EP0054123A1 - Spring terminal - Google Patents

Abstract

1. Electrical spring terminal with an elongate essentially cylindrical contact element (KK) which has a radial perforation (AK) for receiving a first connecting conductor and a bush-shaped extension (BK) insulated on the outside against contact and possessing a central bore (AB) for receiving a second connecting conductor, there being a sleeve-shaped press-on element (AP) consisting of insulating material, which is mounted so as to be longitudinally displaceable on the contact element (KK) and is forced out of the receiving position for the first connecting conductor by means of spring tension and can be transferred into the receiving position against this spring tension, and which surrounds the contact element (KK) by means of its lower part (IHb) at least in the region receiving the first connecting conductor and by means of its upper part (IHa) in the region of the bush-shaped extension (BK), so as to secure the said contact element (KK) against contact, characterised in that a cylindrical receiving space (AR) for a plug-insulating sheath is formed between the inner face of the upper part (IHa) of the press-on element (AP) and the outer face of the bush-shaped extension (BK) of the contact element (KK).

Description

The invention relates to an electrical contact terminal with a terminal contact element, which has a contact recess for receiving a first connection conductor, and with a slidably mounted with respect to the terminal contact element and in the direction against the receiving position of the connection conductor under spring tension and against this spring tension in an open position convertible pressing element. In practice, such contact terminals are also referred to as "pole terminals" and are widely used for the construction of experimental, but also of permanently installed, or measuring circuits, in the low and medium voltage range.

Contact or pole terminals of the aforementioned type are easy and convenient to use, because after the pressing part has been raised, the connecting conductor can only be inserted into the contact recess, generally a transverse bore of a contact pin or the like, whereupon the locking and contacting occurs simply by releasing the pressing element . The problem with these contact terminals, however, is securing the user against contact with live conductors, especially when the pressing element is raised, because in the usual versions, the contact recess and adjacent areas of the contact element are exposed in this state.

On the other hand, contact or pole terminals with an additional socket part for connecting individual plugs are known. However, the terminal part there does not have a displaceable pressure element which is under spring pressure, but rather a union nut which can be moved by hand between an open position and a pressure position and whose outer bore is designed as a socket contact element. These statements do not meet the above-mentioned class of contact terminals, and they lack the convenience and ease of use to the _A and releasing nClose the conductor. With regard to protection against contact of the user, there are the same disadvantages as with the simple spring contact terminals mentioned.

The object of the invention is to provide a contact terminal which is characterized by convenient handling with flawless protection against accidental contact and has a socket part included in this contact protection for the connection of a second conductor. The inventive solution to this problem is determined in a contact terminal of the type mentioned by the characterizing features of claim l.

Because the formation of the insulating then provided pressing member surrounds touch-safe, there is an effective shielding of the leitfühigen components of the clamping part, the easy handling nClose when _A and releasing the first Conductor is maintained by axially moving the pressing part and also the use of the pressing part for shielding the conductive components leads to a simple construction.

According to an essential further development of the invention, the pressing element has a first insulating sleeve which surrounds the socket contact element in the axial direction of the socket up to at least the height of the socket opening. This results in a particularly effective protection against accidental contact due to the comparatively large axial distance between the outer end of the insulating sleeve on the one hand and the conductive terminal components in the interior of the pressing part on the other.

The contact clamp according to the invention is particularly advantageously designed such that a cylindrical receiving space for a plug insulating element is formed between the inner surface of the first insulating sleeve and the outer surface of the socket contact element. Such a plug-insulating element can surround the conductive plug pin, ie the second connecting conductor, cylindrically at a distance in a conventional manner. This results in a labyrinth-like nesting of the interlocking insulating sleeves and socket elements with comparatively large electrical creepage distances and excellent contact protection when the plug is inserted. This can be further improved by the fact that on the outer surface of the socket contact element an insulating cover is attached.

Further features and advantages of the invention will be explained with reference to the embodiment shown in the drawing. This shows a contact clamp according to the invention with a socket part in a partial axial section.

The illustrated contact terminal comprises a terminal part KT and a socket part BT. The clamping contact element KK is formed pin-shaped and provided with a transverse bore as Kontaktausneh- ^m un ^g AK for receiving a not shown first connection conductor. With an inner bolt section, the terminal contact element KK passes through an insulating base element SE, which is inserted into a bore in a housing plate PL and held on the inside of the housing by means of an insulating washer S and a screw connection V. The socket part BT is formed by a socket contact element BK which is connected in one piece to the terminal part and has a contact recess AB for receiving a second connecting conductor, not shown. The contact element BK consists of an inner, thin-walled, cylindrical guide body LK with an outer insulating cover ID. The latter is extended outwards in the axial direction of the bush beyond the end of the guide body and forms an insulating opening section O _A , so that a safety distance with a corresponding creepage distance is formed between the conductive component of the socket part and the socket opening.

A contact element AP made of insulating material is axially displaceably mounted on the outside of the assembly which is formed overall by pins and is formed by the terminal contact element KK and the socket contact element BK. In the starting position shown, this pressing element is biased outwards in the axial direction by a pressing spring AF against an annular extension A of the contact element BK, the terminal contact recess AK being offset against a corresponding contact opening KO of the pressing element .AP. To insert the first connecting conductor (not shown), for example a corresponding wire end, the pressing part is pressed downward in the axial direction against the pressing spring AF until the contact recess AK is aligned with the contact opening KO. After the pressing part has been released, the connecting conductor is clamped between the contact element KK and the wall of the pressing part AP, so that reliable contacting is ensured. For this purpose, the contact opening KO is provided with an inner reinforcing flange F, which transfers the contact pressure to the connecting conductor. To facilitate handling when inserting the first connection conductor, the outer surface of the pressing part AP is provided with a ring groove surface structure GR.

The overall one-piece pressing element AP has at its outer end section a first insulating sleeve IHa, which engages around the socket contact element BK in the axial direction up to the height of the socket opening, in the rest position of the pressing element shown. This results in the desired shielding of the internal conductor components of the terminal against contact. The comparatively large axial extension of the insulating sleeve IHa results in considerable creepage distances, so that there is a high level of safety even in a humid atmosphere.

Between the inner surface of the first insulating sleeve IHa and the outer surface of the socket contact element BK, a cylindrical receiving space AR is formed for a plug insulating element, for example an insulating sleeve which is conventional per se and surrounds the plug pin with a radial spacing. This results in a mutual axial overlap of several sleeve-shaped insulating parts in the manner of a labyrinth seal with correspondingly high-quality shielding and insulation. The insulating cover ID of the socket contact element also contributes to this, as does the insulating opening section OA at the outer end of the socket guide body LK.

The. inner end portion of the pressing element AP forms a second insulating sleeve IHb, which surrounds the pressing spring AF and the outer part of the base element SE. Here too, the telescopic overlap is dimensioned such that reliable shielding against contact by the user in the maximum after externally shifted position of the pressing element AP is guaranteed. For this telescopic overlap, a third insulating sleeve IHc is formed on the base element SE, which in turn encompasses the inner guide components of the clamping part KT. The one-piece design of the base element with its insulating sleeve also results in a construction part that can be produced with little effort. Overall, the manufacturing effort in a construction of the present type can be kept low despite the significantly improved touch shield.

Claims (10)

_1st Electrical contact terminal with a terminal contact element which has a contact recess for receiving a first connection conductor, and with a slidably mounted in relation to the terminal contact element and which is under spring tension in the direction against the receiving position of the connection conductor and can be converted into an open position against this spring tension , characterized in _that a conductively connected to the terminal contact element (KK), insulated on its outside against contact socket contact element (BK) is provided for receiving a second connecting conductor presser gekennzeich- _ne t and that the clamping element (AP) of the clamping member (KT) consists at least on its outer surface of insulating material and encompasses the conductive components of at least the terminal part (KT) in a contact-safe manner. 2. Contact clamp according to claim 1, characterized in that the pressing element (AP) has a socket contact element (BK) in the axial direction of the socket up to the height of the socket opening encompassing first insulating sleeve (IHa). 3. Contact terminal according to claim 1 or 2, characterized in that between the inner surface of the first insulating sleeve (IHa) and the outer surface of the socket contact element (BK), a cylindrical receiving space (AR) for a plug iso! lierelement is formed. 4. Contact clamp according to one of the preceding claims, characterized in that an insulating cover (ID) is attached to the outer surface of the socket contact element (BK). 5. Contact terminal according to claim 4, characterized in that the insulating cover (ID) projects beyond the guide body (LK) of the socket contact element (BK) in the axial direction of the socket and an insulating section on the inner and outer surface (OA) of the Socket contact element (BK) forms. 6. Contact clamp according to one of claims 2 to 5, characterized in that the pressing element (AP) of the clamping part (KT) is designed as a one-piece, sleeve-shaped insulating material part. 7. Contact clamp according to claim 6, characterized in that the outer surface of the sleeve-shaped pressing part (AP) has at least in its axially outer region a surface structure which facilitates the hand attack. 8. Contact terminal according to claim 6 or 7, characterized in that a the terminal contact element (KK) and a pressure spring (AF) acting in the socket axial direction encompassing second insulating sleeve (IHb) is provided as part of the pressing part (AP). 9. Contact terminal according to claim 8, characterized in that in the axially inner region of the terminal part (KT) a third insulating sleeve (IHc) encompassing the conductive components of the terminal part in this area is provided and that the second and third insulating sleeve (IHb, IHc) telescopically with mutual axial overlap are formed. 10. Contact terminal according to claim 9, characterized in that the third insulating sleeve (IHc) is designed as an integral part of a base element (SE) of the terminal part (KT).

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