DE102010048715B4 - Self-locking push-in contact arrangement for a usable in a device housing module and module for this purpose - Google Patents

Abstract

Self-locking slide-in contact arrangement for a module (M) which can be inserted into a device housing, which comprises: • a module housing (MG) with pressure contacts (D) protruding through openings (Ö1) in the base plate (BP) and with as ground contacts through openings (Ö2) in the base plate ( BP) protruding spring contacts (F), • a basic circuit board (L) with several recesses (A1, A2, A3) and parallel to the base plate (BP) of the module housing (MG) and in the device housing of the device and • at least one on the floor (B) of the module housing (MG) arranged latching means such that when the module housing (MG) is pushed in, the pressure contacts (D) for establishing a device-side electrical connection contact contact areas on the base circuit board (L), the spring contacts (F) in first recesses (A1) in the basic circuit board (L) are guided and both the electrical ground connection and the mechanical connection between the module housing (MG) and the basic circuit card (L) nd the locking means snaps into a second recess (A2) in the base circuit board (L) when it reaches a stop. manufacture and the locking means ...

Description

The invention relates to a self-locking Einschubkontaktanordnung for insertable into a device housing module according to claim 1 and according to claim 7, a module for this purpose.

Slide-in contact devices for bays in equipment cabinets, equipment housing or equipment racks have long been known. For example, is from the DD-PS 146 137 a connection and locking device for device bays of telecommunications known, which are electrically connected via plug-in connections with the rack wiring, the device bays are inserted into rack layers. In order to provide a connecting and Verriegelvorvorichtung in which is already locked before making the electrical connector, the slot and during the manufacture of the electrical connector, the lock is not released, the connecting and locking device consists of two mutually movably connected levers, of which the first lever is guided as a spring-loaded locking lever defined in the insertion direction in a groove and the second lever is mounted as an operating lever to a fixed to the device drawer pivot. Specifically, the locking lever is rotatably mounted on a pin fixedly connected to the actuating lever and has a curved slot for receiving the bolt. A tension spring, which is attached to the insert and the locking lever, ensures a defined position of the locking lever and the actuating lever. This position is determined by a guide groove of an extruded part and a stop of the slot on the bolt. When inserting the insert into the frame, the insert is first pushed so far into the frame until the locking lever engages in the receiving device. Thereafter, the operating lever is manually moved to its first stop. The insert is pulled by the interaction of both levers in the frame and the plug connection is made. To release the connector without removing the drawer, the operating lever is moved from its position on the stop to a certain position, wherein the insert is moved by the interaction of the two levers by the size of Einschiebehubes counter to the direction of insertion. In this position of the slot work on the slot or on the frame are possible without removing the slot. To remove the drawer, the lock on the receiving device is released by moving the operating lever until it stops, and the drawer can be removed.

Furthermore, from the EP 1 610 605 A2 an electrical module with a laterally arranged on the module housing locking device, which prevents the unintentional release of an electrical connector between the inserted into an electrical device module. For this purpose, the locking device on a first part and a second part, which are each rotatably mounted about an axis. By a linear displacement movement of the first part for inserting the module, the second part is moved to a Verrieglungsposition and closed the electrical connector on the back of the module housing. Preferably, the first part is configured as a screw and the second part as arranged laterally on the module housing sprocket, which is rotated by turning the screw about its axis and engages the edge in a recess of a circuit board of the electrical device. Furthermore, the front plate of the electrical module on inwardly bent tabs which engage around the front edge of the circuit board as a stop in the final phase of the insertion movement. To unlock the screw is unscrewed again, so that when removing the module, the toothed disc is rotated back through the edge of the recess in the circuit board. The toothed disc can also be spring loaded (tension spring), so that the toothed disc turns back when unscrewing the screw back to the starting position.

Furthermore, from the US 6,549,424 B1 an insertable into an electrical device module with a laterally arranged pivotable lever, which has a pin on the outside. When pivoting the lever in the horizontal of the pin when inserting the module can be inserted in a slot as a backdrop in the side wall of the electrical device. By pivoting the lever in the vertical, the pin rolls on the backdrop, the module is inserted and the back electrical connector between the module and the electrical device is closed. Thereafter, the lever is secured by means of a screw in this position on the front panel of the module.

Furthermore, from the DE 10 2007 024896 B3 an arrangement for securing a drawer assembly in a built-in cage of a computer having a retaining rail with at least one contact surface for fixing the retaining rail in the mounting cage and at least one retaining pin for engaging in a lateral mounting opening of the drawer assembly, wherein the retaining rail by the at least one retaining pin laterally can be fixed to the withdrawable module. To provide a particularly simple design and easy to use holding device for slide assemblies, both vibrations as Also effectively absorbs shocks, at least a first opening is formed in the retaining rail and at least one pot-shaped vibration damper made of an elastic material is received by clamping in the first opening. At least one retaining pin is received by clamping in the vibration damper, wherein the vibration damper surrounds the retaining pin at least partially jacket-shaped. The jacket-shaped vibration damper prevents direct vibration transmission between the retaining pin and the retaining rail. The vibration damper has a circumferential on its outer side of the first groove, and the holding rail has in the region of the first opening at least a first latching lug which engages in the first circumferential groove of the vibration damper. Furthermore, the retaining pin has a circumferential on its outer side second groove, and the vibration damper has on its inner side at least a second latching lug which engages in the second circumferential groove of the retaining pin. By using circumferential grooves and locking lugs, the shrinkage damper can be fixed by locking with the retaining rail tool and adhesive-free. The first and second latching lugs are arranged offset by approximately 90 degrees relative to the axis of symmetry of the retaining pin. Due to the staggered arrangement of the first and second latching lug, the vibration damping is optimized by the vibration damper, since the first and second latching mechanism are mechanically decoupled from each other. Finally, at least one electrically conductive contact spring is arranged on the retaining rail, by which an electrical contact between the plug-in module and the installation cage can be produced. By using an electrically conductive contact spring, a secure ground connection between the plug-in module and the installation cage can also be produced when the plug-in module is mechanically and electrically decoupled from the installation cage by the damping element.

Finally, out of the DE 41 31 661 C1 a device for unlocking a resiliently biased locking element on the side of an electronic plug-in unit, which is connected in a rack inserted state via a connector system with this known. The latching element can be released in the direction of the pull-out movement of the plug-in unit. For this purpose, a pivotally mounted on the side of the plug-in unlocking lever is provided, which pushes the latching element against the spring force from a detent opening by its pivotal movement with a first lever portion and is brought with a second lever portion in a protruding from the front side plane of the plug-in unit position. To unlock the plug-in unit with only one lever movement and to solve the electrical connection between plug-in unit and rack evenly and gently, the first lever portion on a Axialnocken whose Axialhub is at least equal to the movement stroke of the locking element between its latching and unlocking and with the Locking element is engaged. Further, the first lever portion on a radial cam which is movable against a connected to the rack abutment and which has a cam lift, which is in a predetermined relationship to the contact path of the connector system. During the pivoting movement of the unlocking lever about its pivot axis, the axial cam presses the latching element against the spring force out of the latching opening of the module rack. Thereafter, the plug-in unit is released from the rack and can be pulled out of this. Furthermore, a metallic contact spring is provided on the outside of the plug-in unit, which is resiliently in contact with the metallic rack and which is conductively connected to a device held by the plug-in unit, whereby an electrically conductive connection is made between the device and the rack. This serves to dissipate undesired interference currents, sets a defined potential on the device and meets the requirements of electromagnetic compatibility (EMC) for electronic devices in a simple and reliable manner.

As the above appreciation of the prior art shows, the interfaces of plug-in contact devices for producing a device-side electrical connection are constructed as a plug connection. As a result of different form factors, assemblies and connectors usually a special housing construction of the base unit, the equipment cabinet or the equipment rack, in particular the installation of guide rails, and a matched housing construction of the module to be inserted is needed.

The invention has for its object to provide a self-locking Einschubkontaktanordnung for a module to be inserted into a device housing, which can be installed and disassembled without opening the device housing in the device.

• • ein Modulgehäuse mit durch Öffnungen der Bodenplatte ragende Druckkontakte und mit als Massekontakte durch Öffnungen der Bodenplatte ragende Federkontakte,
• • eine parallel zur Bodenplatte des Modulgehäuse und im Gerätegehäuse des Geräts befestigte Basisleiterkarte mit mehreren Aussparungen und
• • mindestens ein am Boden des Modulgehäuses angeordnetes Rastmittel,
• • derart, dass beim Einschieben des Modulgehäuses die Druckkontakte zum Herstellen einer geräteseitigen elektrischen Verbindung Kontaktflächen auf der Basisleiterkarte kontaktieren, die Federkontakte in ersten Aussparungen in der Basisleiterkarte geführt sind und sowohl die elektrische Masseverbindung als auch die mechanische Verbindung zwischen Modulgehäuse und Basisleiterkarte herstellen und das Rastmittel beim Erreichen eines Anschlags in einer zweiten Aussparung der Basisleiterkarte einrastet.

This object is achieved according to claim 1, by a self-locking Einschubkontaktanordnung for an insertable into a device housing module, which comprises:

• A module housing with pressure contacts projecting through openings of the base plate and with spring contacts projecting as ground contacts through openings of the base plate,
• • a multi-slot baseplate mounted parallel to the bottom of the module enclosure and inside the device housing
• At least one latching means arranged on the bottom of the module housing,
• In such a way that upon insertion of the module housing the pressure contacts for producing a device-side electrical connection contact surfaces on the base circuit board, the spring contacts are guided in first recesses in the base circuit board and both the electrical ground connection and the mechanical connection between the module housing and base card and produce the locking means engages when reaching a stop in a second recess of the base circuit board.

While in the prior art has always been trying to realize the electrical and mechanical connection between the module and device to be used by means of plug connection and guide rails, a completely new way with a self-locking is created in the Einschubkontaktanordnung invention, which causes no cost on the circuit board of the basic unit and To mount and dismantle without tools in the basic unit.

• • einem Modulgehäuse mit durch Öffnungen der Bodenplatte ragende Druckkontakte und mit als Massekontakte durch Öffnungen der Bodenplatte ragende Federkontakte und
• • mindestens ein am Boden des Modulgehäuses angeordnetes Rastmittel, derart gelöst, dass beim Einschieben des Modulgehäuses in ein Gerätegehäuse eines Geräts, welches eine parallel zur Bodenplatte des Modulgehäuse und eine im Gerätegehäuse des Geräts befestigte Basisleiterkarte mit mehreren Aussparungen aufweist, die Druckkontakte zum Herstellen einer geräteseitigen elektrischen Verbindung Kontaktflächen auf der Basisleiterkarte kontaktieren, die Federkontakte in ersten Aussparungen in der Basisleiterkarte geführt sind und sowohl die elektrische Masseverbindung als auch die mechanische Verbindung zwischen Modulgehäuse und Basisleiterkarte herstellen und das Rastmittel beim Erreichen eines Anschlags in einer zweiten Aussparung der Basisleiterkarte einrastet.

Furthermore, this object is, according to claim 7, by a module with:

• A module housing with pressure contacts projecting through openings of the base plate and with spring contacts projecting as ground contacts through openings of the base plate and
• • At least one arranged at the bottom of the module housing latching means, solved in such a way that when inserting the module housing in a device housing of a device which has a parallel to the bottom plate of the module housing and a mounted in the device housing of the device base card with a plurality of recesses, the pressure contacts for producing a device-side electrical connection contact surfaces on the base board contact, the spring contacts are guided in first recesses in the base circuit board and both the electrical ground connection and the mechanical connection between the module housing and base card produce and the latching means when reaching a stop in a second recess of the base card.

In a further development of the invention, according to claim 2, the bottom plate of the module housing on at least one survey, which is guided during insertion of the module housing in a third recess in the base circuit card.

This development of the invention has the advantage that when inserting the module, the leading spring contacts can be raised and then forcibly lowered by the weight of the module into the third recess in the base circuit board and there guided on further insertion.

In a preferred embodiment of the invention, according to claim 3, the spring contact as approximately parallel to the base circuit card extending S-contact configured, the end of the S-contact serves as an insertion bevel and the shaft of the S-contact as a clamping point for the contact surface of the base circuit card serves.

This embodiment of the invention has the advantage that when inserting the module on the printed circuit board underside of the base printed circuit board, a strong pressure is exerted, so that the module is firmly connected in its vertical axis with the base circuit board. The spring contacts compensate for tolerances in the thickness of the base card and at the same time serve for electrical ground connection between the module housing and base card.

Further advantages and details can be taken from the following description of a preferred embodiment of the invention with reference to the drawing. In the drawing shows:

1 in perspective view on the underside of a module according to the invention,

2 cut the module in side view 1 in the locked state,

3 cut the module in side view 1 in the unlatched state,

4 cut the module in side view 1 in detail in the locked state,

5 in plan view the bottom of the module after 1 and

6a in plan view the top of a base card and

6b in plan view, the underside of a base card according to the invention.

1 to 5 show a module M and 6a and 6b show a base circuit board L of a device according to the invention. In the context of the invention, the use of the self-locking Einschubkontaktanordnung invention in various technical fields - for example in telecommunications - done, even if subsequently the use of devices in automation technology such as controllers, terminals, drives, Identsysteme, EAs, which work independently or with each other or with a parent system are described. For networking, international standards define the protocol flow and physics of the network. Today, there are about 20 systems in the market, which are divided into master or slave function and historically into field bus and Ethernet technology. These network connections are complex and usually constructed separately as an independent module with its own processor of the application. With the same device interface, the (automation) device can be operated on different networks by replacing the (communication) module.

The commercially available communication modules are currently not standard and have different form factors, assemblies and connectors. As a rule, these communication modules require a special housing construction of the basic device and matched housing constructions of the respective communication module. In particular, in the case of the prior art exchangeable communication module, guide rails, a plug connector on a base circuit board of the device, and a special tool for mounting the module are required.

• • Das Modul M läst sich ohne Öffnen des Gehäuses im Gerät montieren und demontieren.
• • Zur Montage werden im Gerät keine zusätzlichen Komponenten wie Steckverbinder oder Führungsschienen benötigt.
• • Im Gehäuse des Geräts wird nur ein rechteckiger Ausschnitt und keine weiteren Führungsschienen oder Verriegelungen benötigt.
• • Die Montage erfolgt ausschließlich über Aussparungen in der Basisleiterkarte L im Grundgerät.
• • Die Signalübertragung benötigt keine Steckverbinder auf der Basisleiterkarte L im Grundgerät, sondern erfolgt über Kontaktflächen im Basismaterial der Leiterkarte.
• • Zur Montage bzw. Demontage werden keine Werkzeuge oder andere Hilfsmittel benötigt.
• • Ein nicht vorhandenes Modul M, z. B. als Option für eigenständigen oder vernetzten Betrieb, erzeugt keine Kosten im Grundgerät.

According to the invention, a communication module M is defined in its form factor, assembly and electrical connection to the (basic) device with the following features:

• • Module M can be mounted and dismounted in the device without opening the housing.
• • For mounting, no additional components such as connectors or guide rails are required in the device.
• • The housing of the device requires only a rectangular cutout and no additional guide rails or latches.
• • The mounting is carried out exclusively via recesses in the base circuit board L in the basic unit.
• • The signal transmission does not require any plug-in connectors on the basic circuit board L in the basic device, but takes place via contact surfaces in the base material of the printed circuit board.
• • No tools or other aids are required for assembly or disassembly.
• • A non-existent module M, z. B. as an option for stand-alone or networked operation, generates no cost in the basic unit.

In detail, the self-locking push-in contact arrangement according to the invention comprises a module housing MG with projecting through openings Ö1 of the bottom plate BP pressure contacts D and protruding through openings Ö2 of the bottom plate BP spring contacts F as ground contacts and a parallel to the bottom plate BP of the module housing MG and in the device housing of the device attached base circuit card L. with several recesses A1, A2, A3. Thus, according to the invention, the entire contacting of the signals and the mounting in the basic unit is effected solely and solely via contact surfaces on the printed circuit board L or in recesses A1, A2, A3 therein. The signal spring contacts D projecting through openings Ö1 in the base plate BP of the communication module M close the signal connection by pressure on contact surfaces on the printed circuit board top side L.

The strong PE spring contacts F ((Protective Earthing), which protrude through openings Ö2 in the bottom plate BP of the communication module M and the recesses A2 in the printed circuit board L of the base unit are thus so pronounced according to the invention that when inserting the communication module M also through openings O2 protrude in the printed circuit board L and exert strong pressure when inserting the communication module M on the printed circuit board underside, so that the module M is firmly connected in its vertical axis to the printed circuit board L. The spring contacts F compensate for tolerances in the thickness of the printed circuit board L and serve In particular, the spring contact F is designed as an approximately parallel to the base circuit card L extending S-contact, wherein the end of the S-contact serves as an insertion bevel and the shaft of the S-contact as a nip for the contact surface of the base board In another embodiment, the spring contact F is used as a fork contact and the contact surface of the base conductor L as a blade contact surface (upper. and underside of the base circuit board L, for example, both sides rectangular gold-plated copper surface) configured. For better contacting and centering of the contact connection, the blade contact surface of the base circuit board L can also be slotted or the blade contact surface of the base circuit board L can be configured as a profile piece. This can be achieved by a bulbous execution of the fork contact F increasing the spring and centering effect in the connection, d. h., That the two parts to be joined no longer move against each other in height after closing the connection. In addition, the separation force for a desired separation is higher (so that a locking means - see below - can also be carried out by the detent weaker). In the embodiment as a profile piece, z. B. by triangular or round webs, grooves or pyramidal attachments, the height and number of webs, etc., such that on the one hand a good contact (and possibly centering) is achieved, on the other hand, the friction occurring when disconnecting the connection is not so high that the separation is difficult.

Furthermore, according to the invention, at least one latching means arranged on the bottom B of the module housing MG is provided in such a way that the latching means reaches a second stop when a stop is reached Recess A2 of the base card L snaps into place. Thus, a pulling out of the communication module M is no longer possible and this is fixed in all its axes in a precisely defined position. In particular, the locking means consists of a spring-mounted plate P with slope or a plate P with resilient bevel and a slider S with a handle H. The slider S with handle H is approximately T-shaped in the embodiment shown in the drawing, wherein the handle H protrudes through an opening ÖFP in the front panel FP of the module housing MG. The transverse part of the T extends over a two-sided slot in the bottom plate BP within this and the longitudinal part of the T extends between two resilient plate parts P, which lead this front with the inner edge of the slope. Additionally or alternatively, the transverse part of the T can be performed.

When pulling out the handle H, the slider S first lifts the latching of the plate P in the recess A2 and is then against a stop AS (see 5 ) pulled on the module housing MG. Preferably, the handle H protrudes just so far out that it can be pulled out with two fingers - with little force. If the handle H pulled out so far that it can be held firmly with two fingers, the slider S can exert a force on the locking mechanism (spring plate or resilient bevel), so that this from the recess A2 in the circuit board L of the base unit is lifted out and the module M is unlocked. By further pulling on the handle H, the module M is pulled out of the device.

Preferably, the bottom plate BP of the module housing MG at least one elevation E, which is guided during insertion of the module housing MG in a third recess A3 in the base circuit card L. In particular, the elevation E is configured as a strip and the third recess A3 as a slot, wherein the module M in its horizontal axes with respect to. The insertion and insertion are exactly out and in the direction of insertion has a stop. In addition to the transverse guide of the module M, the strip E also serves as contact protection.

Furthermore, the module housing MG is configured on the side facing away from the base conductor L side as a heat sink K and the spring contacts F are in contact with the heat sink K. The heat sink K has webs and nubs to increase the surface. In particular, the dimpled height is reduced toward the rear end of the module so that the leading spring contacts F are initially formed over the front (on the front panel FP) recesses A1 (in FIG 6a and 6b be designed as indentation of the base circuit board L) can be lifted and slide on further insertion on the top of the base circuit board L until it by the weight of the module M in the illustrated embodiment, both rear recesses A1 (in 6a and 6b approximately L-shaped in the base circuit card L configured). In the final phase, either the web E runs against the edge of the rear recess A1 or the vertically extending central part (see 1 , Depth stop T) of the spring contact F runs against the edge of the front recess A1 as a stop.

• – keine Stecker auf der Leiterkarte L, sondern nur Kontaktflächen KD, KF im Kupfer der Leiterkarte L,
• – keine Führungsteile, sondern nur Aussparungen in der Leiterkarte L,
• – keine zusätzlichen Werkzeuge, sondern nur ein Rastmechanismus zur Montage und Demontage des Moduls und
• – keine Zusatzkosten auf der Leiterkarte L für die elektrische und mechanische Verbindung des Moduls M erforderlich.

The self-locking push-in contact arrangement according to the invention has the advantage that upon insertion of the module housing MG, the pressure contacts D for producing the device-side electrical connection contact surfaces KD (see 6a , rectangular, gold-plated copper surface) on the base conductor L contact, the spring contacts F are guided in the first recess A1 in the base circuit board L and both the electrical ground connection (contact surface KF, see 6b ) as well as the mechanical connection between the module housing MG and the base circuit card L produce and that the locking means engages upon reaching a stop in a second recess A2 of the base circuit board L. Accordingly,

• - no plugs on the printed circuit board L, but only contact surfaces KD, KF in the copper of the printed circuit board L,
• No guide parts, but only recesses in the printed circuit board L,
• - No additional tools, but only a locking mechanism for mounting and dismounting of the module and
• - No additional costs on the circuit board L required for the electrical and mechanical connection of the module M.

Thus, for example, when assembling a drive, the communication module M can be selected according to the present order and simply plugged into the drive without further assembly. Alternatively, this step can also be carried out by the machine builder when wiring the system. This makes it possible to avoid network-specific device variants in the production and in the warehouse of the drive manufacturer or to relocate them to OEM customers. Network plugs such as the nine-pin DSub connectors from PROFIBUS and CAN or the RJ45 sockets from Ethernet must have a solid PE connection to dissipate EMC interference, for which PE connections are provided in the drive via two separate spring contacts on the printed circuit board in the drive are. According to the invention, the spring contacts F are now designed so that they simultaneously serve as a spring element for holding the module. Preferably, four spring contacts F are inserted into the bottom of the module M and then exert stable pressure on the printed circuit board underside of the drive at four points. As a result, metal springs replace the plastic springs in the prior art and at the same time increase the contact pressure in the PE connection.

Demanding drive systems today operate synchronously with bus cycle times of less than 100 microseconds and up to 100 nanoseconds. Requirements on which the classic dual port memory of the communication module M comes to its limits, which is why PCI Express is set instead. This interface type, together with the two PHYs (physical interface) of a real-time Ethernet system, generates a typical power loss of about one watt, to which up to an additional watt may be added depending on the CPU, peripherals and frequency. In order to achieve the required operating temperature of 65 ° C, the upper housing part is realized as a heat sink K in black anodized aluminum die casting, alternatively for fieldbus systems with much less power loss, a cheaper plastic cover with ventilation slots LS (see 1 ) is used.

The invention is not limited to the illustrated and described embodiments, but also includes all the same in the context of the invention embodiments. In the context of the invention, a depth stop T can be arranged at the rear of the front panel FP. Furthermore, the invention has hitherto not been limited to the feature combination defined in patent claim 1, but may also be defined by any other combination of specific features of all individual features disclosed overall. This means that in principle virtually every single feature of patent claim 1 can be omitted or replaced by at least one individual feature disclosed elsewhere in the application.

Claims (7)

Self-locking push-in contact arrangement for a module (M) that can be inserted in a device housing, comprising: A module housing (MG) with pressure contacts (D) projecting through openings (Ö1) of the base plate (BP) and with spring contacts (F) projecting as ground contacts through openings (Ö2) of the base plate (BP), • a base PCB (L) with several slots (A1, A2, A3) and parallel to the bottom plate (BP) of the module housing (MG) and in the device housing of the unit At least one detent means arranged on the bottom (B) of the module housing (MG), in such a way that upon insertion of the module housing (MG) the pressure contacts (D) for contacting a device-side electrical connection make contact surfaces on the base circuit card (L), the spring contacts (F) are guided in first recesses (A1) in the base circuit card (L) and establish both the electrical ground connection and the mechanical connection between the module housing (MG) and the base circuit board (L) and the latching means engages on reaching a stop in a second recess (A2) of the base circuit board (L). and the latching means (R) when reaching a stop in a second recess (A2) of the base circuit board (L) engages. Slide-contact arrangement according to claim 1, characterized in that the bottom plate (BP) of the module housing (MG) has at least one elevation (E) which is guided during insertion of the module housing (MG) in a third recess (A3) in the base conductor card (L) , Slide-contact arrangement according to claim 1, characterized in that the spring contact (F) is designed as an approximately parallel to the base circuit card (L) extending S-contact, wherein the end of the S-contact serves as an insertion bevel and the shaft of the S-contact as a nip for the contact surface of the base board (L) is used. Slide-contact arrangement according to claim 1, characterized in that the latching means consists of a spring-mounted plate (P) with bevel or a plate (P) with resilient bevel and a slide (S) with a handle (H), which through an opening (ÖFP ) protrudes in the front panel (FP) of the module housing (MG) and that when pulling out the handle (H) of the slider (S) first the detent of the plate (P) in the recess (A2) picks up and then against a stop on the module housing ( MG) is pulled. Slide-contact arrangement according to claim 2, characterized in that the elevation (E) is designed as a bar and the third recess (A3) as a slot. Slide-contact arrangement according to claim 1, characterized in that the module housing (MG) on the side facing away from the base conductor (L) side designed as a heat sink (K) and that the spring contacts (F) with the heat sink (K) are in contact. Module (M) comprising: a module housing (MG) with pressure contacts (D) projecting through openings (Ö1) of the bottom plate (BP) and with spring contacts (F) projecting as ground contacts through openings (Ö2) of the bottom plate (BP) and at least a latching means arranged on the bottom (B) of the module housing (MG), such that when inserting the module housing (MG) in a device housing of a device having a parallel to the bottom plate (BP) of the module housing (MG) and in the device housing of the device mounted base circuit card (L) with a plurality of recesses (A1, A2, A3) in that the pressure contacts (D) for contacting a device-side electrical connection make contact surfaces on the base circuit board (L), the spring contacts (F) are guided in first recesses (A1) in the base circuit board (L) and both the electrical ground connection and the mechanical connection between module housing (MG) and base card (L) and the latching means when reaching a stop in a second recess (A2) of the base card (L) engages.

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