EP1273072B1 - Insulation piercing connecting device - Google Patents

Description

The present invention relates to an insulation displacement device having a base body, a cutting body held in the base and a closing element guided by the body, which is at least from an opening into a closed position can be transferred, wherein in the open position, a conductor is inserted into the closing element and a in the closing element inserted conductor by transferring the closing element into the closed position into the cutting terminal insertable and durable and can be clamped by the cutting clamp, wherein the cutting clamp is encompassed by an over-spring, which contacts the cutting clamp with contacts and so exerts a pressing force on the cutting clamp.

Such an insulation displacement device is known for example from DE 197 32 182 C1. In her the over-spring is rigidly connected to the insulation displacement terminal.

The object of the present invention is to provide an improved insulation displacement device.

The object is achieved in that the over-spring is arranged on the closing element, so that the contact pieces contact the insulation displacement terminal in the open position in the opening contact areas and in the closed position in the closing contact areas.

Because a variation of the action of the over-spring on the insulation displacement terminal is possible.

If the closing element and the over-spring are integrally connected to each other, the insulation displacement device is particularly simple.

If the closing element and the over-spring are formed as a stamped and bent part, the production of closing element and over-spring is particularly simple.

The actuation of the closing element is particularly easy if a bearing element for an actuating tool is formed on the closing element. Preferably, the bearing element is also part of the stamped and bent part.

When the insulation displacement terminal between the opening contact areas and the closing contact areas is formed such that the pressing force varies upon opening of the closing element from the open position to the closed position, the application of force to the insulation displacement terminal to the respective position of the closing element is adaptable between the opening and closing positions.

When the insulation displacement terminal in the opening and / or closing contact regions and the contact pieces are formed such that the pressure force in the open and / or closed position is minimal, the open and / or closed positions form preferred positions. Their achievement is thus tactile detectable. The minimization of the pressure force can be achieved, for example, in that the insulation displacement terminal in the opening and / or the closing contact regions is tapered. Preferably, the contact pieces are correspondingly tapered.

FIG 1

eine Schneidklemmeinrichtung mit Schließelement, Leiter und Bedienwerkzeug und

FIG 2

eine Schneidklemme mit einem Schließelement.

Further advantages and details emerge from the following description of an embodiment in conjunction with the drawings. This show in a schematic representation

FIG. 1

an insulation displacement device with closing element, conductor and operating tool and

FIG. 2

a cutting clamp with a closing element.

According to FIG. 1, an insulation displacement device has a main body 1. In the main body 1 a cutting clamp 2 is held. The insulation displacement device also has a closing element 3. The closing element 3 is shown in Figures 1 and 2 in an open position. In the open position, a single-core conductor 4 can be inserted into the closing element 3, which does not have to be stripped.

The closing element 3 can be transferred from the opening into a closed position. For this purpose, an actuating tool 5, usually a conventional screwdriver, introduced into a bearing element 6, which is integrally formed on the closing element 3. By pivoting the actuating tool 5 in an actuating direction A, the closing element 3 is then transferred to the closed position. The conductor 4 is thereby inserted into the insulation displacement terminal 2 and held and clamped in the closed position thereof. The position of the conductor 4 in the closed position is symbolized in FIG 2 by a dashed line indicated circle.

On the closing element 3, an over-spring 7 is arranged, which surrounds the cutting clamp 2. The over-spring 7 contacts the insulation displacement terminal 2 with contact pieces 8 and therefore exerts a pressure force F on the insulation displacement terminal 2. Due to the formation of the over-spring 7, in particular due to the presence of front Umgriffslappen 9 and rear Umgriffslappen 10, the over-spring 7 at the same time forms a guide element, due to which the closing element 3 is performed with respect to the insulation displacement terminal 2 and thus in the base body 1.

Due to the arrangement of the over-spring 7 on the closing element 3, the over-spring 7 is moved together with the closing element 3. In the open position of the closing element 3, the contact pieces 8 therefore contact the insulation displacement terminal in opening contact regions 11, in the closed position in the closed contact regions 12. The closure element is apparent here 3 and the over-spring 7 integrally connected to each other. In particular, the closing element 3, the bearing element 6 and the over-spring 7 are formed as a (uniform) stamped-bent part.

According to FIG. 2, the insulation displacement terminal 2 is tapered in the opening and closing contact regions 11, 12. Correspondingly, the contact pieces 8 are also tapered in a curved manner. This design of the insulation displacement clamp 2 and the over-spring 7 ensures that the pressure force F is minimal in these two positions. Thus, preference positions are generated, the achievement of which can be detected tactually.

Between the open and closed positions, however, the cutting clamp 2 is widened bulging. As a result, the pressing force F is varied during the transfer of the closing element 3 from the opening to the closed position in accordance with the bulbous course of the cutting clamp 2.

With the insulation displacement device according to the invention a number of advantages can be achieved. In particular, the pressing force F to the individual process steps in the transfer from the open to the closed position (first insertion and insulation separation, then contacting the conductor 4) adaptable and changeable. Thus, it is possible to implement a force characteristic curve optimized for the individual process steps, which enables ergonomically favorable actuation. The achievement of the two end positions of the closing element 3 is to be effected by minimizing the pressing force F in these two positions on the one hand for sure and on the other tactile detectable. As a result, both the operating forces and the travel distances can be reduced. This results in a relatively small volume of the insulation displacement device. Finally, the insulation displacement device according to the invention can also be used in a larger cross-sectional area than comparable insulation displacement devices of the prior art.

Claims (9)

1. Insulation piercing connecting device with a base body (1), an insulation piercing connector (2) which is held in the base body (1) and a closing element (3) which is guided in the base body (1) and can be transferred at least from one open position into a closed position, it being possible in the open position for a conductor (4) to be inserted into the closing element (3) and it being possible by transferring the closing element (3) into the closed position for a conductor (4) which has been inserted into the closing element (3) to be inserted into the insulation piercing connector (2) and held and clamped by the insulation piercing connector (2), the insulation piercing connector (2) being surrounded by an overspring (7) which contacts the insulation piercing connector (2) with contact pieces (8) and thereby exerts a pressing force (F) on the insulation piercing connector (2), characterized in that the overspring (7) is arranged on the closing element (3), so that in the open position the contact pieces (8) contact the insulation piercing connector (2) in opening contact regions (11) and in the closed position they contact it in closing contact regions (12).
2. Insulation piercing connecting device according to Claim 1, characterized in that the closing element (3) and the overspring (7) are integrally connected to each other.
3. Insulation piercing connecting device according to Claim 2, characterized in that the closing element (3) and the overspring (7) are formed as a punched/bent part.
4. Insulation piercing connecting device according to Claim 2 or 3, characterized in that a bearing element (6) for an actuating tool (5) is formed onto the closing element (3).
5. Insulation piercing connecting device according to Claims 3 and 4, characterized in that the bearing element (6) is also a component part of the punched/bent part.
6. Insulation piercing connecting device according to one of the above claims, characterized in that the insulation piercing connector (2) between the opening contact regions (11) and the closing contact regions (12) is formed in such a way that the pressing force (F) varies when the closing element (3) is transferred from the open position into the closed position.
7. Insulation piercing connecting device according to one of the above claims, characterized in that the insulation piercing connector (2) in the opening contact regions (11) and/or the closing contact regions (12) and the contact pieces (8) are formed in such a way that the pressing force (F) is minimal in the open position and/or the closed position.
8. Insulation piercing connecting device according to Claim 7, characterized in that the insulation piercing connector (2) is narrowed in a curved manner in the opening contact regions (11) and/or the closing contact regions (12).
9. Insulation piercing connecting device according to Claim 8, characterized in that the contact pieces (8) are correspondingly narrowed in a curved manner.

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