member ( 22 ) consists of a groove ( 58 ) and a nose engaging therein ( 60 ). 3. Electrical connector according to claim 1, characterized characterized in that the cable holder funnel-shaped in its lower part or is hemispherical. 4. Electrical connector according to claim 1, characterized in that the spring ( 16 ) between an upper inward edge ( 30 ) of the sliding sleeve ( 12 ) and an upper inward edge of the outer sleeve ( 14 ) is arranged. 5. Electrical connector according to claim 1, characterized in that the plug body ( 10 ) and the outer sleeve ( 14 ) are connected by a bolt ( 34 ) or by gluing.