EP4033610A1 - Electrical connection assembly - Google Patents

Abstract

The invention relates to a connection arrangement (100) for connecting an electrical conductor (200), with
- a housing (110),
- a conductor connection space (111) formed in the housing,
- a current bar (112) against which the conductor (200) to be connected, which is introduced into the conductor connection space (111), can be clamped,
- a clamping spring (113) which has a clamping leg (115) which can be moved into a clamping position and into an open position,
- An actuating element (116) by means of which the clamping leg (115) of the clamping spring (113) can be transferred from the clamping position to the open position, and
- a release element (124),
- wherein in the open position the actuating element (116) is positioned in such a way that the actuating element (116) is latched to the housing (110) in order to hold the clamping leg (115) in the open position,
- wherein the latching between the housing (110) and the actuating element (116) can be released by means of the release element (124).

Description

The invention relates to a connection arrangement for connecting an electrical conductor. The invention further relates to an electronic device.

Such connection arrangements usually have a clamping spring designed as a leg spring, which has a retaining leg and a clamping leg, wherein a conductor inserted into the connection arrangement can be clamped against a current bar by means of the clamping leg of the clamping spring. If, in particular, flexible conductors are clamped, the clamping spring must already be moved into an open position by means of the actuating element before the conductor is inserted and thus actuated in order to pivot the clamping spring or the clamping leg away from the current bar so that the conductor can enter the intermediate space forming the conductor connection space between the current bar and the clamping spring can be inserted. Only in the case of rigid and therefore stable conductors can the conductor exert sufficient force on the clamping spring or the clamping limb of the clamping spring in order to be able to pivot the clamping limb away from the conductor rail without the user having to actuate the actuating element for this purpose. In the case of flexible conductors, the user must first pivot the clamping spring away from the current bar by actuating the actuating element, so that the flexible conductor can be inserted. To clamp the inserted conductor, the operating element has to be actuated manually again by the user in order to move the clamping spring from the open position to the clamping position. The actuation of the actuating element by the user makes the assembly or connection of the conductor more difficult for the user, since handling is cumbersome and the expenditure of time increases as a result.

The invention is therefore based on the object of making available a connection arrangement and a connection device in which the connection of, in particular, flexible conductors can be improved.

The object is achieved according to the invention with the features of the independent claims. Expedient configurations and advantageous developments of the invention are specified in the dependent claims.

The connection arrangement according to the invention essentially has a housing, a conductor connection space formed in the housing, and a current bar which the conductor to be connected, inserted into the conductor connection space, can be clamped, a clamping spring which has a clamping limb which can be moved into a clamped position and an open position, an actuating element by means of which the clamping limb of the clamp spring can be moved from the clamped position into the open position, and a release element, wherein in the open position the actuating element is positioned such that the actuating element is latched to the housing in order to hold the clamping leg in the open position, the latching between the housing and the actuating element being releasable by means of the release element.

By means of the connection arrangement according to the invention, a flexible conductor can now also be connected easily and securely and clamped against the current bar. The clamping spring is preferably designed as a leg spring which has a holding leg and a clamping leg which is designed to be pivotable relative to the holding leg. The holding leg is preferably arranged in a fixed position. By a pivoting movement of the clamping leg of the clamping spring, it can be moved into an open position in which the clamping leg is arranged at a distance from the current bar and a conductor to be connected can be inserted into or out of the conductor connection space in an intermediate space formed thereby between the current bar and the clamping leg, and in a clamping position, in which the clamping leg can rest on the current bar or on the connected conductor in order to clamp the conductor against the current bar, can be transferred. The transfer of the clamping leg, in particular from the clamped position to the open position, takes place by means of an actuating element. The actuating element is preferably movably guided in a purely linear manner in the housing. The actuating element preferably has an actuating section on which an actuating surface is formed, with which the actuating element bears against the clamping leg when the clamping leg is actuated. In order to be able to hold the clamping leg in the open position without the actuating element having to be held in this position manually, the housing and the actuating element are designed in such a way that the actuating element forms a latch with the housing in the open position and thus latches on the housing. The actuation element can be latched to the housing preferably in the area of the actuation section of the actuation element. On the housing, the latching can take place on an inner wall of the housing. A release element is provided according to the invention for releasing this latching. If the latching is released, the actuating element can be moved freely again within the housing and by means of the spring force of the clamping leg of the clamping spring, the clamping leg can act on the actuating element in such a way that the clamping leg can pivot from the open position into the clamping position. The release element preferably acts directly on the actuating element to cancel the latching. The release element and the actuating element are thus preferably in an operative connection at least when the latching is released. The release element is preferably a separately formed component which is arranged within the housing. The release element enables easy handling of the release of the latching between the actuating element and the housing in order to convert the clamping leg of the clamping spring from the open position into the clamping position. The release element can preferably be actuated in different ways. The release element represents an auxiliary tool which can make it easier to connect flexible conductors, in particular.

The release element is preferably positioned in such a way that it is guided essentially parallel to the actuating element. The direction of actuation of the actuation element is thus preferably aligned parallel to the direction of actuation of the release element. The release element is preferably guided in a purely linear manner in the housing. The release element can be designed in the form of a slide.

The release element is preferably arranged between the actuating element and the conductor connection space. The release element can laterally delimit the conductor connection space at least in certain areas. Such an arrangement of the release element between the actuating element and the conductor connection space allows a particularly compact configuration of the arrangement. The actuating element can be arranged between the release element and the clamping spring.

The release element can have an opening through which the clamping leg of the clamping spring can protrude. The clamping leg can thus be guided into the conductor connection space via the opening on the release element. The clamping leg can thus be passed through the release element. The opening on the release element is preferably designed like a window, so that the opening is surrounded on all sides by the material of the release element. Alternatively, it is also possible for the release element to have a reduced width, so that the clamping leg can be guided past the release element into the conductor connection space.

To form the latching, the actuating element can have a latching edge which can interact with an undercut formed on the housing. The undercut can be formed on an inner wall of the housing. In the open position, the latching edge of the actuating element can hook behind the undercut of the housing. By means of the spring force of the clamping leg, which rests against the actuating element in the open position, the actuating element can be securely clamped with its latching edge against the undercut, so that an unintentional release of the latching can be reliably prevented. The latching edge is preferably formed on the actuating section of the actuating element.

To release the locking, the release element is preferably in direct contact with the actuating element, so that the release element can act directly on the actuating element. The release element and the actuating element can preferably slide along one another. For example, the actuating element can have at least one guide bevel and the release element can have at least one guide bevel, with the at least one guide bevel of the release element being able to slide along the at least one guide bevel of the actuating element to release the latching. The at least one guide bevel of the actuating element preferably has the same inclination as the at least one guide bevel of the release element. The at least one guide bevel of the actuating element is preferably formed on the actuating section. The actuating element preferably has two guide bevels formed parallel to one another. The latching edge of the actuating element can be formed between these two guide bevels of the actuating element. If the actuating element has two guide bevels, the release element preferably also has two guide bevels. The two guide bevels can prevent the actuating element and/or the release element from tilting when the locking mechanism is released. The two guide bevels of the release element can be arranged on the release element in such a way that the opening of the release element is formed between the two guide bevels. The two guiding bevels can limit the opening laterally.

If the actuating element is latched on the housing, the release element is preferably also arranged at a defined, fixed position relative to the actuating element. In order to achieve this, a positive connection can be formed between the actuating element and the release element in the open position. For example, the release element can have at least one clearance for this purpose, into which the actuating element can be immersed in the open position. The actuating element can preferably be immersed in this opening with its actuating section.

In order to be able to connect flexible conductors in particular without tools, the release element can have an actuating surface which can protrude into the conductor connection space and via which the release element can be actuated by means of the conductor to be connected. The release element can protrude into the conductor connection space with its actuating surface in such a way that the release element can delimit the conductor connection space in the insertion direction of the conductor with its actuating surface. The actuating surface preferably extends transversely to the insertion direction of the conductor to be connected into the conductor connection space. When the conductor to be connected is inserted into the conductor connection space, the conductor can hit the actuating surface in the insertion direction in order to actuate the release element in such a way that the release element releases the latching between the actuating element and the housing. If the conductor hits the actuating surface, the release element is moved in the direction of insertion, as a result of which the release element can slide along the actuation element and the release element can thereby tilt the actuation element in a direction transverse to the direction of insertion, so that the latching of the actuation element with the housing is released and the actuation element can be guided counter to its actuating direction by the spring force of the clamping leg of the clamping spring in order to release the clamping leg so that it can move from the open position into the clamping position. The actuating surface can be formed on an actuating portion of the release element, wherein the actuating portion can extend transversely to a main portion of the release element. As a result, the release element can have an L-shape.

Additionally or alternatively, the release element can have a handle section for actuating the release element manually or by means of a tool. The handle section is preferably arranged at a free end of the release element. If the release element has a handle section and an actuation surface, then the handle section is formed on a free end of the release element that is remote from the actuation surface. The handle section can protrude through a housing slot, with the actuating element also being able to protrude through this housing slot. The release element and the actuating element can thus be guided in one and the same housing shaft. For manual operation, the handle section can protrude from the housing shaft and thus from the housing, so that it can be easily operated by a user. However, the handle section can also end flush with an outer surface of the housing, so that an unintentional actuation of the release element by means of the handle section can be prevented. The handle section can then have a tool engagement surface, via which the handle section can be actuated by means of a tool. The release element can be actuated by the handle section without the conductor to be connected, which is particularly advantageous in the case of conductors with a very small cross-sectional area. The grip portion is preferably elongate in the shape of a pin or a finger.

The connection arrangement can also have a first spring element which can interact with the actuating element. This first spring element can interact with the actuating element in such a way that the first spring element, during the transfer from the open position to the clamping position, applies a spring force against the actuating element in such a way that the actuating element is counteracted not only by the spring force of the clamping leg but also by the spring force of the first spring element the actuating direction of the actuating element is moved in order to be able to ensure complete release of the clamping leg by the actuating element in the clamping position of the clamping leg. The first spring element can thus form a restoring spring. By means of the first spring element, the actuating element can be guided so far in the housing slot in the clamped position that the actuating element is flush with the outer surface of the housing or even protrudes a little out of the housing slot and thus out of the housing. The actuating element can thus also form a display element which shows a user when the clamping leg of the clamping spring is in the clamping position. The first spring element can be arranged with a first free end on an inner wall of the housing and with a second free end on the actuating element.

It is also possible for the connection arrangement to have a second spring element which can interact with the release element. The second spring element can apply a spring force to the release element, which can act on the release element counter to the insertion direction of the conductor. The second spring element can thus form a return spring. If the release element is actuated in the direction of actuation by means of the conductor to be connected, either manually or by means of a tool, the release element is pretensioned against the spring force of the second spring element, so that the release element automatically returns to its position after actuation and thus the release of the latch between the housing and the actuation element starting position can move. In this initial position, the actuating element can again engage with the release element, in particular in the region of the release of the release element, when transferring from the clamping position to the open position. The second spring element can be arranged with a first free end on an inner wall of the housing and with a second free end on the release element, in particular on the actuating section of the release element.

The first spring element and the second spring element can be positioned in such a way that they have the same spring action direction. The connection arrangement can have only the first spring element or only the second spring element or the first and the second spring element or no such spring element at all.

The release element can be designed in one piece or in two pieces. In a one-piece design, the handle portion is integrally molded to the main portion of the release member. In the case of a two-part design, the handle section rests with one of its two end faces on an end face of the main section.

Furthermore, the object according to the invention is achieved by means of an electronic device which has at least one connection arrangement designed and developed as described above. For example, the connection arrangement can be embodied in a connection terminal, such as a terminal block. This terminal block can be snapped onto a mounting rail and arranged together with the mounting rail in an electronic device, which is then designed as a control cabinet.

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

Fig. 1

eine schematische Schnittdarstellung einer Anschlussanordnung gemäß der Erfindung in einer Offenstellung des Klemmschenkels der Klemmfeder,

Fig. 2

eine weitere schematische Schnittdarstellung der in Fig. 1 gezeigten Anschlussanordnung in der Offenstellung,

Fig. 3

eine schematische Schnittdarstellung der in Fig. 1 gezeigten Anschlussanordnung beim Betätigen des Löseelements mittels eines Leiters,

Fig. 4

eine schematische Schnittdarstellung der in Fig. 1 gezeigten Anschlussanordnung in einer Klemmstellung des Klemmschenkels der Klemmfeder,

Fig. 5

eine schematische Darstellung der in Fig. 1 gezeigten Anschlussanordnung beim Betätigen des Betätigungselements zur Überführung des Klemmschenkels von der Klemmstellung in die Offenstellung,

Fig. 6

eine schematische Darstellung der in Fig. 1 gezeigten Anschlussanordnung,

Fig. 7

eine schematische Darstellung des Löseelements, und

Fig. 8

eine schematische Darstellung des Betätigungselements.

Show it:

1

a schematic sectional view of a connection arrangement according to the invention in an open position of the clamping leg of the clamping spring,

2

another schematic sectional view of in 1 connection arrangement shown in the open position,

3

a schematic sectional view of in 1 connection arrangement shown when actuating the release element by means of a conductor,

4

a schematic sectional view of in 1 connection arrangement shown in a clamping position of the clamping leg of the clamping spring,

figure 5

a schematic representation of the in 1 connection arrangement shown when actuating the actuating element for transferring the clamping leg from the clamping position to the open position,

6

a schematic representation of the in 1 shown connection arrangement,

7

a schematic representation of the release element, and

8

a schematic representation of the actuating element.

1 shows a connection arrangement 100 in a sectional view. This connection arrangement can be integrated, for example, in a connection terminal, such as a terminal block.

The connection arrangement 100 has a housing 110 made of an insulating material. A conductor connection space 111 is formed in an interior of the housing 110, within which the conductor 200 to be connected is connected. A current bar 112 projects into the conductor connection space 111 , against which the conductor 200 to be connected can be clamped and connected by means of a clamping spring 113 . The clamping spring 113 is designed as a leg spring which has a holding leg 114 and a clamping leg 115 . The conductor 200 to be connected is clamped against the current bar 112 by means of the clamping leg 115.

To move the clamping leg 115 into an open position, as shown in 1 is shown, and in a clamped position as shown in 4 As shown, an actuator 116 is provided. The actuating element 116 is guided essentially linearly in a housing shaft 117 of the housing 110 . The actuating element 116 has an actuating section 118 at its lower end in the actuating direction _BB of the actuating element 116 . An actuating surface 119 is formed on an outer peripheral surface of the actuating section 118 and is in operative connection with the clamping limb 115 in particular when the clamping limb 115 is actuated. At an upper end, the actuating element 116 has a tool engagement surface 120 into which a tool 300, such as a screwdriver, can engage in order to actuate the actuating element 116 by guiding the actuating element 116 in the actuating direction _BB , as shown in FIG figure 5 is shown.

As in particular in 8 As can be seen, the actuating element 116 has a latching edge 121 in the region of its actuating section 118 . About this latching edge 121, the actuating element 116 can latch in the open position on an inner wall 122 of the housing 110, as in the sectional view of FIG 2 can be seen. In this area, the inner wall 122 has an undercut 123 on which the actuating element 117 can hook with its latching edge 121 . This latching allows the actuating element 116 and, via the actuating element 116, the clamping leg 115 of the clamping spring 113 to be automatically held in the open position.

The connection arrangement 100 has a release element 124 for releasing this latching. The release element 124 is introduced into the interior of the housing 110 via the housing shaft 117 . The release element 124 and the actuating element 116 are thus movably guided in the same housing shaft 117, as for example in 1 can be seen. The release element 124 is guided in the housing 110 in a purely linear manner. The release element 124 is guided parallel to the actuating element 116 .

The release element 124 has here, as well as in particular in 7 can be seen, an L-shape. The release element 124 is arranged between the conductor connection space 111 and the actuating element 116, so that the release element 124 laterally delimits the conductor connection space 111 at least in sections.

The release element 124 has an opening 125, in particular a window-like opening, through which the clamping leg 115 can protrude in the open position and in the clamping position, as can be seen in the figures. The clamping leg 115 can be moved freely between the conductor connection space 111 and the clamping spring 113 despite the provision of the release element 124 and the arrangement of the release element 124 . The opening 125 is formed at a main portion 140 of the release member 124 .

To release the latching between the actuating element 116 and the housing 110, by actuating the release element 124, the release element 124 can slide in the actuating direction B _L along the actuating element 116 in such a way that the actuating element 116 has its latching edge 121 clear of the undercut 123 of the inner wall 122 of the housing 110 is pushed away, so that the actuating element 116 is disengaged and can move freely again and is guided by the spring force of the clamping leg 115 counter to the actuating direction _BB of the actuating element 116, and the clamping leg 115 can therefore also be moved from the open position into the clamping position.

The release element 124 has, as in 7 is shown, in the embodiment shown here has two guide bevels 126a, 126b, which are formed on the actuating element 116 with guide bevels 127a, 127b, as in FIG 8 is shown, can interact. To release the latch, the release element 124 rests with its guide bevels 126a, 126b flat on the guide bevels 127a, 127b of the actuating element 116, so that the release element 124 can slide along the actuating element 116 to release the latch, causing the actuating element 116 to move laterally in direction Q is deflected or tilted slightly so that the latching between the latching edge 121 and the undercut 123 can be released. The guide bevels 126a, 126b, 127a, _127b are each designed as inclined surfaces which are inclined to the respective actuation direction _BB and BL.

The guide bevels 127a, 127b of the actuating element 116 are formed on the actuating section 118. The locking edge 121 is formed between the two guide bevels 127a, 127b.

On the release element 124, the two guide bevels 126a, 126b form lateral boundary surfaces of the opening 125.

A clearance 128a, 128b is also formed on the release element 124, into which the actuating element 116 can enter with its actuating section 118 in the open position, so that the release element 124 can be held in a fixed position relative to the actuating element 116 in the open position of the clamping leg 115 and so that an unwanted relative movement between the release element 124 and the actuating element 116 is not possible, as in particular in 1 can be seen. The release element 124 has a clearance 128a, 128b in the side walls 129a, 129b of the release element 124 to the side, to the right and to the left of the opening 125 . The clearances 128a, 128b are each formed below the guide bevels 126a, 126b, as seen in the actuation direction B _L . The clearances 128a, 128b are directly adjacent to the guide bevels 126a, 126b. The guide slopes 126a, 126b are also both formed on the side walls 129a, 129b. If the latching is released, the actuating element 116 can be guided with its actuating section 118 directly out of the clearances 128a, 128b along the guide bevels 126a, 126b by the movement of the release element 124 in the actuating direction B _L .

In the embodiment shown here, the release element 124 has an actuating section 130 on which an actuating surface 131 is formed. The actuating section 130 is formed directly on the main section 140 of the release element 124 . The actuating section 130 and thus the actuating surface 131 extend transversely to the main section 140 of the release element 124.

The actuation section 130 protrudes into the conductor connection space 111 in such a way that the conductor connection space 111 is delimited at the bottom by the actuation section 130 . The release element 124 can be actuated via the actuation section 130 by a conductor 200 inserted or introduced into the conductor connection space 111 in the insertion direction E when the conductor 200 abuts against the release element 124 . If the conductor 200 hits the actuating surface 131, as in 3 is shown, the release element 124 is moved in the actuating direction B _L down, whereby the release element 124 slides along the actuating element 116 and the actuating element 126 is thereby actuated in such a way that the actuating element 116 from the latching with the Housing 110 is pressed in direction Q and thus the latching between the actuating element 116 and the housing 110 is released.

Furthermore, the release element 124 also has a gripping section 132, as in particular in 7 can be seen, wherein the release element 124 can also be actuated manually or by means of a tool via the handle section 132 . The handle section 132 is designed here in the form of an elongate pin or rod. The release element 124 is guided through the housing shaft 117 with the handle section 132 . As in 1 is shown, the release element 132 can protrude with its handle section 132 in the open position from the housing shaft 117 and thus from the housing 110 .

In the embodiment shown here, the release element 124 is formed in two parts, in that the grip section 132 is formed as a component that is separate from the main section 140 and the actuating section 130 . The handle section 132 then rests against the main section 140 at the front. However, it is also possible for the handle section 132 to be connected to the main section 140 in one piece. The main section 140 extends between the handle section 132 and the actuating section 130. The handle section 132 forms an extension of the main section 140 from.

The release element 124 is in operative connection with a second spring element 133. The second spring element 133 forms a restoring spring, via which the release element 124 returns to its initial position counter to the actuation direction B _L after the latching between the actuation element 116 and the housing 110 has been released. like you in 1 is shown is moved. The second spring element 133 is arranged with a first end 134 on the housing 110 and with a second end 135 opposite the first end 134 the second spring element 133 is arranged on the release element 124, in particular on the actuating section 130 of the release element 124.

Figures 1 and 2 show the clamping leg 115 of the clamping spring 113 in the open position, in which the clamping leg 115 releases the conductor connection space 111 so that a conductor 200 can be inserted into it. The clamping leg 115 is held in the open position via the actuating element 116 in that the actuating element 116 rests on the clamping leg 115 and presses against the clamping leg 115 . The actuating element 116 is thus on the locking edge 121 on the undercut 123 of

Inner wall 122 of the housing 110 latches, so that the actuating element 116 is held in a fixed position and thus a release of the clamping leg 115 from the open position can be prevented. In this position, the actuating element 116 has its actuating section 118 immersed in the clearances 128a, 128b of the release element 124, as a result of which the release element 124 is held in a fixed position relative to the actuating element 116 in a form-fitting manner.

3 shows a conductor 200 inserted into the conductor connection space 111 in the insertion direction E, which abuts the actuation surface 131 of the release element 124 and thus actuates the release element 124 by the release element 124 being moved in the actuation direction B _L by inserting the conductor 200. As a result of this downward movement of release element 124 in the actuation direction B _L , the release element 124 slides with its guide bevels 126a, 126b along the guide bevels 127a, 127b of the actuation element 116, so that there is a relative movement between the release element 124 and the actuation element 116, and as a result the actuation element 116 is tilted in a direction Q transverse to the direction of actuation B _L , as a result of which the latching edge 121 can unhook from the undercut 123 and the actuating element 116 can be released from the latch and thus from the housing 110, as in FIG 3 can be seen. The actuating element 116 is then also led out of the openings 128a, 128b of the release element 124 again. The spring force acting on the actuating element 116 from the clamping leg 115 then guides the actuating element 116 in the opposite direction to the actuating direction _BB , so that the clamping leg 115 can move from the open position to the clamping position and thereby clamp the inserted conductor 200 against the current bar 112 and can connect as in 4 can be seen.

In order to completely detach the actuating element 116 from the clamping leg 115 and release it, a first spring element 136 can be provided, which in 4 is shown. The first spring element 136 can serve as a return spring and return the actuating element 116 to its initial position, as shown in 4 is shown. The first spring element 136 allows the actuating element 116 to be moved upwards as far as possible, so that the actuating element 116 in the starting position can end flush with an outer surface 137 of the housing 110 with its tool engagement surface 120 or can protrude from the housing 110. The first spring element 136 has a first end 138 with which the first spring element 136 at the Inner wall 122 of the housing 110 is arranged. Furthermore, the first spring element 136 has a second end 139 which is opposite the first end 138 and with which the first spring element 136 can be arranged on the actuating element 116 .

In order to return the clamping leg 115 from the clamping position back to the open position, the actuating element 116 can be actuated with a tool 300 and guided in the actuating direction _BB , as shown in FIG figure 5 is shown, with actuating element 116 being guided in actuating direction _BB until actuating element 116 latches on inner wall 122 of housing 110 and actuating section 118 of actuating element 116 has entered openings 128a, 128b on release element 124.

6 shows the connection arrangement 100 in a non-sectional representation.

Reference List

100

connection arrangement

110

Housing

111

conductor connection room

112

power bar

113

clamping spring

114

holding leg

115

clamp legs

116

actuator

117

case bay

118

operating section

119

operating surface

120

tool engagement surface

121

locking edge

122

inner wall

123

undercut

124

release element

125

opening

126a, 126b

guide bevel

127a, 127b

guide bevel

128a, 128b

clearance

129a, 129b

Side wall

130

operating section

131

operating surface

132

handle section

133

Second spring element

134

First ending

135

second ending

136

First spring element

137

outer surface

138

First ending

139

second ending

140

main section

200

director

300

Tool

bb

Actuating direction of actuating element

BL

Actuating direction release element

E

insertion direction

Q

Direction

Claims (13)

Connection arrangement (100) for connecting an electrical conductor (200), with - a housing (110), - a conductor connection space (111) formed in the housing, - a current bar (112) against which the conductor (200) to be connected, which is introduced into the conductor connection space (111), can be clamped, - a clamping spring (113) which has a clamping leg (115) which can be moved into a clamping position and into an open position, - An actuating element (116) by means of which the clamping leg (115) of the clamping spring (113) can be transferred from the clamping position to the open position, and - a release element (124), - wherein in the open position the actuating element (116) is positioned in such a way that the actuating element (116) is latched to the housing (110) in order to hold the clamping leg (115) in the open position, - wherein the latching between the housing (110) and the actuating element (116) can be released by means of the release element (124). Connection arrangement (100) according to Claim 1, characterized in that the release element (124) is guided parallel to the actuating element (116). Connection arrangement (100) according to Claim 1 or 2, characterized in that the release element (124) is arranged between the actuating element (116) and the conductor connection space (111). Connection arrangement (100) according to one of Claims 1 to 3, characterized in that the release element (124) has an opening (125) through which the clamping leg (115) of the clamping spring (113) protrudes. Connection arrangement (100) according to one of Claims 1 to 4, characterized in that the actuating element (116) has a latching edge (121) which cooperates with an undercut (123) formed on the housing (110) to form the latching. Connection arrangement (100) according to one of Claims 1 to 5, characterized in that the actuating element (116) has at least one guide bevel (127a, 127b) and the release element (124) has at least one guide bevel (126a, 126b), wherein for releasing the latching the at least one guide slope (126a, 126b) of the release element (124) slides along the at least one guide slope (127a, 127b) of the actuating element (116). Connection arrangement (100) according to one of Claims 1 to 6, characterized in that the release element (124) has at least one clearance (128a, 128b) into which the actuating element (116) is immersed in the open position. Connection arrangement (100) according to one of Claims 1 to 7, characterized in that the release element (124) has an actuating surface (131) which projects into the conductor connection space (111) and via which the release element (124) can be activated by means of the conductor (200 ) is operable. Connection arrangement (100) according to one of Claims 1 to 8, characterized in that the release element (124) has a handle section (132) for actuating the release element (124) manually or by means of a tool. Connection arrangement (100) according to one of Claims 1 to 9, characterized by a first spring element (136) which interacts with the actuating element (116). Connection arrangement (100) according to one of Claims 1 to 10, characterized by a second spring element (133) which interacts with the release element (124). Connection arrangement (100) according to one of Claims 1 to 11, characterized in that the release element (124) is designed in one part or in two parts. Electronic device with at least one connection arrangement (100) designed according to one of Claims 1 to 12.

Images