This patent application is a national phase filing under section 371 of PCT/EP2019/058408, filed Apr. 3, 2019, which claims the priority of Chinese patent application 201810300480.1, filed Apr. 4, 2018, each of which is incorporated herein by reference in its entirety.
The invention concerns a thermal protection device to protect an electrical element against overheating, for example a varistor.
In electrical circuits it is important to protect threatened electrical elements against overheating. A varistor is such an electrical element. The varistor can change from an electrically insulating state to an electrically conductive state with a characteristic current-voltage behaviour. On the one hand, if an overvoltage is applied to an electrical circuit, the varistor can protect the electrical circuit. On the other hand, the varistor has to be protected in turn when the overvoltage persists and a high current flows through the varistor.
Embodiments provide a fast and reliable thermal protection device. Further embodiments provide a thermal protection device to protect a varistor in cases of overheating due to a persistently high voltage applied to the varistor over a certain time.
Embodiments relate to a thermal varistor protection device comprising a casing and a varistor which is embedded in the casing, wherein the varistor comprises a first metallization electrode, which is only partly covered by an insulating material of the casing to allow an electrically conductive connection to the first metallization electrode of the varistor. Furthermore the thermal varistor protection device comprises a first terminal wire that is electrically conductively connected to the first metallization electrode of the varistor. The thermal varistor protection device also comprises a contact element which is electrically conductively connected to the first metallization electrode of the varistor in a region where the varistor is not covered by the insulating material of the casing and wherein the contact element is pre-stressed to provide a fast separation of the contact element and the first metallization electrode if the electrical connection between the contact element and the first metallization electrode gets loose.
The varistor is protected against environmental influences and is largely electrically insulated as a result of being embedded by the insulating material of the casing. Therefore the varistor is protected against unwanted contact. Since the first metallization electrode is only partly embedded in the insulating material of the casing, an electrically conductive connection is possible. The pre-stressed contact element ensures a fast and secure separation of contact element and first metallization electrode. Therefore an improvement in the protection function is provided.
The pre-stress of the contact element can be caused by the contact element itself. In such a case the contact element would comprise an elastic part, which causes the pre-stress during an existent connection between the contact element and the first metallization electrode of the varistor.
Alternative the pre-stress can be caused by a separate element which is not part of the contact element. The separate element can be designed as a spring. The separate can be executed like a flat spring, a comprehension spring, an extension spring, a torsion spring, or the like.
If the pre-stress is caused by the contact element itself or by an elastic part of it, the thermal varistor protection device can be built in smaller dimensions, since no additional feature is needed to generate the pre-stress.
The electrically conductive connection between the first metallization electrode of the embedded varistor and the contact element can be realized as a low-temperature solder joint. Therein the low temperature would be a characteristic temperature at which the solder reaches a state where it would allow the pre-stress to interrupt the connection. The low temperature can be a characteristic temperature at which the solder becomes liquid.
A value of the characteristic temperature of the low-temperature solder can be in a range from 100° C. to 210° C. In a special embodiment the value of the characteristic temperature is 138° C.
By using such a low-temperature solder as described above, a thermally triggered interruption of a pre-stressed connection can be ensured. The triggering may be caused by a temperature increase of the varistor as well as by a high current which flows through the electrically conductive connection and heats it up. Both triggering mechanisms can be realized in the electrically conductive connection between the contact element and the first metallization electrode of the varistor, since the connection is close to the varistor and therefore shows a similar temperature behaviour, and the contact element and the connection are connected in series to the varistor and thus have the same current which flows through the varistor and which would heat up all the elements on the current path.
The casing can provide a feature to hold the contact element in place. If the pre-stress to the connection element is caused by a part of the connection element, it is possible to use the feature to build up the pre-stress. The feature can be designed in the form of a rivet. The feature can comprise more than one rivet.
Such a rivet can be part of the casing. In this case it would be possible to produce the rivet in one production step together with the casing itself. That would save production time and costs.
In one embodiment, if the electrically conductive connection between the first metallization electrode of the varistor and the contact element becomes loose, the pre-stress of the contact element pushes the contact element away from the region where the metallization electrode of the varistor is free from insulating material of the casing. The contact element can be pushed in a region where the metallization electrode of the varistor is covered by the insulating material of the casing. Thereby the contact element can get pushed against a wall of the casing by the pre-stress.
A local separation of contact element and metallization electrode can improve a save disconnection of those parts if the connection becomes loose. The separation by the pre-stress can lead to a fast separation, in addition. Here it is not important if the pre-stress is caused by a part of the contact element or by something else.
The first terminal wire can comprise a loop-like-shaped end which is electrically conductively connected to the first metallization electrode of the varistor. More specifically, the end can be shaped as an open loop or an open lug. This modification of the first terminal wire can increase a contact area between the first terminal wire and the metallization electrode of the varistor. As a result, the loop-like shape of the connected end of the first terminal wire can lead to an improved electrically conductive contact with higher stability and conductivity.
In one embodiment the contact element is a wire. Here the contact element can comprise an end which is electrically conductively connected to the metallization electrode of the varistor. For the same reasons as outlined above in view of an improved electrically conductive contact with higher stability and conductivity, it is possible to modify the connected end of the contact element, too.
The thermal varistor protection device can comprise a cap. The cap can be designed to be removably placed on the casing. Here the casing can define a cavity which is closed by the cap. Such a cavity would protect inner parts against environmental influences. The set of parts in the cavity can comprise the region on the metallization electrode of the varistor which is free from insulating material of the casing, a part of the contact element, the feature to hold the contact element, and the electrically conductive connection between the contact element and the metallization electrode of the varistor.
A general shape of the casing can be adjusted to the shape of the varistor. Therefore the casing can have a generally cuboid shape. An alteration of the casing can reduce the needed material to embed the varistor and therefore reduce costs.
The thermal varistor protection device can comprise a second terminal wire. The second terminal wire would be electrically conductively connected to a second metallization electrode of the varistor. Furthermore an arrangement of the second metallization electrode on the varistor at an opposite side to the first metallization electrode is possible.
In the Figures:
The schematic representation of
A terminal wire that is connected to the varistor 2 can comprise an open loop at the connected end. In
In cases of high voltage between the contact element 33 and the second terminal wire 32 the varistor 2 changes from an electrically insulating state to an electrically conductive state, and a high current flows through the varistor 2 and the connections at the varistor 2. If a high electrical current flows through a solder joint of a low-temperature solder, the solder gets heated up and becomes liquid. If the low-temperature solder in the connection between the metallization electrode 21 of the varistor 2 and the contact element 33 becomes liquid, the contact element 33 gets pushed away from the region 12 without insulating material 11 due to its inner pre-stress caused by the features 13 of the casing 10.
The invention described here is not restricted by the description provided in connection with the exemplary embodiments. Rather, the invention encompasses any novel feature and any combination of features, including in particular any combination of features in the claims, even if this feature or this combination is not itself explicitly indicated in the claims or exemplary embodiments.
Number | Date | Country | Kind |
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201810300480.1 | Apr 2018 | CN | national |
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PCT/EP2019/058408 | 4/3/2019 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2019/193055 | 10/10/2019 | WO | A |
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