METHOD FOR DETECTING INGRESS OF A VISCOUS MEDIUM IN AN ELECTRONIC ASSEMBLY FOR A VEHICLE

Abstract

The invention relates to a method for identifying infiltration of a viscous medium (18) into an electronic assembly (10) for a vehicle, the electronic assembly (10) comprising at least one housing (40), a printed circuit board (15) and a connection region (45), the housing (40) providing an almost tight enclosure for the electronic assembly (10) and a redundancy being provided in respect of a processing and/or forwarding of electrical signals by means of the printed circuit board (15) in the electronic assembly (10), the redundancy providing at least a first transmission path (1) and a second transmission path (2) operatively parallel thereto, each transmission path (1; 2) consisting of at least one first electrical conductor (11; 21) and a second electrical conductor (12; 22), the electrical conductors (11, 12; 21, 22) each being electrically insulated from one another, and the first transmission path (1) and the second transmission path (2) forwarding the same electrical signal (U), the second transmission path (2) providing a region (30), the first electrical conductor (21) and the associated second electrical conductor (22) having no insulation in this region (30), so that an electrical signal (U) which is conducted by the two electrical conductors (11; 12; 21; 22) is changed to an electrical signal (Uv) in the event that the viscous medium (18) infiltrates into the electrical assembly (10).

Claims

1. A method for detecting ingress of a viscous medium (18) into an electronic assembly (10) for a vehicle, which electronic assembly (10) comprises at least a housing (40), a printed circuit board (15) and a connection region (45), which housing (40) provides an almost tight enclosure for the electronic assembly (10), with redundancy being provided with regard to processing and/or transfer of electrical signals by means of the printed circuit board (15) in the electronic assembly (10), which redundancy provides at least a first transmission path (1) and a second transmission path (2), which is operatively parallel thereto, each transmission path (1; 2) consisting of at least a first electrical conductor (11; 21) and a second electrical conductor (12; 22), which electrical conductors (11, 12; 21; 22) are electrically insulated from each other, wherein the first transmission path (1) and the second transmission path (2) transfer an identical electrical signal (U), wherein the second transmission path (2) provides a region (30), in which region (30) the first electrical conductor (21) and the associated second electrical conductor (22) have no insulation, and therefore in the event of ingress of the viscous medium (18) into the electronic assembly (10), an electrical signal (U) that is being conducted by the two electrical conductors (11; 12; 21;

22. is modified to an electrical signal (Uv), wherein, in addition, said modified signal (Uv) of the second transmission path (2) is compared with the electrical signal (U) of the first transmission path (1), and a warning message (W) is produced if the one electrical signal (U) differs from the modified electrical signal (Uv).

2. The method as claimed in claim 1, wherein the first transmission path (1) is offset in parallel with, and/or at an angle to, the second transmission path (2).

3. The method as claimed in claim 1, wherein the region (30) is positioned such that the viscous medium (18) penetrating into the electronic assembly (10) first reaches the region (30) of the second transmission path (2).

4. The method as claimed in claim 1, wherein the first and second electrical conductors (21, 22) of the second transmission path (2) provide at the region (30) a bridging point (33).

5. The method as claimed in claim 4, wherein the bridging point (33) is formed by the first and second electrical conductors (21, 22).

6. The method as claimed in claim 4, wherein the bridging point (33) is formed by a first test point (25) and a second test point (26), with the first test point (25) connected to the first electrical conductor (21) in an electrically conducting manner, and the second test point (26) connected to the second electrical conductor (22) in an electrically conducting manner.

7. The method as claimed in claim 1, wherein the electrical conductors (11; 12; 21; 22) are conductor tracks on the printed circuit board (15) and/or electrical cables and/or plug-in contacts located inside the housing (40) and/or in the connection region (45).

8. The method as claimed in claim 1, wherein the connection region (45) comprises at least one electrically conducting connection (47) in order to connect the electronic assembly (10) to a further electrical and/or electronic assembly (50).

9. The method as claimed in claim 8, wherein the electrically conducting connection (47) is designed as a current-conducting cable or as a plug-in connection.

10. The method as claimed in claim 1, wherein the redundancy provides at least a third transmission path (3), which third transmission path provides at least a first electrical conductor and a second electrical conductor (31, 32), with the third transmission path provided between the first transmission path and the second transmission path (1; 2).

11. The method as claimed in claim 10, wherein the third transmission path (3) is similar in design to the second transmission path (2), with the following provided in the event of ingress of the viscous medium (18) into the electronic assembly (10): a) if there is further ingress of a viscous medium (18) into the electronic assembly (10), then in the third transmission path (3), the viscous medium (18) modifies the electrical signal (U) in the region (30′) into an electrical signal (Uv′); b) comparison with the electrical signal (U) in the first transmission path (1); c) if (U)≠(Uv′), an additional warning signal (W′) is produced.

12. The method as claimed in claim 1, wherein the viscous medium (18) is water and/or an oil and/or an emulsion and/or a lubricant and/or a cleaning agent and/or an acid and/or a hydraulic fluid.

13. The method as claimed in claim 8, wherein the further electrical/electronic assembly (50) is a steering assembly or a wheel brake or a radar assembly or a lidar assembly or an assembly related to the safety of a vehicle operation.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0023] The invention is described in greater detail below by way of example with reference to figures, in which:

[0024] FIG. 1 shows a structure according to the invention including method for detecting moisture in an electronic assembly;

[0025] FIG. 2 shows a variant according to the invention;

[0026] FIG. 3 shows a variant according to the invention;

[0027] FIG. 4 shows a variant according to the invention;

[0028] FIG. 5 shows a variant according to the invention;

DESCRIPTION

[0029] FIG. 1 shows an electronic assembly 10, which electronic assembly 10 is enclosed by a housing 40. The primary purpose of the housing 40 is to protect the electronic assembly from, for example, moisture or further external influences. The housing 40 provides a connection region 45. The electronic assembly 10 can be connected by means of this connection region 45 to a further electrical or electronic assembly 50, for example, which in turn can be connected by a connection 47. For instance this may involve a known plug connection located on the housing 40. At least one printed circuit board 15 is located in the housing 40. Said printed circuit board 15 provides at least a first transmission path 1 and a second transmission path 2 for processing and transferring electronic signals. Each transmission path is embodied at least as a first electrical conductor 11, 21 and a second electrical conductor 12, 22. It should be mentioned here that the first transmission path 1 and the second transmission path 2 each transfer or transmit an identical electrical signal U. Each transmission path acts as the redundant transmission path to the other. In addition, the electrical conductors 11, 12 and 21, 22 are insulated with respect to one another. It should be mentioned here that the insulation can be implemented by all known embodiments; for example an insulation layer does not necessarily have to be present. For instance, it is sufficient for the electrical conductors to be spaced apart from each other. A region 30 is additionally provided here on the second transmission path 2, in which region 30 the electrical conductors 21 and 22 have no insulation and here preferably have additionally a bridging point 33. Said bridging point 33 is designed such that the two electrical conductors 21 and 22 are spaced closer to one another than outside the region 30. It should also be mentioned here that the second transmission path 2 is arranged inside the housing 40 such that, in the event that ingress of a viscous medium into the housing 40 is possible, the viscous medium gets to the region 30 of the second transmission path 2 first before it can reach further electrical or electronic components inside the housing 40. In the embodiment of FIG. 1 mentioned here, the connection region 45, for example, may be a potential site for the ingress of a viscous material. Said viscous medium may be almost any type of fluid, or, for example, water and/or an oil and/or an emulsion and/or a lubricant and/or a cleaning agent and/or an acid and/or a hydraulic fluid. It should be mentioned here that these cited viscous media are merely examples. It should also be mentioned here that the electronic assembly may also be exposed to spray water, depending on its arrangement in the vehicle.

[0030] The method for detecting ingress of a viscous medium into the electronic assembly shall be described in greater detail below. As already mentioned, the first transmission path 1 and the second transmission path 2 are intended as redundant transmission paths for electronic or electrical signals. This means that the same electrical/electronic signals are transferred both via the first transmission path 1 and via the second transmission path 2. In this case, an electrical signal is transmitted both via the first transmission path 1 and via the second transmission path 2. In the event that, for instance in the region of the connection region 45, a viscous medium penetrates into the housing 40, the penetrating viscous medium 18 will first reach the region 30 of the second transmission path 2. If the viscous medium reaches the uninsulated electrical conductors 21 and 22 in the region 30, which conductors are spaced at a small distance from one another here, then the viscous medium 18 produces at the bridging point 33 a short-circuit between the first electrical conductor 21 and the second electrical conductor 22. In this case, the electrical signal U is not delivered further as the signal U, but instead the short-circuit modifies the electrical signal U into a modified electrical signal Uv. The first transmission path 1 continues to transmit the electrical signal U in unmodified form, with the signal U still present at the end of the first transmission path. The delivered signals are compared at the end of the two transmission paths 1 and 2. Since the electrical signal U is delivered at the end of the first transmission path 1, and the electrical signal Uv is delivered at the end of the second transmission path 2, it is detected that a change in the electrical signal has occurred in the redundant transmission path, in this case the second transmission path 2. A warning signal W is produced if the electrical signal U does not equal the modified electrical signal Uv. By virtue of this method for detecting ingress of a viscous medium into an electronic assembly, it is possible to detect by means of existing components if there is ingress of a viscous medium. The warning message produced in the event of ingress of a viscous medium in an electronic assembly can be used to store a warning for a driver of the vehicle or in the vehicle itself that moisture has penetrated into a safety-related component, for instance, and a visit to a garage is needed at this point. It is important, however, that the redundant path continues to guarantee the function of the electronic assembly. It should be mentioned here for the sake of completeness that, for instance, there may be a connection between the electronic assembly 10 and electrical steering or, for example, even an electrical braking system for a vehicle, in which case this method allows early detection of ingress of a viscous medium into the electronic assembly before failure of the electronic assembly occurs. Thus it can be indicated to the driver or the system that in this case failure of a safety-related system may be likely.

[0031] FIGS. 2, 3 and 4 show invention-related embodiments of the bridging point 33 at which detection of a viscous medium takes place. FIG. 2 shows a region 30 having a bridging point 33, as already described and also shown in FIG. 1. It should be mentioned again at this point that the first and second electrical conductors 21 and 22 here in the region 30 and especially at the bridging point 33 are not insulated, and therefore the viscous medium penetrating from outside can come into contact with the electrical conductors. In order to guarantee the transmission path reliably in the absence of a viscous medium 18, it must be provided that the first and second electrical conductors do not come into contact even in the region 30. To still ensure rapid detection of a viscous medium, however, the first and second electrical conductors 21, 22 are spaced as closely as possible to each other in the region 30. If now, as already mentioned, the viscous medium encounters the bridging point 33, then the viscous medium 18 makes an electrical connection between the first electrical conductor 21 and the second electrical conductor 22, whereby the electrical signal U to be transmitted is modified into an electrical signal Uv.

[0032] FIG. 3 shows a further exemplary embodiment of the bridging point 33 of the region 30 between the first electrical conductor 21 and the second electrical conductor 22. In this case, what is known as a test point 25, 26 is provided for each of the two electrical conductors 21, 22 in the region 30. These test points 25, 26 are known on printed circuit boards, for instance for checking electrical circuits. It is also possible here, however, to use this test point 25, 26 as well to provide a bridging point 33. If now, as described in FIG. 2 and in FIG. 1, a viscous medium 18 reaches the bridging point 33, then the viscous medium 18 produces an electrical connection between the first test point 25 and the second test point 26. It is again the case here that the signal U to be transmitted is modified into a modified signal Uv.

[0033] FIG. 4 shows a further exemplary embodiment for detecting ingress of a viscous medium into an electronic assembly. In this case, the two electrical conductors 21 and 22 are each connected to a measurement pin 27, 28. The measurement pins are designed here such that in the event of ingress of a viscous medium into the electronic assembly 10, they come into contact with the viscous medium first. If the measurement pins 27, 28 make contact with the viscous medium 18 then the electrical signal U to be transmitted is likewise modified into a modified electrical signal Uv.

[0034] FIG. 5 shows a method and structure for detecting ingress of a viscous medium into an electronic assembly as already described in FIG. 1, although in this case there are three redundant transmission paths for an electrical signal U. In this case, unlike FIG. 1, a third redundant transmission path 3 is present, which has a similar design to the redundant transmission path 2. The third redundant transmission path is arranged such that in the event of ingress of a viscous medium into the housing 40 or into the electronic assembly 10, the region 30 of the second transmission path 2 is reached first. As already described, on contact being made by the viscous medium 18 in the region 30 at the bridging point 33, the electrical signal U is modified into the modified signal Uv. By means of the already described comparison with the transmission of the electrical signal U via the first transmission path 1, a warning signal W is produced in the event that an unequal transmission signal U does not equal Uv. As already described, the warning signal W indicates that a viscous medium has penetrated into the electronic assembly. If there is further ingress of the viscous medium 18 into the electronic assembly 10, then as a result of the position of the third transmission path 3, on the viscous medium reaching the region 30′ of the third transmission path 3, a short-circuit is likewise produced between the first electrical conductor 31 and the second electrical conductor 32 of the third transmission path 3. When this happens, the short-circuit at the bridging point 33′ modifies the electrical signal U in the third transmission path 3 into the modified electrical signal Uv′. Then once again a comparison is made between the electrical signal U of the first transmission path 1 and the electrical signal Uv′ of the third transmission path 3. If it is the case that U does not equal Uv′, a further warning signal W′ is produced. Weighting of the warning signal can be performed in this process, more precisely by this arrangement and by this method. For example, if only the warning signal W is present, then ingress of a viscous medium 18 into the electrical assembly 10 is detected, and a visit to a garage is advised for example in this case. If the warning signal W′ occurs, this indicates that there is further ingress of a viscous medium 18 into the electronic assembly 10, and it is urgently advised to visit a garage, for example, or to bring the vehicle into a safe condition or to a standstill. Obviously it should be noted here that this redundancy can be increased as required, although redundancy in duplicate or triplicate, as described in FIGS. 1 and 5, is deemed practical. It should be noted overall that the aim of the invention is to use existing components to detect ingress of a viscous medium into an electronic assembly, with redundancy ensuring that the electrical assembly is still guaranteed to function.

REFERENCE SIGNS

[0035] 1 first transmission path

[0036] 2 second transmission path

[0037] 10 electronic assembly

[0038] 11 first electrical conductor

[0039] 12 second electrical conductor

[0040] 15 printed circuit board

[0041] 18 viscous medium

[0042] 21 first electrical conductor

[0043] 22 second electrical conductor

[0044] 25 first test point

[0045] 26 second test point

[0046] 27 measurement pins

[0047] 28 measurement pins

[0048] 30 region

[0049] 30′ region

[0050] 31 first electrical conductor

[0051] 32 second electrical conductor

[0052] 33 bridging point

[0053] 33′ bridging point

[0054] 40 housing

[0055] 45 connection region

[0056] 47 connection

[0057] 50 electrical/electronic assembly

[0058] U electrical signal

[0059] Uv modified signal

[0060] Uv′ modified signal

[0061] W warning signal

[0062] W′ warning signal