EP4032149A1

EP4032149A1 - Terminal for contacting a contact pin

Info

Publication number: EP4032149A1
Application number: EP20772306.5A
Authority: EP
Inventors: Andre Holtkämper
Original assignee: Phoenix Contact GmbH and Co KG
Current assignee: Phoenix Contact GmbH and Co KG
Priority date: 2019-09-19
Filing date: 2020-09-17
Publication date: 2022-07-27
Also published as: JP7407914B2; WO2021053062A1; JP2022548969A; CN114402488A; DE102019125285A1; US20220368053A1

Abstract

The invention relates to a terminal (100) for contacting at least one contact pin (102). The terminal (100) comprises a socket support (104) and at least one socket (106), each of which comprises a first contact arm (108) that is secured to the socket support (104) and a second contact arm (112) that is secured to the first contact arm (108) via a spring elastic connection (110). The second contact arm (112) can be pivoted between a vacant position and an occupied position in the area between the first contact arm (108) and the socket support (104). In the vacant position, the second contact arm (112) is arranged at a first distance to the socket support (104), and in the occupied position, the second contact arm (112) is arranged at a second distance to the socket support (104), said second distance being shorter than the first distance. A restoring force of the spring elastic connection (110) in the occupied position is designed to contact the respective contact pin (102) between the first contact arm (108) and the second contact arm (112).

Description

Terminal for contacting a contact pin

The invention relates to a clamp for making contact with at least one contact pin. In particular, the invention relates, without being restricted thereto, to a corresponding terminal block.

In existing terminal blocks, the individual connections, for example with a width of about 6.3 mm, comprise a double-sided spring contact (for example a tulip contact) as a socket. The use of such spring contacts in a terminal with narrower connections, for example with a width of approximately 3.5 mm, is not possible, since their space requirement in the width direction is too great. The installation space requirement is too great, since the double-sided spring contact itself is too wide as a socket and, furthermore, both contact sides of the double-sided spring contact are springy.

The invention is therefore based on the object of providing a terminal for contacting at least one contact pin, which is narrower or allows more connections in an opposite planar width, preferably without reducing a contact force for contacting the contact pin and / or an absorbable pin width of the contact pin. An alternative or more specific object is to provide a terminal for contacting at least one contact pin which is able to receive the contact pin laterally close to an edge of the terminal.

The object or issues are achieved according to the invention with the features of the independent claim. Appropriate configurations and advantageous developments of the invention are specified in the dependent claims.

Further features and advantages of exemplary embodiments of the invention are described below with partial reference to the drawings. One aspect of the invention relates to a terminal for making contact with at least one contact pin. The clamp comprises a socket carrier and at least one socket. The at least one socket each comprises a first contact arm attached to the socket carrier and a second contact arm attached to the first contact arm via a resilient connection. The second contact arm is pivotable in the space between the first contact arm and the socket carrier between a vacant position and an occupied position. In the vacant position, the second contact arm is arranged at a first distance from the socket carrier. In the occupied position, the second contact arm is arranged at a second distance from the socket carrier, which is smaller than the first distance. A restoring force of the resilient connection in the occupied position is designed to contact the respective contact pin between the first contact arm and the second contact arm.

Since the first contact arm is attached to the socket carrier and the second contact arm is attached to the first contact arm via the resilient connection, in exemplary embodiments the second contact arm pivots from the vacant position to the occupied position under a wedge effect of the contact pin inserted into the socket in the longitudinal direction, while the first Contact arm remains in its position relative to the socket carrier. These or further exemplary embodiments enable a terminal for contacting the at least one contact pin, which is narrower or has more connections in an opposite planar width. A contact force for contacting the contact pin and / or an absorbable pin width of the contact pin can be the same as (or greater than) with a larger double-sided spring contact, for example by doubling a path of the second contact arm between vacant position and occupied position within the elastic range of the spring-elastic connection is as big as a conventional contact arm travel. The same or further exemplary embodiments can enable the contact pin to be received laterally close to an edge of the terminal, for example in that the first contact arm faces the edge of the terminal or is arranged on the edge of the terminal. The terminal can be designed or used as a socket. For example, the clamp can be mounted or mountable on a circuit board. Alternatively or in addition, the terminal can be designed as a series terminal. For example, the terminal can comprise a row or a field of the sockets as connections of the series terminal.

The socket or each of the at least one socket can be designed to receive the respective contact pin between the first contact arm and the second contact arm. Each socket can be designed to receive the respective contact pin along a longitudinal direction of the first contact arm.

The restoring force in the occupied position can push the second contact arm in the direction of the first contact arm. In the occupied position, the contact (or the contacting) can comprise an electrical contact and optionally a frictional connection. In the absence of a contact pin, the restoring force can move the second contact arm out of the occupied position into the vacant position.

The second contact arm can only be attached to the first contact arm. That is, the second contact arm can be attached to the socket carrier indirectly via the first contact arm.

A rigidity of a mechanical connection between the first contact arm and the socket carrier can be greater than a rigidity of a mechanical connection between the second contact arm and the socket carrier. The mechanical connection between the first contact arm and the socket carrier can be stiff compared to the resilient connection between the second contact arm and the socket carrier.

The socket carrier can be an electrical insulator. The socket carrier can be made of a thermoplastic. The socket carrier can form a closed outside of the clamp. The clamp can be a variety of sockets with a socket carrier that is continuously closed on the outside.

A distance between the first contact arm and the socket carrier in the vacant position and in the occupied position can be the same. A distance between the first contact arm and the socket carrier can be at least substantially the same in the vacant position and in the occupied position. For example, a path that the first contact arm travels between the vacant position and the occupied position can be a fraction (for example less than a tenth) of the path that the second contact arm covers between the vacant position and the occupied position.

A longitudinal direction of the first contact arm in the vacant position and in the occupied position can be parallel to the socket carrier.

The first contact arm can be connected to the socket carrier on a longitudinal side along the longitudinal direction.

The clamp can comprise at least two sockets. Optionally, the clamp can furthermore comprise at least one partition wall, which protrudes on the socket carrier and extends in the longitudinal direction, between adjacent sockets. The partition wall can extend parallel to the longitudinal direction adjacent to a longitudinal side of the first contact arm which is opposite the connected longitudinal side.

The first contact arm can be attached to the socket carrier along the connected longitudinal side with a socket wall extending in the longitudinal direction and protruding from the socket carrier, for example directly connected. The socket wall can protrude vertically from the socket carrier. The socket wall can be arranged centrally between adjacent partition walls. The socket wall can (opposite to the connected longitudinal side of the first contact arm) comprise a fastening surface for fastening on the socket carrier. The fastening surface can protrude beyond the socket in the longitudinal direction. The socket wall can be hot-riveted to the socket carrier. For example, the fastening surface can have rivet openings for hot riveting.

A height of the socket wall protruding vertically from the socket carrier can determine the first distance. A diameter or a width of the contact pin can determine the second distance. The second distance can be the first distance minus the diameter or the width of the contact pin.

The socket wall, the first contact arm, the resilient connection and / or the second contact arm can be integrally in one piece. Alternatively or in addition, the socket wall, the first contact arm, the resilient connection and / or the second contact arm can be electrically conductive. The resilient connection can connect the second contact arm to the first contact arm in an electrically conductive manner.

One or more contact points for contacting the contact pin can be between the first contact arm and the second contact arm in the longitudinal direction at the level of the socket wall. The first contact arm and the second contact arm can touch at the contact point in the vacant position.

The first contact arm can have a corrugated projection at the contact point. The second contact arm may be curved away from the first contact arm at the point of contact.

An end of the first contact arm opposite the resilient connection can extend in the longitudinal direction and / or be parallel to the socket carrier. The opposite of the resilient connection The end of the first contact arm can protrude beyond the socket wall in the longitudinal direction and / or parallel to the socket carrier.

The resilient connection can comprise an arch on a transverse side of the first contact arm to the second contact arm. An end of the second contact arm opposite the transverse side (for example connected to the first contact arm in a resilient manner) can be a free end of the second contact arm. The end of the second contact arm opposite the transverse side (connected to the first contact arm in a spring-elastic manner) can be a free end of the pivoting movement between the vacant position and the occupied position. The free end can be movable due to or against the restoring force of the resilient connection.

A continuous connection of the socket wall along the longitudinal side of the first contact arm can be wider than the arc on the transverse side of the first contact arm.

At an end opposite the resilient connection, the second contact arm can have a run-on bevel which is designed to be moved from the vacant position into the occupied position counter to the restoring force by the contact pin.

The terminal can be open on a side opposite the socket carrier and / or be delimited by the first contact arm.

The terminal can furthermore comprise a plug-in surface perpendicular to the socket carrier. The plug-in surface can have a through opening for receiving the respective contact pin in spatial association with each of the at least one socket. The end of the first contact arm opposite the resilient connection can be aligned in the longitudinal direction with the through opening in the plug-in surface for receiving the respective contact pin. An end face of the partition, an end face of the plug-in surface and / or a

Outside of the first contact arm can be parallel to the socket carrier.

The front side of the partition, the front side of the plug-in surface and / or the

Outside of the first contact arm (for example with the exception of the bead at the contact point) can be flush.

The invention is explained in more detail below with reference to the drawings using preferred exemplary embodiments.

Show it:

1 shows a schematic perspective illustration of a clamp according to a first exemplary embodiment in a vacant position;

2 shows a schematic sectional illustration parallel to a longitudinal direction of a clamp according to the first exemplary embodiment in a vacant position;

3 shows a schematic side view in the longitudinal direction of a clamp according to the first exemplary embodiment;

4 shows a schematic perspective illustration of a clamp according to a second exemplary embodiment in an occupied position;

5 shows a schematic sectional illustration parallel to a longitudinal direction of a clamp according to the second exemplary embodiment in the occupied position;

6 shows a schematic sectional illustration of an exemplary

Socket carrier, which can preferably be combined with the first or second embodiment; 7 shows a schematic view of an exemplary stamped part for

Production of a socket, preferably according to the first or second embodiment;

8A shows a perspective view of a variant of the first or second exemplary embodiment; and

8B shows a sectional illustration of the variant of the first or second exemplary embodiment.

1 shows a first exemplary embodiment of a terminal, generally designated by reference numeral 100, for making contact with at least one contact pin 102 (for example a pin).

The terminal 100 comprises a socket carrier 104 and at least one socket 106 (which can also be referred to as a socket or socket). The at least one socket 106 each comprises a first contact arm 108 fastened to the socket carrier 104 and a second contact arm 112 fastened to the first contact arm 108 via a resilient connection 110. The first contact arm can form a rigid contact side of the socket 106.

The second contact arm 112 is pivotable in the space between the first contact arm and the socket carrier 104, namely between a vacant position and an occupied position of the second contact arm 112. The second contact arm can form a resilient contact side of the socket 106.

In the vacant position, the second contact arm 112 is arranged at a first distance from the socket carrier 104. In the occupied position, the second contact arm 112 is arranged at a second distance from the socket carrier 104, which is smaller than the first distance. A restoring force of the resilient connection 110 in the occupied position presses the second contact arm 112 against the respective contact pin 102 and thus also the contact pin 102 against the first contact arm 108, whereby the contact pin 102 between the first contact arm 108 and the second contact arm 112 is in contact on both sides.

The first contact arm 108 is preferably attached to the socket carrier 104 over its extent (for example its entire extent or more than half of its extent) in a longitudinal direction of the socket 106 (which is designated as the y-direction in the first exemplary embodiment in FIG. 1), ie , mechanically connected to the socket carrier 104.

The mechanical connection preferably also establishes an electrical contact, for example to a conductor (preferably a conductor track) on the socket carrier 104. The described mechanical connection conducts the current from the contact point to the foot 114 of the socket 106. The electrical contact between the socket 106 and the conductor (for example a conductor track) can furthermore comprise a soldered connection (preferably not in an embodiment variant with a leadframe).

At the foot 114, the contact is made, for example via the soldered connection, with a conductor track on a circuit board of the socket carrier 104. The foot 114 (for example its support surface) can be adapted to a soldering geometry for the circuit board.

For a compact terminal 100 and / or receiving the contact pin 102 laterally close to the edge of the terminal 100, the first contact arm 108 as a contact side of the socket 106 can be connected directly to the socket carrier 104 (for example a rear wall of the terminal 100). As a result, the first contact arm 108 can be stiff, for example several times stiffer than the second contact arm 112. Since the second contact arm 112 is connected to the first contact arm 108 via the resilient connection 110, the latter can be elastically pivotable. The second contact arm 112 generates a contact force (more precisely: normal contact force) required for contacting in the occupied position of the socket 106, that is, in the plugged-in state of the contact pin ok

While exemplary embodiments describe the resilient connection 110 as a separate section of the socket 106, the resilient connection 110 and the second contact arm 112 can also jointly provide the resilience. For example, the second contact arm 112 can be designed as a flat-shaped spring.

The mechanical connection can comprise a foot 114, for example as shown in FIG. 1. The foot 114 can be attached to the socket carrier 104 over a large area or at points (i.e. in places). For example, the foot 114 of the socket 106 can be materially attached (preferably glued) to the socket carrier 104. As an alternative or in addition, the foot 114 can have through recesses through which the foot 114 is riveted to the socket carrier 104. Alternatively, assembly pins (for example thermoplastic) can be molded onto the socket carrier 104, which are pressed or welded into the through-holes of the foot 114.

The foot 114 can be used to attach the socket 106, and preferably to conduct power to the socket 106. Optionally, the geometry of the foot 114, in particular the end of the foot 114, can be brought into a shape adapted for soldering (for example for connection to the circuit board) or shaped depending on the application.

FIG. 2 shows a schematic sectional illustration parallel to the longitudinal direction of the clamp 100 according to the first exemplary embodiment in the vacant position.

A direct connection 116, for example the socket wall, between the first contact arm 108 (ie the rigid contact side of the socket 106) and the socket carrier 104 achieves a rigidity of the first contact arm 108, for example by the socket 106 being shaped in such a way that the first contact arm 108 is directly connected over the entire length (in the y direction) to the socket carrier 104 of the terminal 100. Preferably the direct connection comprises 116 of the first contact arm 108 has a small lever arm in relation to contact points 118 and 120 of the contact arms 108 and 112, respectively.

In a variant of each exemplary embodiment, the contact points 118 and 120 can touch one another in the vacant position. In another variant, the contact points 118 and 120 can be spaced apart from one another in the vacant position.

In the occupied position (for example in both variants) one of the contact points 118 and 120 can rest on opposite sides of the contact pin 102, pressed by the restoring force.

The contact point 118 on the first contact arm 108 can comprise a bead in the first contact arm 108. The contact point 120 on the second contact arm 112 may include a curvature of the second contact arm 112 that is curved away from the first contact arm 108.

Since the contact point 118 of the first contact arm 108 (i.e. the stiff contact side) is implemented, for example, by a bead, the installation space requirement 124 (i.e. the required installation width) can be small, for example in comparison to a kinked contact arm.

In addition, the electrical current carried through the socket 106 can be diverted by means of the direct connection 116. The mechanical fastening of the socket 106, the rigidity of a contact side of the socket 106 on the first contact arm 108 and the power line to the socket 106 (i.e. from the foot 114 to the contact arms) are preferably achieved by means of the direct connection 116, i.e. by means of the same structural element.

The rigidity of the first contact arm 108 ensures that the contact pin 102, which can move freely in the transverse direction (ie the width direction or x-direction) within certain limits, is aligned with the contact point 118 of the first contact arm 108 during a plug-in process 122 of the contact pin 102 and only the second contact arm 112 during the mating process 122 pivots out (that is, pivots out of the vacant position into the occupied position), in that the resilient connection 110 of the socket 106 bends.

As a result, the space requirement 124 of the socket 106 between an edge 126 of the terminal 100 and the contact point 118 on the first contact arm 108 (or an outer edge of the contact pin 102) can be reduced compared to conventional terminals. For example, an installation space requirement 124 can correspond to a thickness of the first contact arm 108, possibly including a bead at the contact point 118 of the first contact arm 108.

The clamp 100 is preferably open on the side of the first contact arm 108. The first contact arm 108 can delimit the corresponding side of the socket 106.

Furthermore, even with a not ideally aligned arrangement of the socket 106 and a contact pin 102 which is laterally clamped, for example is not freely movable transversely to the longitudinal direction (ie in the x-direction), it is ensured that the edge 126 of the terminal 100 or a The installation space limitation or the installation space requirement 124 on the open side of the terminal 100 is not exceeded, since during the transition from the vacant position to the occupied position, the first contact arm 108 (ie, the stiff side of the socket 106) is not or only negligibly small (for example in the direction of the open side of the clamp 100).

A path (i.e., a spring path) of the second contact arm 112 (for example the flat-form spring) when plugging 122 the contact pin 102 is designed such that the second contact arm 112 swings out in the direction of the non-critical installation space (for example away from the open terminal side).

Fig. 3 shows schematically a side view looking in the longitudinal direction of the clamp 100 according to the first embodiment. The direct connection 116 with a low fleece arm from the first contact arm 108 (more precisely: the contact point 118) to the fastening point on the foot 114 in the terminal 100 achieves a stiff contact support on the first contact arm 108. The restoring force (ie the contact force) in the occupied position of the socket 106 (ie in the inserted state of the contact pin 102) can be determined by a material thickness, a first depth 128 (for example an expansion in the z-direction including the resilient connection 110 and the direct connection 116 ), a second depth 129 (for example an extension in the z-direction of the resilient connection 110) and / or a length (for example an extension in the longitudinal direction or y-direction) of the resilient connection 110 and / or the second contact arm 112 (for example the flat spring).

Preferably, the depth 128 or 129 of the resilient connection 110 and / or of the second contact arm 112 (for example the flat spring) is variable, for example the depth 128 or 129 changes along the length of the resilient connection 110 and / or the second contact arm 112 (for example along the flat spring). For example, in order to design the flat-form spring 110-112 in accordance with the mechanical stress, its depth 128 or 129 can increase from the contact point 120 for fixed clamping on the first contact arm 108. The contact force (preferably the normal contact force or a nominal normal contact force) can be in the range from 1N to 7N, preferably from 2N to 6N.

The small overall depth 128 is also advantageous for insulation requirements, for example near an open side of the terminal 100.

As shown by way of example on the basis of the first exemplary embodiment in FIGS. 1 to 3, exemplary embodiments of the clamp 100 enable a very small installation space requirement 124 of the socket 106 in the area of the relevant width direction. This applies in the vacant position (ie in the unmated state) and also in the occupied position (ie in the inserted state), and optionally taking into account a non-aligned contact pin 102. A height 130 of the direct connection 116, for example the height 130 between the foot 114 as a fastening support and the first contact arm 108, can be determined by the shape of the socket 106, for example a corresponding stamped part.

The clamp 100 may comprise a plurality of sockets 106 which are attached to the same socket carrier 104 next to one another.

4 shows a schematic perspective illustration of a terminal 100 according to a second exemplary embodiment in an occupied position. The second exemplary embodiment can partially or completely develop the first exemplary embodiment. For example, individual or all sockets 106 in the second exemplary embodiment can have individual or all features of the first exemplary embodiment. Interchangeable or matching features of the exemplary embodiments are provided with the same reference symbols.

Furthermore, there are requirements for the air gap and / or the creepage distances between adjacent sockets 106 between sockets 106 arranged next to one another. Embodiments (for example the second embodiment) can meet requirements for the insulation, the air gap and / or the creepage distances more compactly. For example, the socket 106 can make it easier to meet these requirements, since the socket 106 requires little installation space near the open clamp side in the z-direction and the necessary larger installation space (e.g. for fastening the socket 106 by means of the foot 114 in the clamp 100) is displaced into the lower area, ie close to the socket carrier 104 (for example the terminal rear wall). For example, an increase in a distance 132 between the first contact arms 108 of adjacent sockets 106 can be achieved by the construction depth 128 which is reduced compared to conventional sockets (for example due to a construction depth 128 according to the invention). The enlarged distance 132 is advantageous for meeting the requirements for the air gap and the creepage distance, as shown schematically in FIGS. 3 and 4, for example. Optionally, the clearances and / or creepage distances are further enlarged by separating walls 134 between adjacent sockets 106.

The foot 114 of each socket 106 can be attached to the socket carrier 104 by means of mounting pins 136. The assembly pins 136 can engage in through-holes in the foot 114 and connect the foot 114 to the socket carrier 104 with a frictional fit (for example by pressing the assembly pins 136) or with a positive fit (for example by riveting the assembly pins 136).

As an alternative or in addition, individual or all sockets 106 can be fastened on a pedestal 138 of the socket carrier 104. The socket 106 can be fastened in the terminal 100 directly on the socket carrier 104 (for example on the rear wall of the terminal) or on an elevation (for example the pedestal 138). With an increased mounting, less material is required for the bushing 106. It can also be attached to the pedestal 138 by means of riveting.

A plurality of contact pins 102 can each be inserted into their own socket 106 and contacted. The plurality of contact pins 102 can be connections of a relay 140.

5 shows a schematic sectional illustration parallel to the longitudinal direction of the clamp 100 according to the second exemplary embodiment in an occupied position. For example, the relay 140 is plugged in. During the plugging process 122, each contact pin 102 can be received in a respective through opening 142, which is laterally close to the edge 126.

6 shows only exemplary dimensions (in millimeters, with decimal places separated by a point) in a schematic sectional view of an exemplary socket carrier 104, which can be combined with the first or second exemplary embodiment. The advantages described in connection with FIG. 6 can also be used with others Dimensions (for example, as a relative change compared to a conventional clamp to be improved in each case) can be achieved.

Exemplary embodiments of the terminal 100, preferably the second exemplary embodiment, can implement a series terminal with an overall width 144 (for example, reduced compared to conventional terminals), for example of 3.5 mm. The reduced or small overall width 144 can be achieved, inter alia, in that one side of the clamp (for example at the edge 126) is open. Exemplary embodiments of the terminal 100, preferably the second exemplary embodiment, can implement terminals of the reduced or small overall width 144 for plug-in relays 140. By means of the compact sockets 106, the contact pins 102 of the relay 140 can be plugged into a series terminal, for example with an overall width of 3.5 mm, taking into account the space available.

A series of several terminals with inserted relays is still possible. A cranking of the contact pins 102 (for example relay pins) is avoided.

The relay 140 typically has pins, i.e. contact pins 102, which lie in a width direction (which is referred to herein as the x-direction) close to one of the relay housing side walls, for example 0.38 mm and / or as shown in FIG.

In the case of a relay 140 with an overall width of approximately 3.3 mm, this results in a relay arrangement in the terminal 100 in which the pins 102 are close to the open terminal side 126. An arrangement of the relay 140 rotated by 180 ° about the y-axis cannot be implemented, since the pins 102 would be too close to or in the terminal rear wall 104 in this case.

By means of the compact socket 106 of the terminal 100 with a construction that is very narrow in the width direction, a construction space of approximately 0.48 mm and / or as shown in FIG. 6 is made possible, for example. Even when the pin 102 is inserted and taking the tolerances into account, the socket 106 preferably does not protrude beyond the installation space, ie the edge 126, of the clamp 100, for example on the open side.

7 shows a schematic view of an exemplary stamped part for producing the socket 106, for example according to the first or second exemplary embodiment of the clamp 100.

The socket 106 can be produced as a stamped and bent part. In a variant, the stamped and bent part of the socket 106 or a plurality of sockets 106 can be stamped as part of a leadframe (i.e. a carrier strip or connection frame). Optionally, the leadframe can not only be used for production, but can also be used directly in the terminal 100 (for example together with other construction elements on the leadframe).

The socket 106 can advantageously be embodied as part of the leadframe, for example because there is no weld or the like, for example only as a bent part.

FIGS. 8A and 8B show a further exemplary embodiment of the clamp 100, for example a variant of the first or second exemplary embodiment of the clamp 100, in a perspective view or a sectional view. The foot 114 comprises a soldering pin 115, for example for soldering to a circuit board or to a conductor.

Alternatively or additionally, the bead at the contact point 118 of the first contact arm 108 can be larger transversely (preferably perpendicular) to the longitudinal direction (i.e. in the z direction) than in the longitudinal direction (i.e. in the y direction).

As shown on the basis of the above exemplary embodiments, embodiments of the clamp can be made more compact. In addition, the second contact arm (for example the flat-form spring) can be protected from impermissible plastic by the first contact arm (ie the stiff contact side) Deformation be protected, for example when handling the open clamp.

In each exemplary embodiment, an optional support (i.e., a stop) of the second contact arm (for example the flat-form spring) can enable a kinking spring characteristic curve during the plugging process.

Further devices which include all or a subset of the features of the exemplary embodiments, in particular also without individual or without all features of the independent claim, are disclosed herein.

Although the invention has been described with reference to exemplary embodiments, it will be apparent to one skilled in the art that various changes can be made and equivalents used as replacements. Furthermore, many modifications can be made to adapt a particular situation or material to the teachings of the invention. Consequently, the invention is not limited to the disclosed exemplary embodiments, but rather encompasses all exemplary embodiments that fall within the scope of the appended claims.

List of reference symbols

Terminal 100

Contact pin 102

Socket carrier of the terminal, preferably the rear wall of the terminal 104

Terminal 106 socket

First contact arm of socket 108

Resilient connection of the socket 110

Second contact arm of socket 112

Bushing base 114

Solder pin 115

Direct connection between the first contact arm and the socket carrier, preferably socket wall 116

Contact point on first contact arm 118

Contact point on the second contact arm 120

Mating process 122

Construction space required 124

Edge of clamp 126

First depth of connections 128

Second depth of the resilient connection or of the second contact arm 129 fleas of the direct connection 130

Distance between contact arms of adjacent sockets 132

Partitions between adjacent sockets 134

Mounting pins of the socket carrier 136

Pedestal 138

Relay 140

Through hole 142

Overall width 144

Claims

Expectations

1. A terminal (100) for contacting at least one contact pin (102), comprising:

- a socket carrier (104); and

- At least one socket (106) each comprising a first contact arm (108) attached to the socket carrier (104) and a second contact arm (112) attached to the first contact arm (108) via a resilient connection (110), which is in the space between the The first contact arm (108) and the socket carrier (104) are pivotable between a vacant position and an occupied position, the second contact arm (112) being arranged at a first distance from the socket carrier (104) in the vacant position and the second contact arm (112) in the occupied position ) is arranged at a second distance from the socket carrier (104), which is smaller than the first distance, and wherein a restoring force of the resilient connection (110) in the occupied position is designed to push the respective contact pin (102) between the first contact arm (108 ) and the second contact arm (112) to contact.

2. Terminal (100) according to claim 1, wherein a distance of the first contact arm (108) to the socket carrier (104) in the vacant position and in the occupied position is the same.

3. Terminal (100) according to claim 1 or 2, wherein a longitudinal direction of the first contact arm (108) in the vacant position and in the occupied position is parallel to the socket carrier (104).

4. Terminal (100) according to one of claims 1 to 3, wherein the first contact arm (108) is connected on a longitudinal side along the longitudinal direction to the socket carrier (104).

5. The clamp (100) according to claim 3 or 4, wherein the clamp (100) has at least two sockets (106) and furthermore at least one on the socket carrier (104) cantilevered, longitudinally extending partition (134) between adjacent sockets (106).

6. Terminal (100) according to claim 4 and 5, wherein the partition wall (134) extends parallel to the longitudinal direction adjacent to a longitudinal side of the first contact arm (108) opposite the connected longitudinal side.

7. Terminal (100) according to one of claims 4 to 6, wherein the first contact arm (108) is fastened along the connected longitudinal side with a socket wall (116) extending in the longitudinal direction and projecting from the socket carrier (104) on the socket carrier (104) .

8. Terminal (100) according to claim 7, wherein a contact point (118, 120) for contacting the contact pin (102) between the first contact arm (108) and the second contact arm (112) in the longitudinal direction at the level of the socket wall (116) .

9. The clamp (100) according to claim 8, wherein the first contact arm (108) has a corrugated projection at the contact point (118).

10. The clamp (100) of claim 8 or 9, wherein the second contact arm (112) is curved away from the first contact arm (108) at the contact point (120).

11. Terminal (100) according to one of claims 3 to 10, wherein one of the resilient connection (110) opposite end of the first contact arm (108) extends in the longitudinal direction and / or is parallel to the socket carrier (104).

12. Terminal (100) according to claim 11 and one of claims 7 to 10, wherein the end of the first contact arm (108) opposite the resilient connection (110) in the longitudinal direction and / or parallel to the socket carrier (104) via the socket wall (116 ) protrudes.

13. Terminal (100) according to one of claims 1 to 12, wherein the resilient connection (110) comprises an arc on a transverse side of the first contact arm (108) to the second contact arm (112).

14. Terminal (100) according to claim 13 and one of claims 7 to 12, wherein a continuous connection of the socket wall (116) along the longitudinal side of the first contact arm (108) is wider than the arc on the transverse side of the first contact arm (108).

15. Terminal (100) according to one of claims 1 to 14, wherein the second contact arm (112) at one of the resilient connection (110) opposite end has a run-on bevel which is designed to counter the restoring force from the contact pin (102) from the Vacant position to be moved to the occupied position.

16. Terminal (100) according to one of claims 1 to 15, wherein the terminal (100) is open on a side opposite the socket carrier (104) and / or is limited by the first contact arm (108).