EP3855571B1 - Terminal and electronic device - Google Patents

Description

The invention relates to a connection terminal for connecting an electrical conductor, with a housing, a current bar arranged in the housing, a clamping spring arranged in the housing for clamping the conductor to be connected against the current bar in a conductor connection space formed between the current bar and the clamping spring, and an actuating element , which is slidably mounted on the housing, wherein a clamping leg of the clamping spring can be actuated to transfer the clamping leg from a clamping position to an open position by means of the actuating element, whereby, viewed along an actuation direction of the actuating element, below a section of the current bar against which the conductor passes through Clamping spring is clamped, a guide element for supporting the actuating element and / or a guide element for supporting the clamping spring is provided.

Such a connection terminal is, for example, from CN 202 564 566 U and the US 2018/166802 A1 known. The actuating element of such a connection terminal therefore serves, on the one hand, to actuate the clamping spring in order to release the conductor connection space for inserting the conductor to be connected. On the other hand, it can be provided that the actuating element delimits the conductor connection space at least in sections. For both functions, it is important that the actuating element reliably assumes its intended position both in the clamping position and in the open position.

If, for example, the actuating element is partially deformed or deflected from its intended position due to excessive force in the open position, an undesirable gap can arise between the housing and the actuating element, into which a conductor end of the conductor to be connected can be accidentally inserted, so that it In the clamping position, there may not be an electrically conductive contact between the current bar and the electrical conductor to be connected.

Furthermore, such a deformation or deflection of the actuating element can cause the actuating element to slide off the clamping leg of the clamping spring, so that the actuating element is no longer in engagement with the clamping leg of the clamping spring. In addition to possible damage to the clamping spring and/or the actuating element, the case can occur here that the clamping leg is already in place before Insertion of the electrical conductor to be connected snaps back into the clamping position, so that the conductor can no longer be inserted into the conductor connection space.

The invention is therefore based on the object of providing a connecting terminal and an electronic device which enable reliable actuation of the clamping leg by the actuating element.

The object is achieved according to the invention with the features of the independent claims. Appropriate refinements and advantageous developments of the invention are specified in the subclaims.

The connection terminal according to the invention is characterized in that the guide element for supporting the actuating element has a first guide surface, which effects a support of the actuating element against transverse displacement along a first direction, and the guide element for supporting the actuating element has a second guide surface, which provides a support of the actuating element against transverse displacement along a second direction that is different from the first direction.

The guide element for supporting the actuating element ensures that the actuating element is not deformed or deflected during the transfer from the clamping position to the open position, and vice versa, and remains in reliable contact with the clamping leg of the clamping spring. The guide element for supporting the clamping spring ensures that the clamping spring is not deformed or deflected, particularly during actuation of the clamping spring by means of the actuating element, and remains reliably in the desired position within the housing. The connection terminal can have the guide element for supporting the actuating element and the guide element for supporting the clamping spring. But it is also possible for the connection terminal to have only one of the two guide elements.

It can be provided that the actuating element limits the conductor connection space at least in sections, in particular at least on two sides. In this case, the guide element additionally supports the actuating element ensures that no gaps formed by a deformation or deflection of the actuating element can arise between the actuating element and the housing, which could lead to incorrect assembly of the electrical conductor to be connected.

The guide element for supporting the actuating element and/or guide element for supporting the clamping spring can be an integral part of the housing. In this way, the respective guide element can be integrated cost-effectively into the shape of the housing.

For example, it can be provided that the guide element for supporting the actuating element and/or the guide element for supporting the clamping spring and/or the housing can have an electrically insulating plastic or can consist of an electrically insulating plastic.

The guide element for supporting the actuating element and/or the guide element for supporting the clamping spring can, for example, be part of a side wall of the housing of the connecting terminal. Consequently, the guide element can be compactly integrated into the housing of the connection terminal.

Alternatively, it can be provided that the guide element for supporting the actuating element and/or the guide element for supporting the clamping spring is provided as a separate component and is connected to the housing of the connecting terminal. The guide element for supporting the actuating element and/or the guide element for supporting the clamping spring can have been encapsulated with a plastic of the housing, so that there is a positive connection between the guide element for supporting the actuating element and/or the guide element for supporting the clamping spring and the housing of the connecting terminal can be formed. It can be provided that the guide element for supporting the actuating element and/or the guide element for supporting the clamping spring is detachably connected to the housing of the connecting terminal.

The guide element for supporting the actuating element can be a web which surrounds a section of the actuating element. Accordingly, deflection of the actuating element can be positively prevented by the web.

The guide element for supporting the clamping spring can also be a web which laterally supports a section of a holding leg of the clamping spring. The guide element for supporting the clamping spring can prevent lateral movement, in particular of the holding leg of the clamping spring, when the clamping leg of the clamping spring is transferred into the clamping position and into the open position. Even in the clamped state of a conductor, a secure fit of the clamping spring can be ensured by means of the guide element and thus tilting of the clamping spring can be prevented.

In particular, it can be provided that the guide element for supporting the actuating element can be part of a linear guide, which only enables a purely translational movement of the actuating element from a first position to a second position, so that the linear guide can deprive the actuating element of three rotational and two translational degrees of freedom . Such a linear guide can, for example, be specified in a purely form-fitting manner by a geometry of the housing of the connecting terminal in which the actuating element is accommodated. For example, the housing can have a shaft along which the actuating element can be moved, the guide element for supporting the actuating element can serve as additional support against deflection or deformation of the actuating element.

According to the invention, the guide element for supporting the actuating element has a first guide surface which supports the actuating element against transverse displacement along a first direction. According to the invention, the guide element for supporting the actuating element has a second guide surface, which supports the actuating element against transverse displacement along a second direction that is different from the first direction. If we are talking about a transverse displacement in the present case, this is in particular a displacement transverse to the actuation direction of the actuating element, along which the actuating element carries out a translational movement in order to move the clamping leg from its clamping position into its open position, and vice versa.

The first guide surface can be a flat surface. The second guide surface can be a flat surface.

The first direction can be oriented orthogonally to the actuation direction of the actuating element. The second direction can be oriented orthogonally to the actuation direction of the actuating element. Alternatively or additionally, the first direction can be oriented orthogonally to the second direction.

The actuating element can have at least one actuating arm, wherein the at least one actuating arm can delimit the conductor connection space transversely to an insertion direction of the conductor, wherein the actuating arm can rest on the clamping leg of the clamping spring with an actuating surface in the open position of the clamping spring. Depending on the installation position of the connection terminal, it can be provided that the actuating arm can rest with its clamping surface on the clamping leg of the clamping spring even in the clamping position.

The guide element for supporting the actuating element can be designed to prevent deflection of the actuating arm transversely to the actuating direction of the actuating element and transversely to the insertion direction of the conductor to be connected. It can be provided that at least one guide surface of the guide element is provided to support the actuating element, along which the actuating element slides when the clamping leg is actuated, the surface normal of which can be oriented essentially perpendicular to the actuation direction and/or to the insertion direction.

At least one actuating arm can have at least one guide web, which can be arranged on a side of the actuating arm facing away from the conductor connection space and/or can slide along the guide element to support the actuating element when the actuating element is actuated. The guide web can be used for the defined contact of the actuating arm on the guide element.

It can be provided that the actuating arm has two guide webs spaced apart from one another, which are set up to rest on the guide element to support the actuating element and/or a section of the housing. In particular, the guide webs can be extended essentially parallel to one another. A further web or several further webs can be arranged between the guide webs in order to achieve structural stiffening of the actuating arm.

At least one actuation arm can have a stop section for limiting a stroke path of the actuation element. In particular, it can be provided that a sliding surface, along which a section of the clamping leg slides on the actuating arm when the clamping leg is actuated, is provided at a recess in the actuating arm, which is at least partially delimited by the stop section. In particular, the stop section can be a hook-shaped end section of the actuating arm.

The current bar can penetrate the actuating element, wherein the section of the current bar against which the conductor is clamped by the clamping spring can be arranged between the at least one actuating arm and a second actuating arm of the actuating element. In this way, the current bar together with the actuating element can be compactly integrated into the housing of the connection terminal. The current bar can have recesses against which the actuating arms of the actuating element can rest, so that the current bar can also provide guidance for the actuating element.

The actuation element can have an asymmetrical shape, with the shape of the at least one actuation arm different from the shape of the second actuation arm.

It can be provided that the at least one actuating arm has a length measured along the actuating direction of the actuating element that is less than a length of the second actuating arm measured along the actuating direction of the actuating element. For example, the second actuation arm can have a stop in order to specify a defined maximum stroke length, while the at least one actuation arm has no such stop and is therefore shaped set back relative to the second actuation arm.

Furthermore, it can be provided that the at least one actuating arm has, for example, the aforementioned guide webs, while the second actuating arm has no such guide webs.

The clamping leg of the clamping spring can have at least one skid which is in contact with the actuating element during the transfer of the clamping leg from the clamping position to the open position.

The clamping spring can have a second skid which is in contact with the actuating element during the transfer of the clamping leg from the clamping position to the open position.

Such a skid can be assigned an actuating surface or pressure surface of an actuating arm of the actuating element, along which the skid slides during the transfer of the clamping leg from the clamping position into the open position.

The skid and/or the pressure surface can be designed to be curved at least in sections in order to promote smooth sliding.

A skid can be a freely projecting end section of the clamping leg, which is arranged adjacent to or adjacent to a freely projecting contact section of the clamping leg, the contact section being intended to rest on the electrical conductor to be connected.

The connection terminal can be a terminal block that can be snapped onto a mounting rail.

According to the invention, an electronic device is also specified with one or more connection terminals, the connection terminals being designed and further developed as described above.

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

Fig. 1a

eine schematische Darstellung einer Anschlussklemme gemäß der Erfindung in einer Klemmstellung in einer perspektivischen Ansicht,

Fig. 1b

eine schematische Darstellung der Anschlussklemme aus Fig. 1a in einer Seitenansicht und in einem Schnitt entlang der Schnittebene A-A,

Fig. 1c

eine schematische Darstellung der Anschlussklemme aus Fig. 1a in einer Offenstellung in einer perspektivischen Ansicht,

Fig. 1d

eine schematische Darstellung der Anschlussklemme aus Fig. 1c in einer Seitenansicht,

Fig. 1e

eine schematische Darstellung der Anschlussklemme aus Fig. 1d in einem Schnitt entlang der Schnittebene B-B,

Fig. 1f

eine schematische Darstellung der Anschlussklemme aus Fig. 1d in einem Schnitt entlang der Schnittebene C-C,

Fig. 2

eine schematische Darstellung eines Betätigungselements der Anschlussklemme aus Fig. 1a in einer perspektivischen Ansicht,

Fig. 3

eine schematische Darstellung der Klemmfeder der Anschlussklemme aus Fig. 1a in einer perspektivischen Ansicht,

Fig. 4

eine schematische Darstellung des Strombalkens der Anschlussklemme aus Fig. 1a in einer perspektivischen Ansicht,

Fig. 5

eine schematische Darstellung des Betätigungselements aus Fig. 2, der Klemmfeder aus Fig. 3 und des Strombalkens aus Fig. 4 in einer perspektivischen Ansicht,

Fig. 6

eine schematische Darstellung eines Gehäuses der Anschlussklemme aus Fig. 1a in einer perspektivischen Ansicht, und

Fig. 7

eine schematische Darstellung einer Anschlussklemme gemäß einer weiteren Ausgestaltung der Erfindung.

Show it

Fig. 1a

a schematic representation of a connection terminal according to the invention in a clamping position in a perspective view,

Fig. 1b

a schematic representation of the connection terminal Fig. 1a in a side view and in a section along the section plane AA,

Fig. 1c

a schematic representation of the connection terminal Fig. 1a in an open position in a perspective view,

Fig. 1d

a schematic representation of the connection terminal Fig. 1c in a side view,

Fig. 1e

a schematic representation of the connection terminal Fig. 1d in a section along the section plane BB,

Fig. 1f

a schematic representation of the connection terminal Fig. 1d in a section along the section plane CC,

Fig. 2

a schematic representation of an actuating element of the connection terminal Fig. 1a in a perspective view,

Fig. 3

a schematic representation of the clamping spring of the connection terminal Fig. 1a in a perspective view,

Fig. 4

a schematic representation of the current bar of the connection terminal Fig. 1a in a perspective view,

Fig. 5

a schematic representation of the actuating element Fig. 2 , the clamping spring Fig. 3 and the current bar Fig. 4 in a perspective view,

Fig. 6

a schematic representation of a housing of the connection terminal Fig. 1a in a perspective view, and

Fig. 7

a schematic representation of a connection terminal according to a further embodiment of the invention.

Fig. 1a shows a connection terminal 100 for connecting an electrical conductor 200. Such an electrical conductor 200 is shown schematically in the sectional view AA Fig. 1b indicated.

The connection terminal 100 according to Fig. 1a has a housing 110. A current bar 120 is arranged in the housing 110. A clamping spring 130 is also arranged in the housing 110. The clamping spring 130 serves to clamp the conductor 200 to be connected against the current bar 120.

A conductor connection space 140 is formed between the current bar 120 and the clamping spring 130, in the area of which the conductor 200 to be connected is clamped against the current bar 120.

The connection terminal 100 has an actuating element 150 which is slidably mounted on the housing 110.

The clamping spring 130 has a clamping leg 131. The actuating element 150 is designed to move the clamping leg 131 from a clamping position ( Fig. 1a , Fig. 1b ) into an open position ( Fig. 1c , Fig. 1d ). In other words, the clamping leg 131 of the clamping spring 130 can be actuated by means of the actuating element 150 to transfer the clamping leg 131 from the clamping position to the open position.

Viewed along an actuation direction H of the actuating element 150, a guide element 111 for supporting the actuating element 150 is provided below a section 121 of the current bar 120, against which the conductor 200 is clamped by the clamping spring 130.

The guide element 111 is an integral part of the housing 110.

As in average AA Fig. 1b As can be seen, the guide element 111 in this case is a web 111 which surrounds a section 151 of the actuating element 150.

The guide element 111 has a first guide surface 112, which supports the actuating element 150 against transverse displacement relative to the actuating direction H of the actuating element 150 along a first direction R1. The Guide element 111 has a second guide surface 113, which supports the actuating element 150 against transverse displacement to the actuating direction H along a second direction R2, which is different from the first direction R1. Accordingly, the web 111 positively counteracts a displacement of the actuating element 150 transversely to the actuating direction H.

The first direction R1 is oriented orthogonally to the actuation direction H of the actuating element 150. The second direction R2 is oriented orthogonally to the actuation direction H of the actuating element 150. The first direction R1 is oriented orthogonally to the second direction R2.

The actuating element 150 has an actuating arm 152, the actuating arm 152 delimiting the conductor connection space 140 transversely to an insertion direction E of the conductor 200 and the actuating arm 152 with an actuating surface 154 resting against the clamping leg 131 of the clamping spring 130 in the open position of the clamping spring 130.

The actuating arm 152 has a guide web 156, which is arranged on a side of the actuating arm 152 facing away from the conductor connection space 140 and slides along the guide element 111 when the actuating element 150 is actuated. The actuating arm 152 has two further webs 157, 158 for stiffening and guiding the actuating element 150.

The actuating element 150 has a second actuating arm 153, which has a stop section 159 for limiting a stroke path of the actuating element 150 along the actuating direction H.

The actuator 150 has an asymmetrical shape, with the shape of the actuator arm 152 different from the shape of the second actuator arm 153. In the present case, the actuating arm 152 is shorter than the actuating arm 153 when viewed along the actuating direction H, since the actuating arm 153 has the stop 159.

The actuating element 150 has a further actuating surface 160 in the area of the second actuating arm 153, as in Fig. 2 to recognize. The actuation surface 154 of the actuation arm 152 and the actuation surface 160 of the second actuation arm 153 are each curved in shape. A recess 161 is formed between the stop 159 and the actuation surface 160 of the second actuation arm 153.

Fig. 3 shows an isolated representation of the clamping spring 130.

The clamping leg 131 of the clamping spring 130 has a first skid 132 which is in contact with the actuating element 150 during the transfer of the clamping leg 131 from the clamping position to the open position.

The clamping leg 131 of the clamping spring 130 has a second skid 133 which is in contact with the actuating element 150 during the transfer of the clamping leg 131 from the clamping position to the open position.

The first skid 132 is assigned the actuation surface 154 or pressure surface 154 of the actuating arm 152 of the actuating element 150, along which the skid 132 slides during the transfer of the clamping leg 131 from the clamping position into the open position, and vice versa.

The skid 132 and the pressure surface 154 are at least partially arcuate or curved in order to promote smooth sliding.

The second skid 133 is assigned the actuating surface 160 or pressure surface 160 of the actuating arm 153 of the actuating element 150, along which the skid 133 slides during the transfer of the clamping leg 131 from the clamping position to the open position, and vice versa.

The skid 133 and the pressure surface 160 are at least partially arcuate or curved in order to promote smooth sliding.

The skids 132, 133 are each freely projecting end sections of the clamping leg 131. The skids 132, 133 are arranged adjacent to or adjacent to a freely projecting contact section 134 of the clamping leg 131, the contact section 134 being intended to rest on the electrical conductor 200 to be connected .

The clamping spring 130 has recesses 137, 138 on a support leg 136 connected to the clamping leg 131 via an arc section 135 in order to create a free space for receiving the skids 132, 133 in the open position.

Fig. 4 shows an isolated representation of the current bar 120. The current bar 120 has recesses 122, 123, against which the actuating arms 152, 153 of the actuating element 150 can rest, so that the current bar 120 also provides guidance for the actuating element 150.

How Fig. 5 As can be seen, the current bar 120 penetrates the actuating element 150, with the section 121 of the current bar 120 being arranged between the actuating arm 152 and the second actuating arm 153 of the actuating element 50.

Fig. 6 shows an isolated representation of the housing 110. The housing 110 in the present case has an insulating plastic.

The housing 110 has a shaft 114 along which the actuating element 150 can be moved. The shaft 114 has a recess 115 into which a web 162 of the actuating element 150 engages in order to ensure correct positioning.

The guide element 111 and the shaft 114 form a linear guide for the actuating element 150, which only enables a purely translational movement of the actuating element 152 along the actuating direction H from a first position ( Fig. 1a , Fig. 1b ) into a second position ( Fig. 1a , Fig. 1b ), so that the linear guide deprives the actuating element 150 of three rotational and two translational degrees of freedom. The guide element 111 serves in particular as additional support against deflection or deformation of the actuating arm 152 in order to prevent the actuating arm 152 from sliding off the skid 132.

The housing 110 has a web 116 for receiving the clamping spring 130. The housing has a recess to accommodate the power bar 120.

To clamp a conductor 200 between the clamping spring 130 and the current bar 120, the actuating element 150 is first made from the in Fig. 1a position shown translationally along the actuation direction H into the in Fig. 1c position shown emotional. The clamping spring 130 is compressed in this way, with the clamping leg 131 being brought closer to the support leg 136.

During this lifting movement, the skids 132, 133 slide along the actuating surfaces 154, 160 of the actuating arms 152, 153 of the actuating element 150.

The actuating arm 152 is guided with its guide web 156 along the guide element 111 of the housing 110. The guide element 111 prevents the actuating arm 152 from being deflected in a direction R2 transverse to the actuating direction H and remaining reliably in engagement with the skid 132 of the clamping spring 130. The guide element 111 therefore enables the actuation arm 152 to be guided in the actuation direction H in an area below the section 121 of the current bar 120.

As soon as the clamping leg 131 of the clamping spring 130 is in the Figures 1c and 1d is in the open position shown, the conductor connection space 140 is released for inserting the conductor 200 along the insertion direction E into the conductor connection space 140 and the conductor 200 can be moved between the clamping leg 131 and the current bar 120.

Subsequently, the actuating element 150 is released and spring-loaded as a result of the tension of the clamping spring 130 by the clamping leg 131 moved against the actuation direction H until the clamping leg 131 with its contact section 134 rests on the conductor 200 inserted into the conductor connection space 140 and the conductor 200 rests against the section 121 of the current bar 120 presses. In this state, the conductor 200 is clamped between the clamping spring 130 and the current bar 120, with a spring force of the clamping spring 130 acting on the conductor 200 holding the conductor 200 in position.

In order to release the conductor 200 from the connection terminal 100 again, the actuating element 150 can be moved again in the actuating direction H in order to lift the contact section 134 of the clamping spring 130 from the conductor 200 and release it.

Moving the actuating element 150 against the spring force of the clamping spring 130 can, for example, be done manually with a tool, such as a Screwdriver or something similar. Alternatively, it can be provided that the actuating element 150 is actuated mechanically in order to enable automated assembly of the conductor 200.

Fig. 7 shows a further embodiment of a connection terminal 100, which is in addition to that in Fig. 1 to 6 shown embodiment of the connecting terminal 100 has a guide element 162 for supporting the clamping spring 130. By means of this guide element 162, lateral tilting or slipping of the clamping spring 130 out of the housing 110 can be prevented.

Here, the guide element 162 for supporting the clamping spring 130, like the guide element 111 for supporting the actuating element 150, is integral and thus formed in one piece with the housing 110. The guide element 162 is formed on a side wall 164 of the housing 110. The guide element 162 thus forms an extension of the side wall 164. The guide element 111 for supporting the actuating element 150 and the guide element 162 for supporting the clamping spring 130 are therefore both formed on the side wall 164 of the housing 110. The guide element 111 for supporting the actuating element 150 also forms an extension of the side wall 164.

The guide element 162 is designed in the form of a web. The guide element 162 here extends in the direction of the conductor connection space 140 in the opposite direction to the actuation direction H of the actuation element 150. The guide element 162 for supporting the clamping spring 130 thus extends starting from the side wall 164 of the housing 110 in the direction of the conductor connection space 140 transversely to the direction of extension of the guide element 111 for supporting the actuating element 150 starting from the side wall 164 of the housing.

The guide element 111 for supporting the actuating element 150 and/or the guide element 162 for supporting the clamping spring 130 can each also be formed by two webs extending parallel to one another, not shown here, so that the actuating element 150 and/or the clamping spring 130 is supported on both sides can be done. The two webs of the guide element 111 and/or the two webs of the guide element 162 are then formed on two side walls 164 of the housing 110 that extend parallel to one another. A sideways tilting of the Actuating element 150 and/or the clamping spring can thus be prevented on two sides.

The guide element 162 extends in the direction of the conductor connection space 140 in such a way that the guide element 162 laterally overlaps the holding leg 163 of the clamping spring 130. The guide element 162 thus forms a lateral support surface for the holding leg 163 of the clamping spring 130. The guide element 162 is guided past a longitudinal side edge surface 165 of the holding leg 163.

The guide element 162 for supporting the clamping spring 130, like the guide element 111, is formed, viewed along the actuation direction H of the actuating element 150, below the section 121 of the current bar 120, against which the conductor 200 is clamped by the clamping spring 130.

Reference symbol list

100

Connection terminal

110

Housing

111

Leadership element

112

first guide surface

113

second guide surface

114

shaft

115

recess

116

web

120

Current bar

121

Section

122

recess

123

recess

130

Clamping spring

131

clamping leg

132

skid

133

skid

134

Contact section

135

Arch section

136

Support leg

137

recess

138

recess

140

Conductor connection compartment

150

Actuator

151

Section

152

Actuation arm

153

Actuation arm

154

Actuation surface/pressure surface

156

Guide bridge

157

web

158

web

159

attack

160

Actuation surface/pressure surface

161

recess

162

Leadership element

163

holding leg

164

Side wall

165

Long side edge surface

200

Director

E

Insertion direction

H

Direction of operation

R1

Direction

R2

Direction

Claims (10)

1. Connection terminal (100) for connecting an electrical conductor (200), having a housing (110), a current bar (120) arranged in the housing (110), a clamping spring (130) arranged in the housing (110) for clamping the conductor (200) to be connected against the current bar (120) in a conductor connection space (140) formed between the current bar (120) and the clamping spring (130), and an actuating element (150) which is mounted so as to be displaceable in the housing (110), wherein a clamping leg (131) of the clamping spring (130) can be actuated by means of the actuating element (150) to transfer the clamping leg (131) from a clamping position into an open position, wherein, as viewed along an actuating direction (H) of the actuating element (150), a guide element (111) for supporting the actuating element (150) is provided and/or a guide element (162) for supporting the clamping spring (130) is provided below a portion (121) of the current bar (120) against which the conductor (200) is clamped by the clamping spring (130), characterized in that the guide element (111) for supporting the actuating element (150) has a first guide surface (112) which supports the actuating element (150) against a transverse displacement along a first direction (R1) and the guide element (111) for supporting the actuating element (150) has a second guide surface (113) which supports the actuating element (150) against a transverse displacement along a second direction (R2) which is different from the first direction (R1).
2. Connection terminal (100) according to Claim 1, characterized in that the guide element (111) for supporting the actuating element (150) and/or the guide element (162) for supporting the clamping spring (130) are/is an integral constituent part of the housing (110).
3. Connection terminal (100) according to Claim 1 or 2, characterized in that the guide element (111) for supporting the actuating element (150) is a web which engages around a portion (151) of the actuating element (151), and/or in that the guide element (162) for supporting the clamping spring (130) is a web which laterally supports a portion of a retaining leg (163) of the clamping spring (130) .
4. Connection terminal (100) according to one of Claims 1 to 3, characterized in that the first direction (R1) is oriented orthogonally to the actuating direction (H) of the actuating element (150) and the second direction (R2) is oriented orthogonally to the actuating direction (H) of the actuating element (150) and/or in that the first direction (R1) is oriented orthogonally to the second direction (R2).
5. Connection terminal (100) according to one of Claims 1 to 4, characterized in that the actuating element (150) has at least one actuating arm (152, 153), wherein the at least one actuating arm delimits the conductor connection space (140) transversely with respect to an insertion direction (E) of the conductor (200), wherein the actuating arm (152, 153) bears with an actuating surface (154, 160) against the clamping leg (131) of the clamping spring (130) in the open position of the clamping spring (130).
6. Connection terminal according to Claim 5, characterized in that at least one actuating arm (152) has at least one guide web (156) which is arranged on a side of the actuating arm (152) facing away from the conductor connection space (140) and/or, when actuating the actuating element (150), slides along the guide element (111) for supporting the actuating element (150).
7. Connection terminal according to Claim 5 or Claim 6, characterized in that at least one actuating arm (153) has a stop portion (159) for limiting a stroke travel of the actuating element (150).
8. Connection terminal according to either of Claims 6 and 7, characterized in that the current bar (120) passes through the actuating element (150), wherein the portion (121) of the current bar (120) is arranged between the at least one actuating arm (152) and a second actuating arm (153) of the actuating element (150).
9. Connection terminal according to Claim 8, characterized in that the actuating element (150) has an asymmetrical shape, wherein the shape of the at least one actuating arm (152) differs from the shape of the second actuating arm (153).
10. Electronic device having one or more connection terminals (100) which are configured according to one of Claims 1 to 9.

Images