DE202019105092U1 - Electrical connecting element with clamping effect - Google Patents

Abstract

Electrical connector, with
a contact element (22a, 22b) for establishing an electrical contact,
- a spring element (30a, 30b),
a sliding element (24) for adjusting the spring element (30a, 30b) and contact element (22a, 22b) to one another between an open position and a clamped position,
the spring element (30a, 30b) has a window region (34a, 34b) with a clamping edge (35a, 35b), the window region (34a, 34b) forming an insertion opening for a conductor element (38) in the open position,
- And wherein in the clamping position to achieve a clamping effect, the clamping edge (35a, 35b) is displaced relative to the open position in the direction of the contact element (22a, 22b).

Description

The invention relates to an electrical connecting element.

Electrical connecting elements serve to create electrical connections between electrical conductors. For this purpose, electrical connecting elements can take up electrical conductors and, for example, bring them into contact with current-carrying contacts.

Connectors such as plugs and sockets to which electrical conductors can be connected are known. It is known, after making an electrical contact between an electrical conductor and an open connector, then to screw the connector in order to clamp the electrical conductor against, for example, two-pole contacts.

DE 20 2009 007 573 U1 describes a connection terminal for electrical conductors. There is a busbar inside a housing, against which an elastic clamping element can press an electrical conductor. A slider is located on the outside of the housing and is designed to tension the clamping element in order to press the conductor against the busbar or to reduce the voltage in order to release the clamping effect.

It can be regarded as a task to provide an electrical connecting element which is distinguished by its simple construction and at the same time enables a good and reliable connection.

The object is achieved by an electrical connecting element according to claim 1. Dependent claims relate to advantageous embodiments of the invention.

The connecting element according to the invention comprises a contact element for establishing an electrical contact, a spring element, and a sliding element for adjusting the spring element and the contact element to one another between an open position and a clamped position.

The contact element is designed to make an electrical contact. For example, the contact element can be a plug contact or a socket contact in order to produce an electrical plug connection. For establishing an electrical connection, the contact element is electrically conductive and consists, for example, of a metal. The design of the contact element is such that components such as plugs, sockets or electrical conductors can be connected. For example, there is a flat, elongated shape that can be curved or straight. A rod shape is preferred. A flat rod shape is further preferred, so that the contact element has flat surfaces and is wider in its width than its height.

The spring element is a component that can be elastically deformed. It can assume a relaxed state when no external forces are acting, or be in a tensioned state as soon as external forces counteract the restoring force. The spring element can preferably be placed in differently tensioned states. The spring element preferably consists of a metallic material such as steel or a copper alloy. A non-conductive material, such as plastic, can also be used. The spring element can be a torsion, bending, tension or compression spring, an embodiment as a spiral spring being preferred.

The sliding element is designed such that it can adjust the spring element and the contact element to one another between an open position and a clamping position. The sliding element is a component which, for example, can perform a free or preferably guided movement on curved or straight tracks. Both the design and the movement space in which the sliding element can be moved can be chosen as long as a sliding function and the action on the spring element and / or the contact element are guaranteed. For example, the sliding element can be moved on a curved or a straight path, it can be designed to be angular or rounded. The sliding element is advantageously mounted in such a way that it can be actuated from the outside. For this purpose, it can also have grip elements in order to simplify its operation. The sliding element can act directly or indirectly on the spring element and / or the contact element by being moved. In this way, the sliding element achieves a relative movement between the spring element and the contact element, so that their position relative to one another can be adjusted. The sliding element can act directly or indirectly on one or both elements. A direct mode of action on the spring element is preferred.

The spring element comprises a window area which has a clamping edge. The window area is characterized by a material recess. The shape of the window area can be rounded or a polygon, for example. The material recess is preferably cuboid. The window area is at least partially bordered by a frame. The frame preferably comprises the window area completely. The clamping edge is at least part of the frame. The clamping edge can preferably be a straight section of the frame.

In the open position, the window area forms an insertion opening for a conductor element. For this purpose, the clamping edge is arranged at a distance from the contact element. The geometry of the window area and its positioning are preferred such that a conductor element can be easily inserted. The conductor element can be an electrical conductor such as a stranded wire, a wire or a cable.

The clamping position is characterized in that a clamping effect is generated by the clamping edge being displaced in the direction of the contact element with respect to the open position. The shape of the contact element and that of the clamping edge are advantageously designed to lie flat against one another or to be able to form a line contact. The spring element thus serves to produce a mechanical and the contact element serves to establish an electrical contact with the conductor element. For this purpose, in order to make a contact, the conductor element is fixed under the clamping action between the clamping edge and the contact element and is thus pressed against the contact element.

The connecting element according to the invention is distinguished by the simple design of the spring element and contact element, which is simple in design. A simple and secure clamping of the conductor element is achieved only by moving the spring element and the contact element relative to one another, so that the clamping edge presses the conductor element against the contact element.

This construction can be used, for example, to implement plugs and / or sockets to which, for example, cables or wires are to be connected. For this application, a quick and easy connection of the electrical conductor is advantageous, the electrical and mechanical contact should be stable and reliable.

In a further development, the spring element is tensioned more in the open position than in the clamped position. An external force must be applied to move the spring element and the contact element from the clamped position to the open position. It is preferred that the restoring force of the spring element acts in the direction of the clamping position. This can be advantageous so that the clamping action in the clamping position receives greater reliability due to the restoring force. Furthermore, only a force is required to release the clamping effect. In a preferred manner, an effort can be transferred directly or indirectly to the spring element and / or the contact element via the sliding element. A change in position of the sliding element particularly preferably leads to a change in the spring tension of the spring element.

According to a preferred embodiment, the sliding element is displaceable between a first and a second sliding position, it being coupled to the spring element such that the spring element and the contact element assume the open position in the first sliding position and the clamping position in the second sliding position. In addition to the first and second sliding positions, the sliding element can assume further sliding positions, so that it can put the spring element into further stressed states.

In a further preferred embodiment, the window area is arranged in a window section of the spring element. The spring element is coupled to the sliding element such that when the sliding element moves between the first and the second sliding position, the window section performs a linear movement which is angled to the direction of movement of the sliding element.

The window section can be any region of the spring element, for example an end region of the spring element or a region lying between the ends of the spring element. The window section is particularly preferably located near a free end of the spring element.

The sliding element can perform a displacement movement which runs in any direction in any way, for example curved or linear. It is preferred that the displacement movement is defined and describes the same displacement path when there is a repeated change between the first and second sliding positions. The linear movement of the window section forms an angle with the displacement movement, which is preferably between 40 ° and 140 °, more preferably between 45 ° and 135 °, particularly preferably between 70 ° and 100 °. In this way, the effort to move the sliding element is redirected. The force deflection can be advantageous for the design of the connecting element, since a compact design can be achieved instead of an elongated one.

According to a further development, the spring element has at least one fixing section and one ramp section. The ramp section is arranged at an angle with respect to the contact element. The fixing section is preferred arranged at one end of the spring element. The fixing section is designed to fasten the spring element, for example on a housing part or on the contact element. The ramp section is attached in such a way that it forms an angle with the contact element, which is preferably acute. In the clamped position, the angle is preferably between 15 ° and 60 °, particularly preferably between 15 ° and 45 °. For example, the contact element and / or the ramp area can have a curvature, so that the angle can vary along the ramp.

A preferred embodiment provides that the window area is arranged in a window section angled from the ramp section. In this embodiment, an acute angle is preferred. An angle between 30 ° and 90 ° is particularly preferred. The angle between the contact element and the window section between 80 ° and 100 ° is particularly preferred.

In a further embodiment, the sliding element is arranged such that it can be pushed against the ramp area in such a way that the angle between the ramp area and the contact element is variable depending on the sliding position of the sliding element. This angle thus differs in the first sliding position from that in the second sliding position. For this purpose, the sliding element can be arranged to slide directly or indirectly against the ramp area, preferably directly. The sliding element particularly preferably moves against the ramp area in such a way that it is pressed in the direction of the contact element. The spring element can be tensioned. When moving into the second sliding position, the sliding element moves in such a way that the pressure on the ramp area is reduced and the angle between the contact element and the ramp area increases.

In a further preferred embodiment, the contact element and the ramp area form a first angle in the clamping position and a second angle in the opening position, the first angle being greater than the second angle. The spring element, which comprises the ramp area, is preferably in a more tensioned state in the open position than in the clamped position. In this way, the contact element and the ramp area form a smaller angle with greater tension of the spring element.

In a preferred development, the contact element runs at least partially through the window area. The contact element can end in the window area or run through the window and end outside. For a compact design, it can be advantageous if the contact element runs into the window on one side and ends on the other side, so that it does not protrude beyond the window. It may be preferred that the width of the contact element fills the width of the window.

The connecting element is preferably at least partially surrounded by a housing. The housing can be round or square and adapted to the application environment. In order to ensure a simple construction, the housing is preferably cuboid. It can consist of a material which, for example, protects the components against environmental influences and is also extremely robust. In addition, the material is preferably electrically insulating. For example, a plastic can be selected here. The plastic is preferably glass fiber reinforced in order to increase its robustness. On the one hand, it can be advantageous for the housing to enclose the internal components in order to protect them from environmental influences. On the other hand, it may be preferred to arrange some components partially or completely accessible from the outside, to provide cutouts in the housing or to install components outside the housing, so that functions such as contacting and actuation can be guaranteed.

In a further embodiment, the housing is provided with a housing opening, the housing opening being at least partially aligned with the insertion opening in the open position. The housing opening can, for example, be a round or angular material recess in the housing. In the open position, the housing opening and the insertion opening can be arranged relative to one another such that the insertion opening is freely accessible from the outside and is not completely closed by the housing. The housing opening preferably has the same or larger dimensions than the insertion opening, so that the insertion opening is completely exposed in the opening position. More preferably, the housing opening is funnel-shaped so that it tapers from the outer housing wall to the inner one. The tapered shape can simplify insertion of the conductor element. The aligned arrangement can be advantageous in order to be able to insert the conductor element into the insertion opening without being hindered by a housing wall. At the same time, the housing can continue to provide protection for the internal components.

According to a development, the connecting element comprises a housing with at least one flat outer surface. An actuating section of the sliding element is arranged at least in part in a recess in the housing. The actuating section of the sliding element can be firmly connected to the sliding element or, preferably, in one piece be designed. It can preferably be arranged such that the sliding element can be actuated from the outside through it. For this purpose, it can be designed, for example, in a handle shape.

The actuating section can be arranged in the depression in such a way that it is completely received by it or that it protrudes over the outer wall of the housing.

It is preferably attached so that it is freely accessible from the outside, so that simple operation is guaranteed to a user. The remaining sliding element can preferably be arranged in the interior of the housing.

A flat outer surface of the housing on the one hand offers a simple construction and on the other hand various other components have flat surfaces, so that an arrangement next to one another can be easily realized. The housing preferably has at least two flat outer surfaces which lie opposite one another. The flat surfaces are more preferably parallel to one another, and the housing is particularly preferably essentially cuboid.

According to a further advantageous embodiment, an outer surface of the actuating section lies in one plane with the outer surface of the housing.

The actuating section can lie in a recess of the housing and can be recessed in such a way that its outer surface is flush with that of the housing. The depth of the depression can advantageously correspond to the height of the actuating section. It can be advantageous for the handling of the connecting element that the flat surfaces of the housing are not interrupted either by sinking in or by protruding the actuating section.

In a preferred development, the spring element is arranged at least in part between the contact element and the sliding element. So it can be in contact with these two elements. The spring element is preferably fixed to the contact element, while the sliding element is movable relative to the spring element. It is also preferred that the contact element and the sliding element are arranged parallel to one another. The sliding element is further preferably designed to be pushed further over the spring element in the open position and thus to cover more surface of the spring element than in the clamping position.

In advantageous embodiments, the contact element consists of platinum, nickel, copper, iron or an alloy of these metals. The materials nickel, a nickel-chromium alloy, a nickel-chromium-silicon alloy, a nickel-silicon alloy, iron or a copper-nickel alloy are particularly preferred. These materials can be used advantageously for temperature sensors. The contact element and the conductor element particularly preferably consist of the same material.

According to an advantageous development, the spring element consists of a different material than the contact element. A rustproof material that is robust against moisture can be advantageous. The spring element can more preferably have a lower electrical conductivity than the contact element. The material of the spring element is designed for a mechanical connection and the material of the contact element for an electrical connection.

It can be advantageous that the contact element and the spring element are designed in duplicate, with a sliding element being able to adjust both spring elements and both contact elements to one another.

In a preferred embodiment of the connecting element, a first and a second contact element are provided, the first and the second contact element being made of different materials. In this way, a multi-pole connecting element can be realized. For example, it can be advantageous to provide a positive and a negative pole for a first and a second electrical conductor. In addition, the different choice of materials can be advantageous, for example to connect a temperature sensor which comprises two conductor elements of different materials. A conductor element of the temperature sensor and a contact element each particularly preferably consist of the same material. It can be advantageous if the first contact element consists of iron and the second consists of a copper-nickel alloy. The first contact element can also be advantageously made of nickel and the second of a nickel-chromium alloy.

In a further embodiment, an opening is provided in an outer surface of the housing. There is preferably an opening in two opposite outer surfaces of the housing, which are arranged in alignment. More preferably, no components are attached to the interior of the housing between the two aligned openings, so that a free area remains between them. Advantageously, for example, a rod can be pushed through both openings and thus crossing the housing. While this embodiment represents a first connecting element, preferably the Rod be so long that it can cross a second housing of a second connecting element. In this way, the first, the second and possibly further connecting elements can be arranged precisely next to one another, so that their relative displacements to one another are restricted.

The connecting element offers a reliable clamping effect. This property is advantageous, for example, for the implementation of a plug or socket to which, for example, a cable can be connected. In this case, a stable and secure clamping of the cable is advantageous, and the spring element and the contact element are preferably only moved into the open position against the restoring force to release the electrical connection. The preferred implementations as plugs or sockets differ essentially in the shape of the contact element. While the contact element for a plug is not completely enclosed by the housing, the contact element of a socket lies entirely inside the housing.

• 1 eine perspektivische Ansicht eines ersten Ausführungsbeispiels eines Verbindungselements,
• 2 eine Explosionszeichnung des Verbindungselements gemäß 1,
• 3a - 3d eine Schnittdarstellung verschiedener Stellungen eines Kontaktelements, eines Federelements und eines Schiebeelements in Seitenansicht,
• 4 eine Schnittdarstellung eines Kontaktelements und eines Federelements in vergrößerten Seitenansicht,
• 5a eine perspektivische Ansicht eines zweiten Ausführungsbeispiels eines Verbindungselements,
• 5b eine Explosionszeichnung des Verbindungselements gemäß 5a.

An embodiment of the connecting element according to the invention is explained in more detail below with reference to drawings. The figures show:

• 1 2 shows a perspective view of a first exemplary embodiment of a connecting element,
• 2 an exploded view of the connecting element according to 1 .
• 3a - 3d 2 shows a sectional illustration of different positions of a contact element, a spring element and a sliding element in a side view,
• 4 2 shows a sectional illustration of a contact element and a spring element in an enlarged side view,
• 5a 2 shows a perspective view of a second exemplary embodiment of a connecting element,
• 5b an exploded view of the connecting element according to 5a ,

1 shows a connector 10 as a first embodiment of a connecting element in a perspective view.

The connector 10 includes a housing 12 , which consists of a lower housing part 14 and a cover element 16 is assembled into a closed cuboid. The housing 12 has on a front wall 18 two housing openings 20a . 20b , The housing openings are funnel-shaped and taper from the outer housing wall to the inner. A rod-shaped contact element ends at the upper ends of both housing openings 22a . 22b , Under the contact elements 22a . 22b are the housing openings 20a . 20b circular and freely accessible.

The opposite ends of the contact elements protrude from the opposite rear wall 22a . 22b out.

The cover element 16 has two notches 17a . 17b on its two long sides. Within these notches 17a . 17b are two handles 36a . 36b a sliding element 24 arranged. The handles 36a . 36b fill the length of the notches 17a . 17b not completely off so that they are slidable along this.

2 shows the internal structure of the connector 10 , Between the housing parts 14 . 16 are the two contact elements 22a . 22b , two spring elements 30a . 30b and a sliding element 24 ,

Over the two contact elements 22a . 22b are the spring elements 30a . 30b , over which together the sliding element 24 is arranged. Each is on a contact element 22a . 22b a spring element 30a . 30b arranged. Each spring element consists of a bent flat steel, which is divided into three sections. At one end there is a contact element 22a . 22b parallel fixing section 33a . 33b , This is followed by a ramp section 31a . 31b whose distance to the contact element 22a . 22b itself in the course of the fixing section 33a . 33b enlarged away and so with the contact element 22a . 22b encloses an angle β (see 4 ). The angle β is approximately 20 ° in the position shown. The free end of the spring element 30a . 30b includes the third section, a window section 32a . 32b , in which a rectangular window 34a . 34b is appropriate. The window section 32a . 32b is in the example shown at an angle γ of approximately 70 ° from the ramp section 31a . 31b angled. The lower edge of the window, which is parallel to the contact elements, is a clamping edge 35a . 35b ,

One spring element each 30a . 30b is with its fixing section 33a . 33b on one contact element each 22a . 22b medium one screw each 26a . 26b and a mother 28a . 28b attached.

Over the spring elements 30a . 30b the sliding element is movable 24 arranged so that it areas both spring elements 30a . 30b can cover at the same time. The sliding element 24 comprises a sliding section which points in the direction of the ramp section. On the two sides parallel to the contact elements there is one handle each 36a . 36b , The sliding element 24 is a continuous component, so it with the handles 36a . 36b and the sliding section forms a unit and is made in one piece.

The connector 10 comprises two separate contact units, each with a contact element 22a . 22b , a spring element 30a . 30b and a sliding element shared by both contact units 24 , Both contact units have the same structure and show the same functionality. A first of the two contact units is now described below.

3a to 3d show the first contact unit comprising a first of the two contact elements 22a , a first of the two spring elements 30a and the sliding element 24 ,

The sliding element 24 can be moved between a first and a second sliding position. The first sliding position realizes the open position and the second sliding position the clamping position around a conductor element 38 to fix.

3a shows the sliding element 24 in its right stop position, which is the second sliding position. The leading edge 37 of the sliding element 24 lies in the middle of the ramp 31a of the spring element 30a on. The contact element 22a lies on the clamping edge 35a . 35b of the window 34a a clamping force acts on and between them because the spring element 30a is in a prestressed state. The spring element 30a and the contact element 22a are thus in a clamped position.

3b shows the first sliding position in which the sliding element 24 can be moved to the left stop position by moving it in the direction of the arrow. The sliding element is in the first sliding position 24 continue forward towards the window 34a is moved. The leading edge 37 of the sliding element 24 is at the top of the ramp 31a on. Because the distance between the front edge of the sliding element 24 and the contact element 22a remains constant is the window section 32a compared to 3a , against the restoring force of the spring element 30a , pressed down. The movement of the window section 32a . 32b and that of the sliding element 24 at an angle α (see 4 ) to each other, which is at least approximately 90 °. The movement of the sliding element 24 is thus deflected approximately at right angles. At the same time, the angle β of the ramp section becomes more acute with respect to the second sliding position. This has the consequence that the clamping edge 35a no longer on the contact element 22a , which has remained immobile, but is spaced apart from it. So stays inside the window 34a a free area between the contact element 22a and the clamping edge 35a which acts as an insertion opening for an electrical conductor 38 ( 3c ) can serve. The spring element 30a and the contact element 22a are thus in an open position.

3c also shows the first sliding position. The spring element and the contact element 22a . 22b are still in the open position. To the in 3b arrangement shown is an electrical conductor 38 shown, which is in the direction of the arrow between the clamping edge 35a and the contact element 22a coming into the window from the outside 34a is introduced.

In 3d is the sliding element 24 has been moved back to the second sliding position in the direction of the arrow. As a result, the front edge lies 37 the sliding element back in the middle of the ramp 31a so that the angle β increases and the window 34a is no longer pressed down. By the spring force of the spring element 30a presses the clamping edge 35a . 35b the electrical conductor 38 against the contact element 22a ,

In the 3a - 3d and in 4 The opening and clamping positions shown come for the connector 10 for use. In the connector 10 there are two of the contact units, making two electrical conductors 38 can be connected.

The handles are in the open position 36a . 36b of the sliding element 24 towards the front wall 18 moved (second sliding position). This will make the spring elements 30a . 30b so through the inside sliding edge 37 of the sliding element 24 pushed that window down 34a . 34b with the insertion openings in the housing 12 of the connector 10 align and an electrical conductor in each insertion opening 38 can be introduced. Then the handles 36a . 36b of the sliding element 24 pushed towards the rear wall (first sliding position), the windows move 34a . 34b by the restoring force of the spring elements 30a . 30b up. The introduced electrical conductors 38 are then between the clamping edges 35 and the contact elements 22a . 22b trapped. In this way, the electrical conductors 38 mechanically securely connected and stand with the contact elements 22a . 22b in electrical contact.

The contact elements exist in the example shown 22a . 22b made of different materials. The first contact element 22a is made of nickel, while the second contact element 22b is made of a nickel-chrome alloy. So the electrical conductors 38 one Type K thermocouples can be connected to the contact element without any material transfer at the connection point.

In further embodiments of the connector 10 can the contact elements 22a . 22b are made from other material pairs so that thermocouples of other types can be connected. For example, the first contact element 22a made of a nickel-chromium-silicon alloy and the second contact element 22b consist of a nickel-silicon alloy in order to be able to connect a type N thermocouple. Furthermore, the first contact element 22a made of iron and the second contact element 22b consist of a copper-nickel alloy, so that a type J thermocouple with the connector 10 can be associated.

5a and 5b show a second embodiment of a connector 40 , The connector 40 according to the second embodiment is constructed in the same way as the connector 10 the first embodiment and differs only by an additional strain relief function. During the connector 10 according to the first embodiment, two electrical conductors 38 electrically connected and mechanically fixed, offers the second embodiment 40 with the strain relief an additional reduction in mechanical stress on the electrical conductors 38 and the connection points. The strain relief is implemented by a lid extension 42 that over the front wall 18 protrudes. The lid extension 42 covers the transition at which the electrical conductor 38 inside the case 12 pass. The front part of the lid process 42 is as a half clamp 44 educated. Now becomes a cable, for example 48 with two electrical conductors 38 connected to the connector, so the half clamp is put 44 stabilizing around the top half of the cable 48 , Around the half clamp 44 and the cable 48 there's a clamp around 46 attached which the cable 38 in the half clamp 44 holds and provides additional mechanical stabilization. So hold the half clamp 44 and the clamp 46 the cable 48 even outside the case 12 in a desired position and reduce mechanical stresses, especially tensile forces.

This embodiment already includes the half clamp 44 as part of the housing 12 , so that only the clamp 46 must be used and installed as an additional component. A combination of housing 12 and half clamp 44 on the one hand, offers high stability against mechanical stress. On the other hand, there is no need to install a separate clamp, so that this embodiment provides a time-efficient and precise implementation of the strain relief function.

QUOTES INCLUDE IN THE DESCRIPTION

This list of documents listed by the applicant has been generated automatically and is only included for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 202009007573 U1 [0004]

Claims (15)

Electrical connector, with a contact element (22a, 22b) for establishing an electrical contact, - a spring element (30a, 30b), a sliding element (24) for adjusting the spring element (30a, 30b) and contact element (22a, 22b) to one another between an open position and a clamped position, the spring element (30a, 30b) has a window region (34a, 34b) with a clamping edge (35a, 35b), the window region (34a, 34b) forming an insertion opening for a conductor element (38) in the open position, - And wherein in the clamping position to achieve a clamping effect, the clamping edge (35a, 35b) is displaced relative to the open position in the direction of the contact element (22a, 22b). Electrical connector after Claim 1 , in which - the spring element (30a, 30b) is tensioned more in the open position than in the clamped position. Electrical connector after Claim 1 or 2 , in which - the sliding element (24) is displaceable between a first and a second sliding position, - and wherein the sliding element (24) is coupled to the spring element (30a, 30b) such that the spring element (30a, 30b) is in the first Sliding position assumes the open position and in the second sliding position the clamping position. Electrical connector after Claim 3 , in which - the window area (34a, 34b) is arranged in a window section (32a, 32b) of the spring element (30a, 30b), - and the spring element (30a, 30b) is coupled to the sliding element (24) such that the When the sliding element (24) moves between the first and second sliding positions, the window section (32a, 32b) performs a linear movement which is directed at an angle to the direction of movement of the sliding element (24). Electrical connector according to one of the preceding claims, in which the spring element (30a, 30b) has at least one fixing section (33a, 33b) and one ramp section (31a, 31b), - The ramp section (31a, 31b) is arranged at an angle (β) with respect to the contact element (22a, 22b). Electrical connector after Claim 5 , in which - the window area (34a, 34b) is arranged in a window section (32a, 32b) angled from the ramp section (31a, 31b). Electrical connector after Claim 5 or 6 , in which - the sliding element (24) is arranged so that it can be pushed against the ramp area (31a, 31b) in such a way that the angle (β) between the ramp area (31a, 31b) and the contact element (22a, 22b) depends on the sliding position of the sliding element (24) is changeable. Electrical connector according to one of the Claims 5 - 7 , in which - in the clamped position the ramp area (31a, 31b) and the contact element (22a, 22b) form a first angle (β), - and in the open position the ramp area (31a, 31b) and the contact element (22a, 22b) form a second angle (β), - and wherein the first angle (β) is greater than that of the second angle (β). Electrical connector according to one of the preceding claims, in which - The contact element (22a, 22b) extends at least partially through the window area (34a, 34b). Electrical connector according to one of the preceding claims, in which a housing (12) with a housing opening (20a, 20b) is provided, - The housing opening (20a, 20b) is at least partially aligned with the insertion opening in the open position. Electrical connector according to one of the preceding claims, in which a housing (12) with at least one flat outer surface is provided, - And an actuating section (36a, 36b) of the sliding element (24) is at least partially arranged in a recess (17a, 17b) of the housing (12). Electrical connector after Claim 11 , in which - an outer surface of the actuating section (36a, 36b) lies in a plane with the outer surface of the housing (12). Electrical connecting element according to one of the preceding claims, wherein the spring element (30a, 30b) is arranged at least in part between the contact element (22a, 22b) and the sliding element (24). Electrical connecting element according to one of the preceding claims, - The spring element (30a, 30b) made of a different material than the contact element (22a, 22b). Electrical connector after Claim 14 , - wherein the contact element (22a) is a first contact element, - and wherein a second contact element (22b) is provided, - and wherein the first and second contact elements (22a, 22b) consist of different materials.

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