DE102015200549A1 - Circuit device and method for monitoring a circuit device - Google Patents

Abstract

A circuit device (100) is presented which has an electrical circuit (110) and a housing (120) for housing the electrical circuit (110). In this case, by means of the housing (120), the electrical circuit (110) and a cavity (130) within the circuit device (100) fluid-tight einschließbar. The housing (120) in this case has a flow control device (140) for controlling an admission of a gaseous medium to the cavity (130). In this case, the circuit device (100) is characterized by a detection device (150) which is designed to detect a disturbance-related change of at least one property and / or at least one parameter of the gaseous medium arranged in the cavity (130).

Description

The present invention relates to a circuit device and to a method for monitoring a circuit device, in particular for a circuit device in the form of a control device, for example for use in a transmission of a motor vehicle or the like.

Housing, in particular housing of control devices, can be filled with a flowable material in a housing interior for the protection of printed circuit boards arranged in the housing interior and equipped with electronic components. In this case, the flowable material can largely completely fill the housing interior, which extends, for example, via electrical components and a carrier substrate. The filling with the flowable material can be carried out in particular via an opening in a housing part or cover part, which was previously used for example for leak testing of the housing interior by means of positive or negative pressure.

The DE 10 2007 003 009 A1 discloses a method of manufacturing fluid tight housings and a fluid tight housing.

Against this background, the present invention provides an improved circuit device and method for monitoring a circuit device according to the main claims. Advantageous embodiments will become apparent from the dependent claims and the description below.

According to embodiments of the present invention, in particular, a circuit device can be provided with such a housing or used in such a way that a tightness monitoring and / or a tamper protection of a media-tight housing can be realized. For this purpose, an active interior monitoring of the housing with regard to at least one property, for example a state variable, of a predeterminable atmosphere located within the housing can take place on a change caused by leakage, errors and / or manipulation. In particular, it can be monitored whether a defined atmosphere generated within the housing of the circuit device, for example, during a production process, is subject to a fault-related change or fluctuation.

Advantageously, according to embodiments of the present invention, it is possible in particular to achieve a leak-tightness monitoring and / or manipulation monitoring of media-tightly sealed housings, which is aligned with an overall operating time of the circuit apparatus and may be continuous. Thus, printed circuit boards populated with electronic components, which due to their sensitive electronic components are to be hermetically sealed from external influences, can be reliably protected from damage by leakage or manipulation by circuit devices. It can be a cost-effective monitoring of leaks or leaks in the housing and for tamper resistance can be realized. In this case, the circuit device can be produced by means of an inexpensive production method, wherein devices can be equipped by means of conventional tools. By such leakage monitoring and / or manipulation monitoring damage can be detected, such as burst capacitors or the like, a nondestructive diagnosis and / or repair is possible and can be avoided that chemically interacting or reactive substances are introduced with the circuit device. Furthermore, it can be avoided that consequential damage to components or devices that are connected to the circuit device or functionally associated with the same, such as transmissions of vehicles or the like, and as a result malfunction of such components or devices occur, such as a sudden absences a vehicle on a road.

A circuit device comprising an electrical circuit and a housing for housing the electrical circuit, wherein by means of the housing, the electrical circuit and a cavity within the circuit device are fluid-tight einschließbar and / or enclosed, wherein the housing is a flow control device for controlling an access of a gaseous medium to the cavity, is characterized by a detection device, which is designed to detect a disturbance-induced change of at least one property and / or a parameter of the gaseous medium arranged in the cavity.

The circuit device may be a controller, a sensor device, or the like. In particular, the circuit device can be embodied as a control device for a vehicle, for example as a control device for a transmission of a vehicle, wherein the circuit device can be arranged in a region of a transmission of a vehicle. In addition, the circuit device may in particular be embodied as a sensor device for a vehicle, for example as a sensor device for a media-tight housing such as a motor vehicle battery or battery bay for a hybrid vehicle. This would be a simple way of influencing, manipulation or Destruction of the media-tight housing or arranged in the media-tight housing components detect by gassing. The circuit device may comprise a circuit board or printed circuit board on which the electrical circuit may be arranged. The electrical circuit may comprise at least one electrical or electronic component. The circuit device may comprise at least one electrical circuit. The gaseous medium may comprise a gas or a gas mixture of a plurality of gases. The gaseous medium may be gaseous at least at standard conditions. The cavity may be disposed between a wall of the housing and a circuit board or circuit board of the circuit device. The housing may be configured to fluid-tightly enclose or seal the electrical circuit and the cavity. In this case, the housing may in particular be designed to include the electrical circuit and the cavity in a fluid-tight manner permanently or for a defined period of time, wherein a gradual migration of molecules may be possible. The housing is attachable using sealants or connectable to a portion of the circuit device. The sealing means may be adapted to swell upon contact with a liquid, whereby a sealing effect can be enhanced. The flow control device may have a passage opening and a valve, which may be arranged in a region of the passage opening. The valve may be a check valve or the like. The at least one property of the medium may be a state variable, in particular a thermodynamic state variable, a chemical species or a gas composition. The disturbance-related change may be due to a leakage of the housing, caused by a malfunction of the circuit device and additionally or alternatively by a manipulation or improper handling caused or caused.

According to one embodiment, the detection device may comprise at least one sensor element which is designed to detect a disturbance-related change of a pressure, a temperature, a composition and additionally or alternatively a humidity of the gaseous medium arranged in the cavity. The switching device may have, in addition to the detection device, a temperature sensor, which may be connectable or connectable to the detection device in a manner capable of data transmission. Such an embodiment offers the advantage that a suitable property for fault detection or a combination of properties suitable for fault detection can be evaluated in order to be able to reliably and securely monitor the circuit device for leaks, manipulations and the like. By acquiring various properties or a plausibility check by diversification of measured variables, the accuracy and correctness of a fault detection can be improved.

The detection device can also have at least one first sensor element which can be arranged or arranged within the housing and at least one second sensor element which can be arranged or arranged outside the housing. In this case, the first sensor element and the second sensor element can be designed to detect at least one identical property or different properties or quantities. Such an embodiment offers the advantage that an accuracy of the interference detection can be improved by a comparison between different locations for plausibility is made possible.

In this case, the detection device can be arranged within the housing or arranged pressure sensor for detecting a pressure of the disposed in the cavity gaseous medium or arranged within the housing or arranged pressure sensor for detecting a pressure of the disposed in the cavity gaseous medium and an outside of the housing can be arranged or arranged pressure sensor for detecting a pressure of an environment of the circuit device. Such an embodiment has the advantage that leakage, manipulation and / or malfunction of the circuit device can be reliably detected using inexpensive sensors. Because pressure changes can be related to a variety of different disorders and thus be detected.

In addition, the detection device can have a temperature sensor which can be arranged or arranged within the housing for detecting a temperature of the gaseous medium arranged in the cavity and additionally or alternatively have a temperature sensor which can be arranged or arranged outside the housing for detecting a temperature of an environment of the circuit device. Such an embodiment offers the advantage that a multiplicity of disturbances can likewise be detected on the basis of temperature changes, wherein a combination with sensor elements for acquiring other measured variables can be used to check the plausibility of the plausibility of detecting faults even more reliably and reliably.

In particular, the detection device can have at least one pressure sensor or a pressure sensor and one temperature sensor. Thus, in a cost effective way a Confirmation recognition can be realized, which can be used, for example, on existing sensors in the form of a temperature sensor.

Furthermore, the detection device can have a gas sensor which can be arranged or arranged within the housing for detecting a gas species or gas composition of the gaseous medium arranged in the cavity and additionally or alternatively a humidity sensor which can be arranged or arranged within the housing for detecting a humidity of the gaseous medium arranged in the cavity. Thus, the detection device can also be designed to perform an evaluation method for detecting a moisture in the cavity or within the housing or to detect moisture in the cavity or within the housing. Such an embodiment has the advantage that when special gases are detected by their detection, an integrity of the housing in a simple and secure manner and, if necessary, also detected harmful moisture and thus damage caused by the switching device can be averted.

In particular, at least one sensor element of the detection device can be arranged in a protective element partially embedded in a housing material or a potting compound. In this case, the protective element may be formed in order to establish a fluid connection between the cavity and the at least one sensor element of the detection device. The protective element can be a tube, an open hollow cylinder or another snorkel-shaped element. In the potting compound, the electrical circuit of the circuit device may be at least partially encapsulated. Such an embodiment offers the advantage that in addition a potting compound can be used to improve protection against intrusion of hostile media without impairing a function of the detection device.

A method for monitoring a circuit device according to a variant presented here is characterized in that the method comprises the following steps:
Controlling an admission of a gaseous medium to the cavity using the flow control means of the housing to adjust an amount of the gaseous medium in the cavity; and
Detecting a disturbance-related change of at least one property and / or at least one parameter of the gaseous medium disposed in the cavity using the detection device of the circuit device.

The method may be advantageously carried out in conjunction with an embodiment of the aforementioned circuit device to monitor the circuit device for an intact and additionally or alternatively proper condition. In the step of controlling, a quantity of gaseous medium may be introduced into the cavity and additionally or alternatively discharged out of the cavity. In this case, in the step of controlling an overpressure or a negative pressure in the cavity can be generated, wherein a pressure value of a pressure generated in the cavity can be set to a defined value. If an overpressure is applied to the cavity in the step of controlling, entry of foreign matter, especially water, water vapor, oil or the like, in the cavity can be reduced or avoided. In addition, such a monitoring option can be created if foreign substances should have penetrated. In the step of controlling, in particular a special gas or special gases can be introduced into the cavity. A special gas may have a protective gas, for example nitrogen. By using special gases, improved heat dissipation or improved thermal management can be achieved, an unscheduled gas exchange or a manipulation associated therewith can be monitored and detected, and a risk of corrosion, for example at contact points, solder joints, etc., can be reduced. In particular, in the step of controlling, a gaseous medium having defined properties, such as moisture and gas composition, may be introduced into the cavity. Thus, adjustment and monitoring of a desired atmosphere, for example in terms of moisture and inert gas, can be made possible. After the step of controlling, the method may include a step of fluid-tightly closing the flow control device. In this case, the flow control device can for example be welded or closed or sealed with a plug or the like. Thus, an improved assurance of tightness of the housing can be achieved.

According to an embodiment, in the step of detecting, a gradient and additionally or alternatively a value of the at least one property and / or the at least one parameter may be compared to a threshold value in order to detect the disturbance-related change. Also, the step of detecting may be repeatedly performed. In particular, the step of detecting may be performed every time the circuit device is put into operation, and additionally or alternatively during operation of the circuit device be executed repeatedly. Such an embodiment offers the advantage that a large number of different fault events can be reliably detected in order to prevent or minimize consequential damage.

Furthermore, in the step of detection, a first property and / or a first parameter of the gaseous medium arranged in the cavity and a second property and / or a second parameter of the gaseous medium arranged in the cavity and additionally or alternatively at least one property and / or at least a parameter of the disposed in the cavity gaseous medium and at least one property and / or at least one parameter of an environment of the circuit device are evaluated to detect the disturbance-induced change. Such an embodiment offers the advantage that such a fault detection can provide particularly reliable results, with an alignment of the fault detection on different measured variables both a plausibility of measurement results and an increase in a recognition accuracy can be realized.

A computer program product with program code which can be stored on a machine-readable carrier such as a semiconductor memory, a hard disk memory or an optical memory and is used to carry out the method according to one of the embodiments described above if the program is installed on a computer or a device is also of advantage is performed.

In one embodiment variant of the circuit device as a transmission control unit, which is placed, for example, in a transmission fluid or oil, a housing interior can be sealed to an external environment in order to reliably prevent the penetration of transmission fluid into the housing interior and damage to electrical components or an electrical circuit of the circuit device , And a protective function of the housing can be additionally checked for their effectiveness.

In particular, it can be avoided according to embodiments of the present invention that, for example, only potting compound is used to protect the circuit device. Thus, it can be prevented, for example, that air pockets or cracks in the potting compound during filling and thus could penetrate external media and that the circuit device could be leaking in spite of filling with potting, leaking filler and / or foreign substances could penetrate. Such known, filled with potting, applicable as media-tight housing can be tested by a leak test once, for example, at a production time, on their media tightness usual way. Thus, in accordance with embodiments of the present invention, it can be avoided that leaks occur in a curing process of the package sealing compound, and the leak tested circuit fails, for example, after a few days of operation, and in accordance with embodiments of the present invention, a leak in the package also occurs can already be determined before a failure of the circuit device. It can therefore be prevented in accordance with embodiments of the present invention that there are safety-critical and incalculable safety risks, dropouts and / or misconduct, for example, that a vehicle remains in the middle of driving on a highway or the like. In particular, according to embodiments of the present invention, a permanent monitoring of a housing density over a term of the circuit device can be realized, which may allow early warning of a sudden and likely failure of the circuit device. Furthermore, a non-destructive fault diagnosis and / or repair of the divider device, in particular the electrical circuit, can be made possible. It can also be prevented that the circuit device without a trace or unnoticed by third parties or unauthorized persons for reading or manipulation example, a telematics control unit (TCU, Telematic Control Unit) can be opened and closed again and thereby late effects, eg. As a destruction of a transmission of a vehicle can be caused. For example, this can also reputation damage of a manufacturer, repair costs, etc. are avoided, which would be created by, for example, such a manipulated gear. Also, according to embodiments of the present invention, which can be partially or completely dispensed with a potting compound, the problem can be circumvented that by subsequent damage, by any penetrating dirt or by mechanical stress, a potting compound could decompose or rupture, resulting in a partial Ingress of foreign substances would result. According to embodiments of the present invention can be dispensed with a potting compound partially or completely, it can be avoided that, for example, by comparison with a circuit board of the circuit device different expansion coefficients of the potting compound to mechanical stresses in the circuit device comes. It can also be prevented at exposed or open positions of a printed circuit board of the circuit device, for example around so-called exposed pads, to which a Base material of the circuit board is open, the encapsulant or filling material penetrate and could lead to unforeseeable damage, such as capacitive influences in the high frequency range, leakage currents, heat accumulation or heat load of adjacent components, infiltration and thus possibly detachment of components, interactions with decomposition products or like.

The invention will be described by way of example with reference to the accompanying drawings. Show it:

1 to 4 schematic sectional views of circuit devices according to embodiments of the present invention; and

5 a flowchart of a method according to an embodiment of the present invention.

In the following description of preferred embodiments of the present invention, the same or similar reference numerals are used for the elements shown in the various figures and similarly acting, wherein a repeated description of these elements is omitted.

1 shows a schematic sectional view of a circuit device 100 according to an embodiment of the present invention. The circuit device 100 is for example designed as a control unit. In this case, the switching device is provided for example for an application for controlling a vehicle transmission. The circuit device can be arranged here in the region of a transmission of a vehicle.

The circuit device 100 according to the in 1 illustrated embodiment of the present invention, an electrical circuit 110 and a housing 120 on. The housing 120 is designed to handle the electrical circuit 110 einhausen or in other words in particular the circuit device 100 fluid-tight against an environment of the switching device 100 seal. Inside the case 120 is a cavity 130 arranged. The cavity 130 is in accordance with the in 1 illustrated embodiment of the present invention adjacent to the electrical circuit 110 arranged. The cavity 130 is from the case 120 enclosed in a fluid-tight manner. Thus, the electrical circuit 110 and the cavity 130 with respect to an environment of the circuit device 110 fluid-tight in the housing 130 locked in.

The housing 120 has a flow control device 140 on or in the housing 120 is the flow control device 140 arranged. According to the 1 Illustrated embodiment of the present invention is the flow control device 140 in a housing wall of the housing 120 arranged. The flow control device 140 is designed to allow access of a gaseous medium to the cavity 130 to control. In particular, the flow control device 140 usable to a defined amount of the gaseous medium in the cavity 130 to arrange. The gaseous medium is, for example, a gas, a protective gas or a mixture of multiple lanes. Even if it is in 1 is not explicitly shown, so the flow control device 140 for example, have a check valve. In other words, the flow control device 140 a closable opening of the housing 120 on.

The circuit device 100 further comprises a detection device 150 on. The detection device 150 is adapted to a disturbance-induced change of at least one property of in the cavity 130 to detect arranged gaseous medium. The detection device 150 is according to the in 1 illustrated embodiment of the present invention within the housing 120 arranged. Optionally, the detection device 150 have at least one sensor element. Such a sensor element may be configured to cause a change in a pressure, a temperature, a composition and / or a moisture in the cavity due to interference 130 to detect arranged gaseous medium. According to an embodiment, the detection device 150 at least one inside the case 120 arranged, the first sensor element and at least one outside of the housing 120 having arranged, second sensor element. Alternatively, the detection device 150 only two or more inside the case 120 having arranged sensor elements.

The electrical circuit 110 can optionally have at least one electronic component. According to embodiments, the housing 120 be executed in one piece or more parts, wherein in a multi-part design, the housing 120 For example, may have a housing bottom and a housing cover, which may be connected to one another via adhesion-promoting sealing means. The flow control device 140 According to one embodiment, a passage opening through a housing wall of the housing 120 through and have a valve disposed in the passage opening.

2 shows a schematic sectional view of a circuit device 100 according to an embodiment of the present invention. At the in 2 shown circuit device 100 For example, these are the Switching device off 1 , in the 2 is shown in more detail, or one of in 1 shown circuit device similar circuit device.

In the 2 shown circuit device 100 corresponds to the circuit device 1 with the exception that of the electrical circuit, a plurality of electronic components 210 shown are on a printed circuit board 215 are arranged, that of the housing a housing bottom 222 , a housing cover 224 and sealants 226 or a sealing element are shown and that the circuit device 100 also a plug 260 has, which is sealed in or shed with a housing material.

According to the 2 illustrated embodiment of the present invention comprises the detection device 150 a pressure sensor attached to the circuit board 215 is arranged. Also one in 2 is not shown explicitly, the detection device 150 also have a temperature sensor. Alternatively, the circuit device 100 a temperature sensor connected to the detection device 150 can be connected in a data-transferable manner. The cavity 130 is between the assembled circuit board 215 and the housing cover 224 arranged. The flow control device 140 is in the housing cover 224 arranged. The caseback 222 and the housing cover 226 are by means of the sealant 226 or the sealing element fluid-tightly connected to each other. The plug 260 is designed to external electrical contacting of the assembled printed circuit board 215 or the electronic components 210 and the detection device 150 to convey.

In other words, shows 2 the housing of a circuit device designed as a control device 100 wherein the flow control device 140 having an inlet valve in the housing cover 224 is integrated. The circuit device 100 is equipped for a pressure test. After the successful pressure test in a manufacturing process, a defined amount of gaseous medium or gas quantity for generating a defined pressure in the cavity is via the inlet valve 130 filled or from the cavity 130 aspirated. If a previously performed pressure test fails, the housing is leaking and will be sorted out accordingly. After a successful pressure test, a gas filling element is connected to the inlet valve or to the flow control device 140 connected and a defined amount of gaseous medium in the cavity 130 arranged inside the housing. So inside the housing is a defined chamber under pressure in the cavity 130 produced. As the case in which the circuit board 215 and the electronic components loaded thereon 210 are included, even at joints between the housing bottom 222 and the housing cover 224 due to the sealant 226 as well as in the area of the sealed and, for example, molded-on connector 260 media-tight, should, for example, a defined and generated by filling the gaseous medium pressure in the cavity 130 remain constant in the absence of a disturbance, in particular taking into account or compensation for temperature fluctuations. Such overpressure may be for example 1 bar, whereby other suitable pressure values may be generated. The sealants 226 For example, they may have at least one sealing element which swells when in contact with a liquid and seals the housing to a greater extent. After the filling process, to improve the tightness of the housing, the flow control device may 140 welded or sealed or sealed with a plug.

Before evaluation method or method for monitoring the circuit device 100 on leakage, manipulation and the like are described in more detail, it should be mentioned that by expanding a volume of the gaseous medium expands and thus a pressure in the cavity 130 increases. This physical effect can be taken into account. An error due to temperature rise or due to falling temperature can by means of a temperature sensor, the detection device 150 can be compensated inside and / or outside of the housing. A volume change over temperature for a particular gas or gaseous medium may be present in the detector 150 deposited and used in a detection process to compensate for the temperature-induced pressure change.

In a first variant of an evaluation method, a pressure drop measurement, the pressure sensor, in particular a barometer, is the detection device 150 arranged inside the housing. The pressure sensor is over the circuit board 215 or a circuit carrier with an evaluation unit, for example a microcontroller, of the detection device 150 connected. In this case, the evaluation also outside the circuit device 100 be arranged. Over a term of the circuit device 100 In the meantime, pressure will decrease each year by outgassing by an assumed or approximable value. This value can be measured, calculated or estimated and stored in the evaluation unit. The outgassing can be stored as a permissible pressure drop and with a time stamp of the circuit device 100 providable. Such a pressure drop per year can be with safety values or Tolerance Surcharge, for example at 100 millibars. This pressure drop measurement could, for example, be performed once each time the vehicle is started, if the circuit device 100 is installed in a vehicle. Exceeds the pressure drop, the permissible value, so may from a leak and thus a media exchange between the cavity 130 and an environment of the circuit device 100 or be assumed by an opening of the housing. This can be reported to a main control unit which, for example, can display to a driver via a display in the vehicle cockpit an indication for the search for the next workshop.

Another variant of an evaluation method is a residual pressure measurement. It can be of a certain duration, for example, 15 years or the like, the circuit device 100 be assumed. Within the running time is a residual pressure in the cavity 130 or a housing interior a stored value, limit or threshold, for example, 0.2 bar, which can be determined on the outgassing, not exceed. Again, a measurement at engine start, an hourly measurement, etc. conceivable.

In particular, rapid pressure fluctuations can be detected by, for example, periodically repeating and frequent execution of the method. Such variations can be achieved, for example, by opening the housing or, for example, by a condenser explosion, with the cavity being inflated thereby 130 be justified. Consequently, a pressure increase can also be evaluated.

3 shows a schematic sectional view of a circuit device 100 according to an embodiment of the present invention. At the in 3 shown circuit device 100 For example, it is the circuit device 1 respectively. 2 or a similar circuit device. In the 3 shown circuit device 100 This corresponds to the circuit device 2 except that the detection device 150 in addition to a sensor element arranged within the housing, as it is also in 2 is shown, a further sensor element which is arranged outside of the housing. According to the in 3 illustrated embodiment of the present invention is the further sensor element of the detection device 150 in the area of the plug 260 arranged. In the further sensor element of the detection device 150 For example, it is an additional pressure sensor.

The additional pressure sensor outside the housing of the circuit device 100 is adapted to an ambient pressure in an environment of the switching device 100 to investigate. In this case, the detection device 150 formed to the determined value of the ambient pressure with a value from the acting as a pressure chamber cavity 130 to compare. The outside of the housing arranged pressure sensor is according to the in 3 illustrated embodiment of the present invention on the molded connector 260 attached and largely protected, for example by means of a plug seal against external influences. Like plug pins of the plug 260 the further pressure sensor can be used for data transfer with the printed circuit board 215 and / or a part of the detection device arranged inside the housing 150 be connected. Are the two measured values, ie the pressure value for the cavity 130 and the pressure value for the environment, very similar or the same, it is assumed that a leak in the housing or an example wanton opening of the housing.

In such an evaluation method can optionally be dispensed with temperature sensors. Alternatively, a manipulative opening of the housing in a pressure chamber, external pressure equal to internal pressure, can be detected by using at least one temperature sensor. When dispensing with outside and / or inside mounted temperature sensors, a cost-effective circuit device 100 to be provided. In a further, particularly safe, a temperature sensor arranged outside the housing can be used, since with special extreme temperatures or temperature fluctuations, for example at +100 degrees Celsius or -100 degrees Celsius, the internal pressure within the cavity 130 could be equal to an external pressure due to an expansion or contraction of the gaseous medium in the cavity 130 , Thus, an improved validation can be achieved and, in particular, it can be prevented that in such a special case otherwise an error would be displayed that actually does not exist at all.

4 shows a schematic sectional view of a circuit device 100 according to an embodiment of the present invention. At the in 4 shown circuit device 100 For example, it is the circuit device 1 . 2 respectively. 3 or a similar circuit device. In the 4 shown circuit device 100 this corresponds to the circuit device 2 except that the circuit device 100 furthermore a protective element 455 in which the detection device 150 or at least one sensor element of the same, and that the cavity 130 partially with a potting compound 470 is filled. Here is the protective element 455 partially in the potting compound 470 embedded. The protective element 455 is formed to provide fluid communication between the cavity 130 and the at least one sensor element of the detection device 150 manufacture. Alternatively, the protective element 455 partially embedded in a housing material.

In other words, shows 4 a circuit device 100 , for reasons of vibration safety, additional protective seal or the like with potting compound 470 partially filled. According to the in 4 illustrated embodiment of the present invention, the circuit device 100 by way of example, only one chamber. In this case, the detection device 150 or at least one sensor element thereof, for example a pressure sensor, by means of the protective element 455 with the cavity 130 fluidly connected. In the protective element 455 For example, it is a tube in which the detection device 150 or the at least one sensor element of the detection device 150 is placed. In the case of partially encapsulated electronic components 210 an evaluation method can be used which is executable in accordance with or similar to the methods described above.

Alternatively, the switching device 100 be divided into several chambers or cavities. In this case, in each chamber, for example, a pressure sensor of the detection device 150 be arranged. Should by the potting compound 470 or a connection to the plug 260 be formed further cavities, so they can by means of trachea or fluidly with the detection device 150 or whose at least one sensor element can be connected or each cavity can be provided with at least one further sensor element.

5 shows a flowchart of a method 500 according to an embodiment of the present invention. The procedure 500 is feasible to monitor a circuit device, in particular to perform a leak-tightness and tamper protection over a life of the separation device away. Here is the procedure 500 in connection with a circuit device such as a circuit device of any one of 1 to 4 executable.

The procedure 500 has a step 510 the provision of a circuit device. Here, for example, a circuit device such as the circuit device of one of 1 to 4 provided. Generally speaking, in step 510 providing a circuit device having an electrical circuit and a housing for housing the electrical circuit. In this case, the electrical circuit and a cavity within the circuit device can be enclosed in a fluid-tight manner by means of the housing. The housing in this case has a flow control device for controlling an admission of a gaseous medium to the cavity. In this case, the circuit device is characterized by a detection device, which is designed to detect a disturbance-related change of at least one property of the gaseous medium arranged in the cavity.

In a subsequent step 520 controlling the admission of gaseous medium to the cavity using the flow control means of the housing to adjust an amount of the gaseous medium in the cavity. Here is by performing the step 520 controlling a defined atmosphere within the cavity.

In one step 520 of controlling subsequently executable step 530 detecting, a disturbance-induced change of at least one property of the gaseous medium disposed in the cavity is detected by using the detection means of the circuit device. This is the step 530 the acquisition multiple times or repeatedly executable. In particular, the step 530 of the detection at definable intervals repeatedly or repeatedly executable.

According to one embodiment, in step 530 detecting a gradient and / or a value of the at least one property with a threshold value in order to detect the disturbance-related change. Optionally be in step 530 detecting a first property of the disposed in the cavity gaseous medium and a second property of the disposed in the cavity gaseous medium to detect the disturbance-induced change. Additionally or alternatively, in step 530 detecting at least one property of the gaseous medium disposed in the cavity and at least one property of an environment of the circuit device to detect the disturbance-related change.

With reference to the 1 to 5 It should be noted that the above-described monitoring method or evaluation methods and arrangements also for a suction of the gaseous medium in the housing interior or cavity 130 , So generating a negative pressure, in the extreme case of a vacuum, in the cavity 130 be valid. Alternatively, a special gas or inert gas via the flow control device 140 in the cavity 130 be initiated.

The following are with reference to 1 to 5 now summarizes background and embodiments of the present invention and / or explained in other words.

For leak testing of a housing 120 For example, with the flow control device 140 a valve or an opening in the housing 120 be arranged over the or a gaseous medium in the housing 120 can be initiated in the cavity 130 of the housing 120 So briefly an overpressure can be generated. If this pressure remains constant during the duration of the leak test, the housing is valid 120 as tight. The flow control device 140 can be used according to embodiment of the present invention for the introduction or discharge of a gaseous medium. The flow control device 140 This may for example have a check valve, so that a filled amount of gas can not escape. A state of the gaseous medium is a pressure, a temperature, a state of decomposition of unstable gases, a humidity, an additive content, a volume of the cavity 130 and / or the like. For example, in the cavity 130 an overpressure of 1 bar or other suitable value of generated. Inside the case 120 is the detection device 150 arranged, which in particular has a pressure sensor and additionally or alternatively has a temperature sensor or uses an existing temperature sensor, and additionally or alternatively may have additional sensors for humidity, gas species and / or the like. The detection device 150 is designed to over a term of the circuit device 100 For example, by at least one of various evaluation methods to detect a pressure change with respect to an initial pressure. About evaluation, an irregular or unscheduled pressure change, for example, a pressure drop, to a with the circuit device 100 be reported data transfer capable connected control unit. A pressure drop may occur, for example, by a gas exchange between the cavity 130 and the external environment. Consequently, it can be assumed that the circuit device 100 has leaked or opened unplanned. An increase in pressure, on the other hand, can be an indication of a burst capacitor, a smoking chip, or degrading adhesives or fillers.

According to one embodiment, the detection device 150 one inside the case 120 arranged pressure sensor for detecting a pressure of the in the cavity 130 arranged gaseous medium. This case is for example with 1 comparable and in 2 shown. Alternatively, the detection device 150 one inside the case 120 arranged pressure sensor for detecting a pressure of the in the cavity 130 arranged gaseous medium and one outside the housing 120 arranged pressure sensor for detecting a pressure of an environment of the circuit device 100 on. This case is for example in 3 shown. Additionally or alternatively, the detection device 150 one inside the case 120 arranged temperature sensor for detecting a temperature of the in the cavity 130 arranged gaseous medium and / or outside the housing 120 arranged temperature sensor for detecting a temperature of an environment of the circuit device 100 exhibit. Furthermore, the detection device 150 optionally one inside the housing 120 arranged gas sensor for detecting a gas species or gas composition in the cavity 130 arranged gaseous medium and / or one within the housing 120 arranged humidity sensor for detecting a moisture in the cavity 130 having arranged gaseous medium.

Alternatively, the detection device 150 be designed as a special type of pressure sensor, the one in the cavity 130 arranged arranged glass tube. This can be achieved by a simple and inexpensive type of pressure sensor. The detection of a change of a measured variable by means of such a sensor is to a certain extent binary. The glass tube can have a defined internal pressure. A glass wall of the tube is stable at a defined external pressure range. Without this external counterpressure, the glass shatters. Such a glass tube could, for example, be set to an outside overpressure of 0.2 bar or the like as a threshold value. If this threshold is exceeded, for example, in the event of a leak or opening of the housing 120 , the wall of the glass tube does not withstand a resulting compressive force and it breaks. This breakage could be detected by means of a sensor signal. Thus, protection against manipulation can also be realized.

An evaluation can be carried out, for example, using the general ideal gas equation p * V * T = const., Or in particular for isochoric state changes (V = const.) Using p * T = const.

If the case 120 would be opened in a pressure chamber, the pressure (p) in the cavity would be 130 still constant. The temperature (T) could change here, however. By means of an internal temperature sensor and / or an external Temperature sensor can be detected and validated such a change in temperature.

Further, according to one embodiment, intrusion or presence of oil or water vapor in the cavity 130 or housing interior by means of suitable sensor elements of the detection device 150 be recognized and evaluated. Moisture sensors could detect water in the cavity 130 be used.

In addition, for example, a volume in the cavity 130 when condensing water vapor change. Water vapor requires a larger volume than in condensed droplet form. As a result, the volume in the cavity changes 130 , The gas equation described above is not constant. Even with an introduction of a special gas, the gas equation may change. The term p · V · T would then no longer be constant, but substance-dependent. Substance values for a specific gas can be known and taken into account in the equation and optionally evaluated in the sense of a fingerprint. If another gas is introduced during manipulation, this could be determined via the equation or a gas composition by means of a gas analysis sensor. It is also possible to use an unstable gaseous medium which, for example, reacts with ambient air. Such a reaction can be detected by means of an analysis sensor or detector of the detection device.

According to one exemplary embodiment, fire detection can be carried out by means of carbon monoxide sensors or CO detectors. Furthermore, a CO detector can detect and verify a composition of the charged gaseous medium. This also applies to other compositions of substances or gas sensors.

The embodiments described and shown in the figures are chosen only by way of example. Different embodiments may be combined together or in relation to individual features. Also, an embodiment can be supplemented by features of another embodiment.

If an exemplary embodiment comprises a "and / or" link between a first feature and a second feature, this can be read so that the embodiment according to one embodiment, both the first feature and the second feature and according to another embodiment, either only the first Feature or only the second feature.

LIST OF REFERENCE NUMBERS

100

circuit device

110

electrical circuit

120

casing

130

Cavity or air chamber

140

Flow control device or inlet valve

150

detector

210

electronic component

215

circuit board

222

caseback

224

housing cover

226

Sealant or sealing element

260

plug

455

Protective element or trachea

470

potting compound

500

Method of monitoring

510

Step of providing

520

Step of controlling

530

Step of grasping

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102007003009 A1 [0003]

Claims (12)

Circuit device ( 100 ), which is an electrical circuit ( 110 ; 210 ) and a housing ( 120 ; 222 . 224 . 226 ) for housing the electrical circuit ( 110 ; 210 ), wherein by means of the housing ( 120 ; 222 . 224 . 226 ) the electrical circuit ( 110 ; 210 ) and a cavity ( 130 ) within the circuit device ( 100 ) are enclosed and / or enclosed in a fluid-tight manner, wherein the housing ( 120 ; 222 . 224 . 226 ) a flow control device ( 140 ) for controlling an admission of a gaseous medium to the cavity ( 130 ), wherein the circuit device ( 100 ) is characterized by a detection device ( 150 ) which is adapted to cause a disturbance-related change of at least one property and / or parameter of the cavity in the cavity ( 130 ) to detect gaseous medium arranged. Circuit device ( 100 ) according to claim 1, characterized in that the detection device ( 150 ) has at least one sensor element which is designed to detect a change in a pressure, a temperature, a composition and / or a humidity of the cavity in the cavity ( 130 ) to detect gaseous medium arranged. Circuit device ( 100 ) according to one of the preceding claims, characterized in that the detection device ( 150 ) at least one within the housing ( 120 ; 222 . 224 . 226 ) can be arranged or arranged, the first sensor element and at least one outside of the housing ( 120 ; 222 . 224 . 226 ) can be arranged or arranged, second sensor element. Circuit device ( 100 ) according to one of the preceding claims, characterized in that the detection device ( 150 ) one within the housing ( 120 ; 222 . 224 . 226 ) arranged or arranged pressure sensor for detecting a pressure of the in the cavity ( 130 ) arranged gaseous medium or within the housing ( 120 ; 222 . 224 . 226 ) arranged or arranged pressure sensor for detecting a pressure of the in the cavity ( 130 ) arranged gaseous medium and one outside the housing ( 120 ; 222 . 224 . 226 ) arranged or arranged pressure sensor for detecting a pressure of an environment of the circuit device ( 100 ) having. Circuit device ( 100 ) according to one of the preceding claims, characterized in that the detection device ( 150 ) one within the housing ( 120 ; 222 . 224 . 226 ) arranged or arranged temperature sensor for detecting a temperature of the in the cavity ( 130 ) arranged gaseous medium and / or one outside the housing ( 120 ; 222 . 224 . 226 ) arranged or arranged temperature sensor for detecting a temperature of an environment of the circuit device ( 100 ) having. Circuit device ( 100 ) according to one of the preceding claims, characterized in that the detection device ( 150 ) one within the housing ( 120 ; 222 . 224 . 226 ) arranged gas sensor for detecting a gas species or gas composition of the in the cavity ( 130 ) arranged gaseous medium and / or within the housing ( 120 ; 222 . 224 . 226 ) arranged or arranged moisture sensor for detecting a moisture in the cavity ( 130 ) arranged gaseous medium. Circuit device ( 100 ) according to one of the preceding claims, characterized in that at least one sensor element of the detection device ( 150 ) in a partially in a housing material or a potting compound ( 470 ) embedded protection element ( 455 ), the protective element ( 455 ) is formed to a fluid connection between the cavity ( 130 ) and the at least one sensor element of the detection device ( 150 ). Procedure ( 500 ) for monitoring a circuit device ( 100 ) according to one of the preceding claims, characterized in that the method ( 500 ) comprises the following steps: controlling ( 520 ) an admission of a gaseous medium to the cavity ( 130 ) using the flow control device ( 140 ) of the housing ( 120 ; 222 . 224 . 226 ) to remove an amount of the gaseous medium in the cavity ( 130 ); and capture ( 530 ) a disturbance-related change of at least one property and / or at least one parameter of the in the cavity ( 130 ) arranged gaseous medium using the detection device ( 150 ) of the circuit device ( 100 ). Procedure ( 500 ) according to claim 8, characterized in that in step ( 530 ) of detecting a gradient and / or a value of the at least one property and / or the at least one parameter with a threshold value in order to detect the disturbance-related change, wherein the step ( 530 ) of detecting is carried out repeatedly. Method according to one of claims 8 to 9, characterized in that in step ( 530 ) of detecting a first property and / or a first parameter of the in the cavity ( 130 ) arranged gaseous medium and a second Property and / or a second parameter of the in the cavity ( 130 ) arranged gaseous medium and / or at least one property and / or at least one parameter of the in the cavity ( 130 ) arranged gaseous medium and at least one property and / or at least one parameter of an environment of the circuit device ( 100 ) are evaluated to detect the disturbance-related change. Computer program adapted to perform all steps of a procedure ( 600 ) according to any one of claims 8 to 10 perform and / or to control.  Machine-readable storage medium with a computer program stored thereon according to claim 11.

Images