DE102011105036B4 - Connector for mobile measurement module system - Google Patents

Abstract

The invention relates to a connector (300, 320) for a first mobile measuring technology module (400, 402) for coupling to a similar second connector (300, 320) of a second mobile measuring technology module (400, 402), wherein the connector ( 300, 320) comprises a double spring contact (200, 610). The double spring contact (200; 610) has an outer contact pin (204; 309,309 '; 604) with a contact head (220) for contacting an opposing contact pin (260; 632) of the second connector (300,320) and an inner one Contact pin (216; 306, 306 ') with a contact head (222) for contacting a contact point in the first mobile measurement technology module (402). The double spring contact further includes an outer spring member (206) which, when cocked, exerts a compressive force on the outer contact pin (204; 309, 309 '; 604) which acts in the direction of the opposite contact pin of the second connector (300,320). and an inner spring element (218) which, in the tensioned state, exerts a compressive force on the inner contact pin (216) which acts in the direction of the contact point in the first mobile measuring technology module (400, 402).

Description

FIELD OF THE INVENTION

The present invention relates to the field of mobile measurement technology, in particular to a connector for the signal transmission between mobile measurement technology modules in a motor vehicle, a mobile measurement technology module with such a connector, and a corresponding module system for mobile measurement technology.

BACKGROUND OF THE INVENTION

In mobile measurement technology, in particular vehicle measurement technology, the compact and flexible integration of electronic units in vehicles plays an important role. As miniaturization progresses, a variety of modular electronic units, hereafter referred to as mobile instrumentation modules, are to be integrated into a vehicle that enables a wide range of analysis, detection or diagnostic concepts.

Vehicle measurement modules are typically connected to sensors that are specified for the particular analysis, acquisition or diagnostic task. The modules collect data collected by the sensors and store them in integrated data stores, if necessary, or store them in buffers for further processing or transmission. The modules further include microprocessors for acquiring, storing and processing the accumulated data, and provide interfaces for providing the collected data and / or the resulting analysis results or diagnostic results to the outside world. The interfaces allow z. B. a connection of the modules to a vehicle provided in the data bus system (eg CAN bus). Furthermore, the interfaces also allow a connection of the modules with each other or to one in the vehicle, z. B. in the trunk of a motor vehicle integrated central computing or storage unit. Usually, the connection of the modules to the vehicle bus system and the coupling of the modules with each other by means of cable connections.

Due to the large number of analysis, acquisition and diagnostic tasks required today, equipping a vehicle with the required complex measurement technology - in particular the cabling of the modules among each other - is a complex task. With the large number of required modules and cable connections, it is often not easy to keep track of the wiring and detect any faults. In addition, the placement of the modules and the wiring in the available, often scarce space is a problem - especially when one or more measurement modules near the sensors must be positioned in a confined space.

From the publication DE 100 42 377 A1 a modular arrangement of electronic subsystems in motor vehicles is known in which a provided for receiving modules of the subsystems module carrier is set up so that it can accommodate different, different and different modules according to design, size and configuration, the connection between the module carrier and the modules is is made by a deliberately partitioned plug-in system. Of the plug-in system of the module carrier pluggable modules, a main power supply module that receives the vehicle electrical system voltage, and a main network interface module that interfaces with existing vehicle buses, be firmly plugged into the connector system, while the other optional modules are easily detachable plugged into the connector system. The in the published patent application DE 100 42 377 A1 described use of a module carrier with a partitioned connector system, however, has the disadvantage of lack of flexibility. Module carrier and plug-in system have a fixed scope and a defined number of module slots or slots. Such module carriers with partitioned plug-in system are therefore inefficient, especially in equipping a vehicle with measuring technology.

The publication DE 10 2004 033 369 A1 relates to electronic control units, in particular a door control device for motor vehicles with a controller arranged on a motherboard for controlling standard functions of a vehicle component, in particular a window lift function. The controller further includes a first connector connected to the controller. An expansion module with at least one further printed circuit board is provided, on which electrical components for controlling additional functions of the vehicle component are arranged. The expansion module is plugged onto the first connector and has a second connector with which the control unit together with the expansion module can be connected to the vehicle bus system. In contrast to the second connector, the first connector also has a number of additional connections which allow serial communication between the controller and the expansion module. On the board of the expansion module is an integrated circuit that operates as a slave input / output unit that only executes commands and contains no additional logic so that the expansion module can only execute commands. This connector of the publication DE 10 2004 033 369 A1 for a controller with expansion card is not for a measuring module system suitable because it relates to a base module (or carrier module) with expansion module and thus it does not allow to connect several similar measurement technology modules symmetrical with each other.

For the realization of a connector contacting elements are required. From the state of the art so-called spring contacts are known in this regard. Spring contacts are contacting elements used for testing printed circuit boards, electronic assemblies, components such as connectors and other components in the electronics industry. In the case of spring contacts, the contact is not produced by plugging a pin into a socket, as is the case with plug connectors, but by probing by means of a spring-supported pin. 1 shows a spring contact 100 , which is a guide tube 104 , which is also called pin sleeve or housing, a compression spring 106 and a piston serving as a contact pin 102 , includes. The piston 102 Can run freely in the longitudinal direction of a certain spring travel. The front tip of the piston or contact pin serves as a probe. Usually, the compression spring of a spring contact is biased. It requires a certain initial force to push the spring contact from its zero position to a component.

From the U.S. Patent No. 4,289,367 For example, an electrical test probe is known for electrically coupling a first contact pad disposed opposite a first side of a planar test fixture with a second contact pad disposed opposite the opposite side of the test fixture to test circuits on a printed circuit board. A first tubular cylinder is firmly inserted in the test fixture. A second tubular cylinder is inserted in the first tubular cylinder and a piston is inserted in the second tubular cylinder. The electrical test probe has - unlike the above-mentioned simple spring contact pin - two biasing devices with cylindrical helical springs. The electrical test probe is used to test integrated circuit board. Such contacting elements with Doppelfern have hitherto been used only in the testing technique, not for the realization of the contact elements of a connector.

The publication DE 30 22 394 A1 relates to a contact block for measurement and test purposes, in particular for testing electronic components, with a guided in a sleeve contact piston, which is pressed by a coil spring arranged in the sleeve against the one sleeve end.

From the publication JP 2004-257 831 A a contact module for contacting an electrode of a semiconductor integrated circuit is known, wherein the contact module is equipped with a first pin consisting of a sleeve and a first contact piece at one end of the sleeve. The contact block also includes a second pin consisting of an axially movable shaft portion received from the other end of the sleeve and consisting of a second contact piece extending from the sleeve toward the other end. The contact block further includes a first spring which drives the first contact piece, and a second spring, which is arranged in the sleeve and drives the first and second contact piece.

From the U.S. Patent No. 7,057,403 B2 a microcontact probe consisting of two pistons is known, wherein the pistons each comprise a needle element and are adapted so that the one piston contact a printed circuit board and the other piston a contact target.

The U.S. Patent No. 6,464,511 B1 shows a housing and a lower cover, which are attached to each other and include through holes, are inserted in the probe pins. Each probe pin consists of a tube which includes a stop flange, wherein a movable piston is received in the tube so that a part of the movable piston is urged by a coil spring into a narrowed first end portion of the tube. Further, the probe pin includes a solid piston at a second end portion of the tube. The probe pin is urged by a second coil spring so that a tip end of the fixed piston protrudes beyond the outer surface of the lower cover and a tip end of the movable piston protrudes beyond the outer surface of the housing.

The object of the invention is to provide a plug connection for mobile measurement technology modules in a motor vehicle, which achieves a compact, space-saving and yet flexible coupling of measurement technology modules in a motor vehicle and enables signal transmission between the modules.

SUMMARY OF THE INVENTION

According to a first aspect, the present invention relates to a connector for a first mobile instrumentation module for coupling to a similar second connector of a second mobile instrumentation module, the connector comprising a double spring contact having an outer contact pin with a contact head for contacting a opposite Contact pin of the second connector and an inner contact pin having a contact head for contacting a contact point in the first mobile instrumentation module. The double spring contact further comprises an outer spring element which exerts a compressive force on the outer contact pin in the tensioned state, which acts in the direction of the opposite contact pin of the second connector, and an inner spring element which exerts a compressive force on the inner contact pin in the tensioned state, in Direction of the contact point in the first mobile measurement technology module acts on.

According to a further aspect, the present invention relates to a mobile measurement technology module with a connector according to the invention, in which the inner contact pin of the double spring contact does not contact the contact point in the mobile measurement technology module in the unplugged state of the connector.

According to yet another aspect, the present invention relates to a modular system for mobile measurement technology, comprising at least two mobile measurement technology modules according to the invention, wherein the connectors of the two mobile measurement technology modules are arranged on the housings of the mobile measurement technology modules such that when coupled the two mobile measurement technology modules by means of the connecting pins and guide holes, the two connectors are opposite and automatically coupled together.

Further aspects and features of the present invention will become apparent from the dependent claims, the accompanying drawings and the following description of preferred embodiments.

BRIEF DESCRIPTION OF THE DRAWING

Embodiments of the invention will now be described by way of example and with reference to the accompanying drawings, in which:

1 shows a spring contact from the prior art;

2A shows an embodiment of a double spring contact in a sectional view in a first, unloaded condition;

2 B an embodiment of a double spring contact in a sectional view in a second partially loaded state shows;

2C shows an embodiment of a double spring contact in a sectional view in a third, fully loaded condition;

3A an embodiment of a connector in a side view shows;

3B shows an embodiment of a connector in a plan view;

4 shows an embodiment of two mobile measurement modules with respective connectors and a locking mechanism;

5 an embodiment for a locking plate of the locking mechanism shows;

6A an embodiment of a cable connection plate for the connection of a mobile instrumentation module with one or more ribbon cables in a plan view;

6B an embodiment of two ribbon cables, each leading two wires, in a cross-sectional view shows;

7 shows an embodiment of a mobile instrumentation module with a cable connection plate to be connected therewith in a side view;

8A shows an embodiment of a cable connection plate with contact pins for contacting a power supply line and a CAN line; and

8B the embodiment of the cable connection plate of 8A when plugged in a section shows.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

In the embodiments described here, connectors with double spring contacts are described, which serve to establish an electrical connection between two mobile measurement technology modules. In addition, exemplary embodiments of mobile measurement technology modules with such connectors are shown, and a module system is described which uses these mobile measurement technology modules. Before the embodiments are described in detail with reference to the accompanying drawings, however, only some of the terms used are generally explained.

The exemplary embodiments describe plug connectors for signal transmission between mobile measurement technology modules. Conventional connectors are often based on a male part with outwardly facing contact pins (plug) and a female part with inwardly facing contact openings (socket) and have in this regard an asymmetrical structure. But there are also connectors with plug-in elements of both sexes. The connectors described here have contact pins as plug-in elements. However, these contact pins are not designed to cooperate with contact openings of a female connector. Rather, the connector described here is based on a symmetrical contacting of the plug-in elements (or contact pins) of two similar connectors.

The term measuring technology module is understood in the following to mean an electronic or optoelectronic unit which comprises electronic and / or optoelectronic components which are accommodated in a module housing, typically arranged on a printed circuit board. The connector described here serves as an interface for transmitting signals between mobile measurement technology modules, or for coupling a module to a vehicle bus. Signal transmission here essentially means the transmission of data, such. B. measurement results and control commands. In addition, the connector can also be used to power the module with operating voltage or the like.

The signal transmission from connector to connector can be done by means of electronic signals on electrical conductors, by optical means using optical fibers, or by means of the principle of electromagnetic, inductive or capacitive coupling.

The connector uses as a contacting element one or more double spring contacts. Unlike a conventional spring contact, a double spring contact has two spring elements. The operating principle of the double spring contact is based on two movably mounted contact pins. An outer contact pin has a contact head for contacting an opposite contact pin of a second connector. An inner contact pin has a contact head for contacting a contact point in the vehicle measurement module, z. B. a conductor on a printed circuit board in the case of electrical data transmission or an optical waveguide carrier in the case of optical data transmission. Under contact head is understood here the end of the contact pin, which establishes the actual contact. As a rule, the contact head is an integral part of the contact pin. But it is also conceivable to carry out the contact head as a separate component, for. B. to be able to replace worn ends. Spiral springs can be used as spring elements - but alternatively also enclosed gas cushions or the like.

The following also describes mobile measuring technology modules which have connectors with double spring contacts as contacting elements. Such modules can be used in motor vehicles or even in ships.

The operating principle of the double spring contacts makes it possible that the inner pins of the connector in the unplugged, so unloaded state of the connector are not in contact with the associated contact points in the mobile measurement technology module. This is achieved by positioning the contact points in the mobile measuring technology module such that in the zero position of the double spring contacts their inner contact pins do not contact the respective contact points. Accidental contact of the outer pins with z. B. live objects (cables, touch by hand, accidental contact with the vehicle body mass, etc.) do not lead in the case of electrical connectors therefore not to an involuntary voltage transfer to the circuit board of a measurement module.

The following also describes a modular system of mobile measuring technology modules, each of which uses connectors with double spring contacts as contacting elements. The modular system is characterized by the fact that the mobile measuring technology modules can be easily coupled together in the manner of a plug-in system. For this purpose, for. B. used fasteners that allow mating the modules. When plugged in, these connecting elements are locked, resulting in a secure cohesion of the modules. The lock can by means of appropriate unlocking, such. B. an unlocking quickly be solved again. Since the connectors enable wireless signal transmission, the mobile measurement technology modules and their connectors can be set up in such a way that the module's connectors are automatically coupled with one another when mechanically coupling two modules.

The connectors described here thus enable a wireless connection of the mobile measuring technology modules with each other.

Alternatively, it is also possible to use a connector described herein in a connector which is attached to the end of a cable, or the connector with a cable connection plate for a cable, for. As a ribbon cable, to allow a decentralized placement of the mobile instrumentation module, or to connect remote modules with a ribbon cable or the like.

The connector described here can also be used in a cable connection plate for contacting a measurement technology module with a cable. The cable connection plate to Connecting the cable to the measuring module in this case has the connector with double spring contacts, which cooperates, for example, with a similar connector of the instrumentation module. Furthermore, the cable connection plate has a cable receiving portion for receiving the cable to be connected. Contact means, z. B. electrical connection lines connect the contact pins of the connector of the cable connection plate with wires of the cable to be connected. The contact means may further comprise needle contacts or the like, which are adapted to penetrate at any point in the cable to be connected and to contact wires of the cable to be connected.

In the following, the embodiments for connectors, mobile module with such connector and corresponding module systems will now be described in more detail with reference to the accompanying drawings.

The 2A . 2 B and 2C show a schematic representation of the principle of action of a double spring contact in three different stress levels, unloaded ( 2a ), partially loaded ( 2 B ) and fully loaded ( 2C ).

2A shows the double spring contact 200 in the unloaded state, ie in a connector (not shown) of a first electronic module in the unplugged state. The double spring contact 200 is located above a circuit board 250 of the first module (not shown) and serves for the electrical connection of a conductor track of this line plate 250 with the contact pin 260 an opposite connector (not shown) of a second electronic module. The double spring contact 200 consists of a substantially cylindrical outer sleeve 202 in which an outer contact pin 204 and an outer coil spring 206 are stored. The outer contact pin 206 can be in the sleeve 204 linear in the direction of the axis A of the double spring contact 200 move. The outer contact pin 204 located inside the outer coil spring 206 and has a flange at its upper end 208 on, to which the outer coil spring 206 from below strikes. The outer coil spring 206 is due to a movement of the outer contact pin 204 in the direction of the spring axis on the board 250 to (in 2A down) under compressive stress. The sleeve 202 has an opening at its lower, platinum-side end 210 on, through which the outer contact pin 204 during a movement in the direction of the board 250 can pass through. The arrangement of the outer contact pin 204 and the outer coil spring 206 can be done so that in the unloaded state of the flange 208 with its upper side on an upper end piece 212 the sleeve 202 strikes. The outer coil spring 206 may be biased such that in the unloaded state of the double spring contact 200 ) the flange 208 the outer contact pin 204 slightly against the upper end piece 212 the sleeve 202 is pressed.

The outer contact pin 204 is cylindrical and has a cavity in its interior 214 for supporting a second, inner contact pin 216 on. The inner contact pin 216 is - as well as the outer contact pin 204 - Movably mounted so that it can move in the axial direction A. The inner contact pin 216 is itself hollow and takes in its interior an inner spiral spring 218 on, which is when pushing in the inner contact pin 216 in the outer contact pin 204 compressed while this movement opposes a compressive stress. The outer contact pin 204 has on the inside at its lower end a projection 223 on that with a corresponding stop 221 of the inner contact pin 216 cooperates such that a complete sliding out of the inner contact pin 216 from the outer contact pin 204 prevented. The inner spiral spring 218 may be designed to be slightly biased when the inner contact pin 216 on the outer contact pin 204 strikes.

The upper end of the outer contact pin 204 forms an outer contact head ( 220 ) for contacting the contact pin 260 an opposite connector. The lower end of the inner contact pin 216 forms an inner contact head 222 for contacting the printed circuit board 202 , The contact heads 220 ; 222 Depending on the field of application and the materials used, they can have different shapes (pointed, round, etc.).

2A shows the double spring contact 200 in unloaded condition, ie in the unmated condition. The outer contact pin 204 of the connector touches the contact pin 260 not the opposite connector. In this unloaded state contacted the double spring contact 200 or its inner contact pin the circuit board 250 Not. 2A shows in this regard only the operating principle of the double spring contact. Other components such as connector housing and the like, which ensure that the double spring contact 200 at a distance from the printed circuit board 250 are held in 2A Not shown.

The connector is closed by bringing the opposing connectors together. Here comes the contact pin 260 the opposite connector with the outer contact pin 204 of the double spring contact 200 in contact and it becomes a pressing force on the outer contact pin 204 exercised in the direction of the printed circuit board 202 acts. This pressure force acts on the spring force of the outer coil spring 206 counteracts and causes, as far as it exceeds their biasing force, a movement of the outer contact pin 204 in the direction of the circuit board 250 , Due to the bias of the outer coil spring 206 It requires a certain initial force to the outer contact pin 204 from his in 2A shown zero position (unloaded state) to move.

2 B shows the double spring contact 200 in partially loaded condition. Under the pressure of the opposite contact pin 260 has the outer contact pin 204 in the direction of the circuit board 250 emotional. The inner contact pin 216 and the inner coil spring 218 are carried along, ie they change their relative position to the outer contact pin 204 Not. The contact head still touches 222 of the inner contact pin 216 not the circuit board, leaving the inner contact pin 216 and the inner coil spring 218 - apart from their bias - continue to be unloaded. A conductive connection to the circuit board 250 is not yet manufactured in this partially loaded state.

2C shows the double spring contact 200 in fully loaded condition. The plug connection is completely inserted. By the progressive movement of the outer contact pin 204 towards the board, is the inner contact pin 216 finally with his contact head 222 in contact with the circuit board 250 come, causing a pressure on the inner contact pin 216 and its coil spring 218 has built up. This pressure causes the inner contact pin 216 in the outer contact pin 204 pushes in and the inner spiral spring 218 brings under compressive stress. In the inserted state of the plug-in connection, the inner contact pin is pressed by this compressive stress 216 or the contact head 222 against the circuit board 250 pressed, creating a secure electrical contact between circuit board 250 arises. Likewise, the compressive stress causes the outer coil spring 206 in the plugged state of the connector, that the outer contact pin 204 against the contact pin 260 the opposite connector is pressed and thus the electrical connection of these pins is secured.

As materials for the pins and the probes good electrical conductors are used, for. B. beryllium copper. Alternatively, the contact pins can also be made of steel, especially with pointed head arms, which require increased mechanical stability. The coil springs can z. B. made of spring steel wire, stainless steel or beryllium copper.

The contact forces exerted by the double spring contact can advantageously amount to about 2-4 Newton in the inserted state.

The 3A and 3B show an embodiment of a connector 300 for an electronic measuring module in a side view and in a plan view. The connector comprises a plurality of double spring contacts as contacting elements, as described above with reference to the 2A . 2 B respectively. 2C have been described. The double spring contacts are located in a connector housing 302 . 304 that consists of an inner housing part 302 and an outer housing part 304 exists and is in 3A and 3B not completely visible. The inner housing part 302 is designed to work on a circuit board 308 (in 3A dashed lines shown) to be plugged. It has on the circuit board side holes, through which the inner pins 306 . 306 ' , ... the double spring contacts can pass through to corresponding tracks 310 . 310 ' , ... on the circuit board 308 to contact. The outer housing part 304 is designed to be a second connector 320 (in 3A shown in dashed lines) of a second electronic module. It accordingly has holes ( 3B ), through which the outer pins 308 . 308 ' , ... the double spring contacts can pass to corresponding pins of the second connector 320 to contact.

In the supervision of the 3B are the outer pins 309 . 309 ' , ... the double spring contacts seen through the outer housing part 304 pass. At the four corners, the inner housing part 302 more holes 314 for receiving screws (not shown), by means of which the plug housing on the circuit board 308 ( 3A ) can be attached. Alternatively, the connector housing 302 . 304 also by means of other plug or clip connections on the circuit board 308 be attached.

In 4 are a first 400 and a second one 402 mobile measuring module shown in plan, each on its longitudinal sides two of the connectors described above 404 and 406 respectively. 408 and 410 exhibit. The second module 402 also has two connecting pins on one of its longitudinal sides 412 on, which are intended, in appropriate leadership holes 418 (shown in phantom) of the first module 400 intervene to effect a fixed connection of the modules with each other. The first module 400 points on the long side with the guide holes 418 a module cover 417 on, under which a Entriegelungsblech 420 is mounted so movable that it by pulling on a handle 422 can be moved in the direction of B The module cover 417 is by means of fastening screws (not shown) to the housing of the module 400 attached.

The unlocking plate is in 5 shown in a top view. It essentially has a frame structure. At its front end is a handle 502 trained, with the z. B. manually a tensile force in the direction B on the Entriegelungsblech 500 can be exercised. On the back side of the release plate 500 the frame structure is curved inward. At the apex of the arched section 504 beats the Entriegelungsblech 500 on the module housing (not shown). Pull on the handle 502 causes a movement of the Entriegelungsblechs in direction B. The abutting module housing on the curved portion 504 comes under bending stress and exerts a force on the Entriegelungsblech 500 off, the traction on the handle 502 counteracts, by pulling the handle 502 so can the Entrieglungsblech 500 a short distance in the direction of B to be moved. When the tension on the handle decreases 502 moves the Entriegelungsblech 500 independently back to its zero position. The Entriegelungsblech has long holes in its Länggseiten 508 on, through which the fastening screws of the module cover 417 ( 4 ) pass through. At the four corners of the Entrieglungsblechs 500 There are four holes in keyhole shape 506 ie with a narrow radius on the side that faces the handle 502 points and with a larger radius on that side, in the direction of the domed section 504 has. The holes in keyhole shape 506 communicate with the connection pins 412 ( 4 ). The connecting pins 412 have a corresponding groove, in which the Entriegelungsblechs 500 at the location of the holes in keyhole shape 506 get in touch. When plugging the first module 400 with the second module 402 grip the pins in the guide holes 418 and press with increasing penetration depth the Entriegelungsblech 500 in direction B. As the penetration depth increases, the grooves of the pins communicate 412 with the holes in keyhole shape 506 , so that the unlocking plate by the restoring force of the curved portion 504 is pushed back in the direction of its zero position and the connection of the first module 400 with the second module 402 locks. The engaged connection can be made by pulling the handle 422 respectively. 502 and simultaneously disconnecting the two modules 400 and 402 be solved again. By this locking mechanism is a firm connection of the two modules 400 and 402 reached each other.

By locking the two modules 400 and 402 will also be the two connectors 404 and 408 pressed against each other and the double spring contacts are according to the sequence of 2A . 2 B and 2C from the unloaded state ( 2A ) about the partially loaded state ( 2 B ) in the fully loaded condition ( 2C ) brought. As a result, a wireless electrically conductive connection between the outer pins of the connector 404 of the first module 400 with the outer pins of the connector 408 of the second module 402 realized. In particular, the inner contact pins of the connector 404 and 408 against the tracks on the circuit boards of the respective modules 404 and 408 pressed. An electrical connection with the respective circuit boards comes according to the explanations to the 2A . 2 B and 2C So only when plugged in the connector 404 and 408 conditions. By the pressure force of the double spring contacts both a secure electrical connection of the inner contact pins is achieved with the circuit boards, as well as a secure electrical connection of the outer pins of the two connectors 404 and 408 among themselves.

6A shows a cable connection plate 600 for connecting a mobile instrumentation module, as in 4 shown with one or more ribbon cables 602a . 602b , The cable connection plate 600 is flat, parallelepiped-shaped and comprises at one top a center connector there 604 with double spring contacts according to the invention 610 , two eccentric grooves (in 6 not to be seen; 703a and 703b in 7 ) for receiving two ribbon cables 602a . 602b and four connecting pins 612 , each near the corners of the cable connection plate 600 are arranged. In the grooves runs the ribbon cable 602a . 602b , In the in 6A the embodiment shown, the ribbon cable consists of a first sub-cable 602a and a second, separated therefrom sub-cable 602b , The first subcable 602a leads, as in the cross-sectional view of 6B shown, for. B. the power supply, so z. B. a Masseader (GND), and a supply voltage wire (+12 V). The second ribbon cable (eg a CAN cable) transports data and includes, for example, B. two data wires (CAN-H, CAN-L). The division into two separate sub-cables, as shown in this embodiment, is not mandatory. Alternatively, only a ribbon cable can be used and there are other vein assignments possible, for. B. 8 or 16 data wires, shielding, ground, multiple supply voltages or the like. In 6A is the outer housing part of the connector 604 to see that the outer housing part 304 of the connector 300 out 3A equivalent. Accordingly, the outer pins of the double spring contacts 610 to see which the outer pins 204 of the double spring contact of the 2 correspond. Are the ribbon cables 602a and 602b in the slots provided for this purpose, their cores are +12 V, GND, CAN-L and CAN-H via in the cable connection plate 600 running connecting lines 606 ( 806a -D in 8th ) with associated contact pins of the connector 604 connected (see also 8th and corresponding description below).

7 shows a side view of a cable connection plate 704 in interaction with a measuring technology module 700 , The measuring technology module 700 corresponds to the measuring technology module 400 of the 4 , The connector 706 is designed to be the connector 714 of the measuring technology module 700 to contact if cable connection plate 704 and metrology module 700 - as indicated by the lateral double arrows in 7 indicated - merged. When merging the cable connection plate 704 with the measuring technology module 700 be the two ribbon cables 702a and 702b in the grooves provided for this purpose 703a and 703b trapped. In the grooves are four needle contact tips 708 arranged so that these in the ribbon cable 702a and 702b prick and contact the wires + 12V, GND, CAN-L, CAN-H, if the ribbon cable 702a and 702b into the grooves 703a and 703b be pressed (see also 8B and corresponding description below). Will the cable connection plate 704 on the measuring technology module 700 stuck, grab the connecting pins 712 into the corresponding pilot holes (shown in phantom) of the module 700 in order to effect a firm connection of the cable connection plate with the module. The double spring contacts of the connector contact 706 the cable connection plate the double spring contacts of the connector 714 of the measuring technology module 700 To make an electrically conductive connection between the wires of the ribbon cable 702a . 702b and the double spring contacts of the connector 714 of the measuring technology module 700 manufacture.

8A shows the cable connection plate 704 of the 7 in an illustration, in the inside of the cable connection plate extending electrical lines 806a -D can be seen. The electrical wires 806a -D connect the double spring contacts with the needle contacts 808 , in turn, the wires # 12 V, GND, CAN-L and CAN-H of the ribbon label 802a and 802b to contact.

8B shows the two ribbon cables 802a and 802b in the clamped state, in which the tips of the needle contacts 808 Contact the wires 12 V, GND, CAN-L and CAN-H in the ribbon cables. Contacting by means of needle contacts is a possible technique, the ribbon cable quickly and without soldering, cutting and stripping (LSA technology, eg insulation displacement terminal) with the electrical connection cables 806a -D to connect. Will the cable connection plate 800 removed from the measuring module, is a clamped ribbon cable 802 . 802b freed. The needle contacts pull back out of the ribbon cable. The sleeves of ribbon cables are usually made of flexible materials from which the needle contacts almost reversibly remove without the cable sleeve is significantly damaged by the penetration of the needles. Thus, a measurement technology module can be quickly connected by means of the cable connection plate according to the invention at any point to a cable and also easily removed.

A ribbon cable with cable connection plates according to the invention at its ends acts, for example, as a cable extension, in order to electrically interconnect measuring technology modules arranged at a distance from one another. With a cable connection plate according to the invention, for example, a measurement technology module can also be connected to a bus system and / or to a power supply line

The cable connection plate according to the invention is designed so that it can be plugged onto a mobile measurement technology module to connect this with a ribbon cable.

Claims (9)

Connector ( 300 . 320 ) for a first mobile measuring technology module ( 400 . 402 ) for coupling to a similar second connector ( 300 . 320 ) of a second mobile measuring technology module ( 400 . 402 ), wherein the connector ( 300 . 320 ) at least one double spring contact ( 200 ; 610 ), comprising: an outer contact pin ( 204 ; 309 . 309 '; 604 ) with a convex contact head ( 220 ) for contacting a similar contact head of an opposing outer contact pin ( 260 ; 632 ) of the second connector ( 300 . 320 ); an inner contact pin ( 216 ; 306 . 306 ' ) with a contact head ( 222 ) for contacting a contact point in the first mobile measuring technology module ( 400 . 402 ); an outer spring element ( 206 ), which in the tensioned state, a pressure force on the outer contact pin ( 204 ; 309 . 309 '; 604 ) exerted in the direction of the opposite contact pin of the second connector ( 300 . 320 ) acts; and an inner spring element ( 218 ), which in the tensioned state, a pressure force on the inner contact pin ( 216 ) in the direction of the contact point in the first mobile measuring technology module ( 400 . 402 ) acts. Connector according to claim 1, wherein the double spring contact ( 200 ) is used for coupling electrical conductors, wherein the outer contact pin ( 204 ) and the inner contact pin ( 216 ) are electrically conductive and the contact head ( 222 ) of the inner contact pin ( 216 ) for contacting a contact point on a printed circuit board ( 250 ) of the first mobile measuring technology module ( 400 . 402 ) is provided. Mobile Measurement Module ( 400 . 402 ) with a connector ( 300 ) according to one of the preceding claims, in which in the unplugged state of the connector ( 300 ) the inner contact pin ( 216 ; 306 . 306 ' ) of the double spring contact the contact point in the mobile instrumentation module ( 400 . 402 ) not contacted. A mobile measurement module according to claim 3, further comprising connection pins ( 412 ), which are designed to fit into corresponding guide holes ( 418 ) of a second mobile measuring technology module ( 400 . 402 ) intervene. Mobile instrumentation module according to claim 4, further comprising a Entriegelungsblech ( 500 ), which is displaceable under a module cover ( 417 ) and with connecting pins ( 412 ) of the second mobile measuring technology module ( 400 . 402 ) such that when plugged in a locked connection of the mobile instrumentation module ( 400 . 402 ) with the second mobile measuring technology module ( 400 . 402 ) caused by displacement of the Entriegelungsblechs ( 500 ) can be solved. Modular system for mobile measuring technology, with at least two mobile measuring technology modules ( 400 . 402 ) according to one of claims 4 or 5, wherein the connectors of the two mobile measurement technology modules on the housings of the mobile measurement technology modules ( 400 . 402 ) are arranged so that when coupling the two mobile measurement technology modules ( 400 . 402 ) by means of the connecting pins ( 412 ) and guide holes ( 418 ) the two connectors ( 300 . 320 ) and automatically coupled with each other. Use of the modular system for mobile measurement technology according to claim 6 in a motor vehicle. Cable connection plate ( 704 ) for connecting a cable ( 702a . 702b ) to a mobile measuring technology module ( 700 ), whereby the cable connection plate ( 704 ) comprises: a connector ( 706 ) according to one of claims 1 or 2 for connecting the cable connection plate to the mobile measuring technology module ( 700 ); a cable receiving section ( 703a . 703b ) for receiving the cable to be connected ( 702a . 702b ); Contact agent ( 708 ; 808 . 806a . 806b . 806c . 806d ) for the electrical connection of pins of the connector with wires (+12 V, GND, CAN-L, CAN-H) of the cable to be connected ( 702a . 702b ) A cable connection plate according to claim 8, wherein the contact means comprise needle contacts ( 708 . 808 ) adapted to be connected to a cable ( 702a . 702b . 802a . 802b ) and wires (+12 V, GND, CAN-L, CAN-H) of the cable to be connected ( 702a . 702b . 802a . 802b ) to contact.

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