DE9211238U1 - Sensor cable - Google Patents

Description

6445/+II/bu

data precision Computer GmbH
Cronenberger Str. 296, 5600 Wuppertal 1

Sensor cable

The present invention relates to a novel sensor cable for connecting a sensor that detects a physical measurement value, in particular an NTC resistor, to a component that is to be controlled or regulated depending on the physical measurement value, in particular to a temperature-controlled fan motor.

It is known to install a fan inside the respective case to ventilate computer cases and computer power supplies. Temperature-controlled fans are increasingly being used, the speed of which is varied depending on the temperature prevailing in the area of a main board (motherboard). It is also often desirable to replace conventional, uncontrolled fans with such temperature-controlled fans. For this purpose, in addition to the new fan, whose motor has three connecting wires, two for the "normal" power supply and one for speed control, a temperature sensor must also be installed. This installation has so far been very complicated and time-consuming, because on the one hand a connecting cable must be connected to the sensor, and this connecting cable must then be connected to

the fan. The power supply must also be connected accordingly. This requires a lot of soldering work, and the respective soldering points must then be insulated, usually with shrink tubing. An additional problem here is that the distance between the fan and the location of the sensor can vary greatly from device to device, so that the sensor cable, for which a standard stranded cable is usually used, must always be individually made up, or - if the length is sufficient for all possible applications - in some cases, when its length is actually too long for the device in question, it must be wound up in a suitable way and secured in the device, e.g. with a cable tie, if further shortening is to be avoided.

The present invention is based on the object of eliminating the problems described and, to this end, of creating a possibility of being able to connect the required measurement sensor in a particularly simple manner and with only a short expenditure of time, and in particular also independently of the distance between the sensor and the component to be connected when assembling a component to be controlled as a function of a specific physical measurement value, in particular a temperature-controlled fan.

According to the invention, this is now achieved by a new type of sensor cable, which consists of a spiral cable with at least two wires that is electrically connected to the sensor at one end and has a connector device using insulation displacement and/or crimping technology at the other end.

This is a pre-assembled sensor cable which is already electrically - and therefore also mechanically, practically "in one piece" - connected to the sensor, so that no connection work is required at this point. The connector device arranged at the other end advantageously enables the connecting wires of the component to be connected to be connected particularly easily and quickly, as the design using the insulation displacement technology known per se or the crimping technology known per se means that complex soldering work can be avoided here too. The connection of a power supply is then also advantageously carried out via the connector device of the sensor cable according to the invention, preferably via a connector part designed using insulation displacement technology. Due to the design according to the invention, it is then also possible to replace one of the components at any time in a simple manner, as the connector parts of the connector device only need to be removed and re-inserted. By using a spiral cable according to the invention, the sensor cable according to the invention can advantageously be prefabricated with only a very specific length, which is then sufficient for all possible applications, whereby - through an "elastic length variability" of the spiral cable - different lengths can nevertheless be bridged without the cable having to be wound up and fastened or even shortened if it is too long.

Further advantageous design features of the invention are contained in the subclaims and the following description.

The invention will now be explained in more detail using preferred embodiments shown in the accompanying drawings.

Fig. 1 shows a sensor cable according to the invention in a simplified, schematic view with additional representation of a fan motor and a power supply,

Fig. 2 is an enlarged, more detailed and partially sectioned view of a first embodiment of the connector device according to the invention, i.e. area II in Fig. 1,

Fig. 3 shows an enlarged cross-section through the sensor cable along the line III-III in Fig. 1 in the area of an additional resistance element connected to the spiral cable,

Fig. 4 is a plan view of a second embodiment of the connector device, alternative to Fig. 1 and 2 (area II in Fig. 1) and

Fig. 5 is a view of the connector device in the direction of arrow V according to Fig. 4 without the connector parts connected to the intended cables.

In the different figures, identical parts are always provided with the same reference symbols.

According to Fig. 1, a sensor cable 1 according to the invention consists of a spiral cable 2 with at least two flexible

stranded wires 4, 5 (see also Fig. 2), a sensor 6 electrically connected to the spiral cable 2 at one end and a plug connector device 8 electrically connected to the spiral cable 2 at the other end. The sensor 6 is used to detect a specific physical measurement variable; for the preferred application of the invention, the sensor 6 is preferably designed as a temperature-dependent resistor, in particular as an NTC resistor.

As can be seen in particular from Fig. 2, the plug connector device 8 consists of a first insulation displacement plug connector part 10 that is electrically connected to the connecting wires 4, 5 of the spiral cable 2, a second insulation displacement plug connector part 14 that can be electrically connected to a connecting cable 12 (see Fig. 1) of a component to be connected and controlled depending on the sensor 6, here a fan motor M, and preferably a third insulation displacement plug connector part 18 that can be electrically connected to a power supply cable 16 of a computer power supply N (Fig. 1). The first plug connector part 10 and the third plug connector part 18 are each electrically plugged or pluggable to the second plug connector part 14.

Preferably, the second connector part 14 is designed to be four-pole with four contact parts 20, while the first connector part 10 and the third connector part 18 are each designed to be two-pole with two contact parts 22. Since the third connector part 18 is used to connect the power supply line 16, the contact parts 22 of this third connector part are designed to avoid contact with the live parts when the plug connection is released.

The contact parts of the connector part 18 - and preferably also those of the first connector part 10 - are designed as plug sockets 24, while the contact parts 20 of the second connector part 14 are designed as corresponding plug pins 26. In principle, this would of course also be possible the other way round. This described design of the connector device 8 enables the spiral cable 2 according to the invention to be connected extremely easily to the connection cable 12 and to the power supply cable 16. The two connecting wires of the power supply cable 16 are connected to the third connector part 18. The connection cable 12 of the fan motor M is connected to the second connector part 14, with the voltage supply wires being connected to the contact parts 20 assigned to the third connector part 18 and the "control conductor" of the connection cable 12 being connected to the "outer" contact part 20 of the two contact parts 20 assigned to the first connector part 10. The "inner" of these last two contact parts can be connected to a conductor of the power supply cable 16 or to the corresponding contact part 20 via a wire bridge 28, which can be seen in Fig. 1. This connection diagram can be clearly seen in Fig. 1. However, it is particularly advantageous to design the second connector part 14 in such a way that the two corresponding contact parts 20 - in a preferred "series arrangement" of four contact parts (as shown) the two inner contact parts 20 - are already electrically connected to one another internally via a bridge. This advantageously eliminates the need to insert the "external" wire bridge 28. The connection of the individual conductors is very simple due to the use of the "insulation displacement technology". Each contact part 20, 22 of the connector parts 10, 14, 18 has on its side facing the plug-in connector.

socket 24 or the plug pin 26, in a manner known per se, an insulation displacement section 30, wherein the contact parts 20, 22 are each arranged in a plastic housing 32, 33, 34 and each of these housings is connected to a pressing element 36, 37, 38 in such a way that by pressing the respective pressing element in the direction of arrow 40 onto the respective housing, the inserted conductors of the existing cables are contacted by the insulation displacement sections 30, in that the cutting edges of these insulation displacement sections 30 penetrate through the conductor insulation to the metallic conductor and thus bring about a metallic, electrically conductive contact. Each pressing element 36, 37, 38 is connected to the respective housing 32, 33, 34 via lateral locking arms, which interact with locking elements of the respective housing in such a way that the pressing element is held in a form-fitting or at least force-fitting manner in the pressed-on position. This fixed position is shown in Fig. 2 using the first connector part 10.

According to the invention, it is particularly advantageous if the spiral cable 2 and the sensor 6 are cast with an insulating and permanently elastic or flexible casting compound at least in their connection area. The spiral cable 2 and the sensor 6 are thus connected to one another practically in one piece.

In a particularly advantageous development of the invention illustrated in Fig. 1 and 3, a resistance element 42 is electrically connected to the connecting wires 4, 5 of the spiral cable 2, which is thus electrically connected in parallel to the sensor 6. Preferably, this resistance element 42 consists of a standard trim potentiometer.

tiometer 44 - see Fig. 3. The resistance element 42 thus advantageously has a variable resistance, so that due to its parallel connection with the sensor 6, the minimum speed of the fan motor M can also advantageously be continuously changed within a certain range. In this case, it is particularly expedient if the resistance element 42 is detachably plugged into a plastic housing 48 via plug connector elements 46, whereby the contact between the plug connector elements 46 of the housing 48 and the connecting wires 4, 5 of the spiral cable 2 is then preferably made via insulation displacement connectors (analogous to the plug connector device 8, see Fig. 2 and the related description). The plug connector elements 46 of the housing 48 are preferably designed as sockets 50 and those of the resistance element 42 as plug pins 52. The plastic housing 48 advantageously has a receiving recess 54 which is adapted to the spatial shape of the resistance element 42 in such a way that the latter is received in a substantially form-fitting manner by the receiving recess 54 and thus ends flush with the surface of the plastic housing 48.

The resistance element 42 arranged in the housing 48 is therefore a resistance module which can be connected in a simple manner - if necessary also at a later date - to practically any point on the sensor cable according to the invention in parallel to the sensor 6; the arrangement of the resistance element 42 shown in Fig. 1 is therefore only to be understood as an example, ie the resistance element 42 can also be arranged near the plug connector device 8. The trim potentiometer 44 used preferably has a resistance range of 0 to 500 k-Ω, linear.

However, since the resistance element 42 can be removed via the connector elements 46, it can also be easily replaced with other resistance elements with different resistance values. The parallel connection of the sensor 6, which is preferably an NTC resistor, i.e. a resistor with a negative temperature coefficient, with the resistance element 42 always results in a reduction in the total resistance, which results in an increase in the minimum speed of the fan motor M.

In Fig. 4 and 5, an alternative but particularly advantageous embodiment of the connector device according to the invention to Fig. 1 and 2 is illustrated and designated with the reference number 8a. Here too, the spiral cable 2 is connected to the first connector part 10 and the power supply cable 16 is connected to the third connector part 18. The second connector part connected to the connection cable 12 of the motor M is, however, designed here using crimping technology and is therefore designated with the reference number 14a. This design using crimping technology is advantageous in comparison to insulation displacement technology because the conductors of the connection cable 12 can be relatively thick and have relatively thick insulation.

In this embodiment, the connector parts are not directly connected to one another, but according to the invention, each of the connector parts 10, 14a and 18 is electrically connected or can be connected to a corresponding connector counterpart 60, 62 or 64, whereby these connector counterparts 60, 62, 64 are arranged on a circuit board 66 for electrical connection. The circuit board 66 has conductor tracks (not shown) with which the counterparts 60, 62, 64 are connected via corresponding

Solder pins (also not visible) are connected, i.e. soldered.

It is advantageous here if the connector counterparts 60, 62, 64 are enclosed by a cover 68, whereby the cover 68 has a through-opening 70 (see Fig. 5) for the respective connector part 10, 14a, 18 in the area of the insertion side of each counterpart. In the illustrated, particularly advantageous arrangement of the counterparts 60, 62, 64 in a row directly next to one another, the cover 68 naturally only needs to have a uniform through-opening 70. The cover 68 is expediently connected to the circuit board 66 in a detachable manner via a clip connection. This can be seen in Fig. 5; the cover 68 partially encompasses the circuit board 66 with spring-elastic locking webs (not designated).

In this preferred embodiment, it is also advantageous not to connect the resistance element - here as an alternative to Fig. 1 to 3 with the reference number 42a - directly to the conductors 4, 5 of the spiral cable 2, but also to arrange it on the circuit board 66 and thus to connect it indirectly to the conductors 4, 5 of the spiral cable 2 via corresponding conductor tracks and in this way to connect it electrically parallel to the sensor 6. Analogous to Fig. 1 to 3, the resistance element 42a here also consists of the trim potentiometer 44, as already described above. The cover 68 advantageously has a non-designated through-opening for an adjustment axis 72 of the trim potentiometer 44 or for a corresponding tool (e.g. a screwdriver) with which the trim potentiometer

44 is adjustable.

As can be seen in Fig. 4, the circuit board 66 preferably has the shape of an equilateral triangle. As a result, with the arrangement of the components shown, the circuit board 66 can be designed to be particularly small and compact, i.e. with a small surface area.

The invention is not limited to the illustrated and described embodiments, but also includes all embodiments having the same effect within the meaning of the invention.

Claims (12)

6445/+II/bu data precision Computer GmbH Cronenberger Str. 296, 5600 Wuppertal 1 Claims 1. Sensor cable (1) for connecting a sensor (6) that detects a physical measurement value, in particular an NTC resistor, to a component that is to be controlled or regulated depending on the physical measurement value, in particular to a temperature-controlled fan motor (M), consisting of an at least two-core spiral cable (2) that is electrically connected to the sensor (6) at one end and has a plug connector device (8, 8a) in insulation displacement and/or crimping technology at the other end. 2. Sensor cable according to claim 1, characterized in that the plug connector device (8) consists of at least a first insulation displacement plug connector part (10) electrically connected to the spiral cable (2) and a second insulation displacement plug connector part (14) electrically connectable to a connecting cable (12) of the component to be connected (M). 3. Sensor cable according to claim 2, characterized in that the connector device (8) has a third insulation displacement connector part (18) that can be electrically connected to a power supply cable (16), wherein the first and the third connector part (10, 18) are each electrically plug-connected or plug-connectable to the second connector part (14). 4. Sensor cable according to claim 2 or 3,
characterized in that the second connector part (14) is designed as a four-pole connector with four contact parts (20) and the first and third connector parts (10, 18) are each designed as a two-pole connector with two contact parts (22), wherein preferably the contact parts (20) of the second connector part (14) are designed as plug pins (26) and the contact parts (22) of the first and third connector parts (10, 18) are each designed as plug sockets (24). 5. Sensor cable according to claim 1, characterized in that the plug connector device (8a) consists of a first plug connector part (10) that is electrically connected to the spiral cable (2) and is designed using insulation displacement technology, a second plug connector part (14a) that can be electrically connected to a connecting cable (12) of the component (M) to be connected, in particular designed using crimping technology, and preferably a third plug connector part (18) that can be electrically connected to a power supply cable (16), each of these plug connector parts (10, 15a, 18) being provided with a corresponding The connector counterpart (60, 62, 64) is electrically plug-connected or can be plugged in, and the connector counterparts (60, 62, 64) are arranged on a circuit board (66) for electrical connection. 6. Sensor cable according to claim 5, characterized in that the connector counterparts (60, 62, 64) are covered by a cover hood (68), the cover hood (68) having a through opening (70) for the respective connector part (10, 14a, 18) in the region of the insertion side of each connector counterpart (60, 62, 64). 7. Sensor cable according to claim 6, characterized in that the cover (68) is detachably connected to the circuit board (66) via a clip connection. 8. Sensor cable according to one or more of claims 1 to 7, characterized in that the spiral cable (2) and the sensor (6) are cast together at least in their connection area. 9. Sensor cable according to one or more of claims 1 to 8, characterized by a resistance element (42, 42a) which is directly or indirectly electrically connected to the conductors (4, 5) of the spiral cable (2) and thus electrically connected in parallel to the sensor (6). 10. Sensor cable according to claim 9, characterized in that the resistance element (42) can be releasably inserted into a plastic housing (48) via plug connector elements (46), wherein preferably a direct contact is made between the plug connector elements and the conductors (4, 5) of the spiral cable (2) via insulation displacement connectors. 11. Sensor cable according to claim 9, characterized in that the resistance element (42) is arranged on the circuit board (66) for an indirect connection with the conductors (4, 5) of the spiral cable (2), wherein preferably the cover (68) has a through-opening for an adjustment axis (72) of the resistance element (42). 12. Sensor cable according to one or more of claims 9 to 11, characterized in that the resistance element (42, 42a) consists of a standard trim potentiometer (44), preferably in an encapsulated, dust-tight design and in particular in the "small, horizontal" design.