DE3901473A1 - Electrical apparatus - Google Patents

Abstract

In the case of an electrical apparatus having a printed circuit board which has conductor tracks, having an electrical resistor which has electrical connecting parts which are electrically conductively connected to the conductor tracks, and having a supply voltage source, for simply and cost-effectively increasing the operating reliability and the electrical and thermal load capacity, that connecting part which is connected to the positive terminal of the supply voltage source is larger than that connecting part which is connected to the negative terminal of the supply voltage source.

Description

The invention relates to an electrical device with a Printed circuit board, which has conductor tracks, with a electrical resistance, the electrical connectors has that is electrically conductive with the conductor tracks are connected and to a supply voltage source.

Such electrical devices can, for. B. flasher, Incandescent lamp control devices or clocks for motor vehicles be. The electrical resistances used there are often so-called measuring resistors for monitoring the proper functioning of circuits such. B. Turn signal lamps or incandescent lamp circuits in motor vehicles. The currents flowing in such circuits are comparatively large and are z. B. in the order of magnitude of several amps, the resistance values themselves are comparatively small to the voltage drop in the to keep the monitoring circuit as low as possible. Due to the high flowing currents, the heat load Such electrical resistances are comparatively large.

From DE-PS 29 04 197 is such an electrical Device known in which the electrical resistance from a Tape material is punched out. The electrical there Resistance is a so-called four-pole resistor trained in which the current to be monitored Circuit leading electrical connector parts wider are executed as the leading the measuring current Connecting parts. The leading the current to be monitored Connection parts are both of the same size.

The electrical device of DE-PS 29 04 197 has, however Disadvantage. Due to the equal training of the It is load current-carrying electrical connecting parts possible that the one with the positive pole of the  Supply voltage source connected connector due the higher thermal load there differs from the It separates the conductor tracks of the circuit boards because that Conductor tracks with the electrical connecting parts electrical conductive solder is melted and z. B. by Vibrations, especially in motor vehicles, from the Solder joint is removed. The increased temperature load of the with the positive pole of the supply voltage source connected connector opposite to that with the negative Pole of the supply voltage source connected connecting parts results from the fact that in addition to the Joulian heat, that in power conduction through an electrical resistor arises at the junctures between the electrical connecting parts and the conductor tracks or on the Connection points between the electrical connection parts and the solder of the solder joint or between the solder Solder joint and the electrical conductor tracks with the positive pole of the supply voltage source connected Connection part through the so-called Peltier heat is heated, whereas the same amount of Peltier heat the one with the negative pole of the supply voltage source connected connections cools. The emerging Peltier warmth is created by the so-called Peltier effect, which is always measurable when the electrical current passes through a transition point between different electrical conductive materials.

That is, through the equal training of the Connection parts of the known electrical device is the different temperature load of the electrical Connection parts due to the Peltier effect are not included worn so that the one with the positive pole of the Supply voltage source connected to the connector Conductor tracks are no longer connected if the with the negative pole of the supply voltage source connected Connection part still firmly with the conductor tracks electrically is conductively connected. Experiments have shown that with connected to the positive pole of the supply voltage source  Connection parts become approx. 60-100 ° C warmer than those with the negative pole of the supply voltage source connected Connection parts if the connection parts as in the prior art be made the same size.

The removal of the electrically conductive connection between the one with the positive pole of the supply voltage source connected connector and the corresponding conductor tracks can cause the electrical device to malfunction to the destruction of the electrical device or parts other connected circuits can lead. At a soldered connection, the solder can become liquid on the Circuit board of the electrical device wander around and close Short circuits and thus also malfunctions and Destruction of the electrical device.

The invention has for its object to an electrical device create that in a simple and inexpensive way reliable and highly electrically and thermally resilient is.

This problem is solved in that the one with the positive Pole of the supply voltage source connected connector is larger than the one with the negative pole Connection part connected to the supply voltage source.

The measure according to the invention is the one with positive pole of the supply voltage source connected Connection part thermally more resilient than that with the negative pole of the supply voltage source connected Connection part, so that the different heat loads the connecting parts is taken into account and thereby a premature disconnection of the electrical connections between the one with the positive pole Supply voltage source connected connector and the corresponding conductor track is avoided. Through this Measures will be easy and inexpensive device according to the invention more reliable and higher electrical  and thermally resilient than the previously known electrical Device.

The electrical device according to the invention has the advantage that with a solder connection between the electrical Connection parts and the conductor tracks not the solder joints more with different increased electrical Stress cases can become fluid. It follows from it can with the usual load cases there is no liquid solder in the control unit and short circuits or cause malfunction. The mechanical attachment the resistance on the circuit board is increased electrical load case more stable because it melts of the solder both solder joints remain fixed. The circuit board can may be designed smaller, because the one with the positive pole of the supply voltage source connected Connection part larger and the one with the negative pole Supply voltage source connected connecting part smaller can be trained. Because of the asymmetrical electrical connections of the connecting parts with the Conductor paths may be a cheaper conductor path on the circuit board of the electrical according to the invention Device possible.

Further advantageous refinements and developments of Subject of the invention emerge from the subclaims.

It is for the sake of saving space in the electrical device advantageous if the electrical resistance three has electrical connectors, one of which electrical connector with a first pole of Supply voltage source is connected and the others electrical connecting parts with the other pole of the Supply voltage source are connected. Through this Measure can be particularly useful when using the electrical resistance as measuring resistor, if necessary, two electrical load circuits are monitored.

An embodiment of the electrical according to the invention Device is shown in the drawings and is in the following explained with reference to the drawings. It shows

Fig. 1 shows an electrical device according to the invention in a first view and

Fig. 2 pivoted the same electrical device in a view through 90 ° to the viewer. In this Fig. 2, the electrical wiring of the consumer circuit is also shown schematically.

In Fig. 1, an electrical resistor ( 1 ) has two electrical connections ( 7 , 8 ). A circuit board ( 2 ) is provided with electrical conductor tracks ( 3 ) and openings or holes ( 4 ). The ends of the connecting parts ( 7 , 8 ) are inserted through the openings ( 4 ) in the printed circuit board ( 2 ). The ends of the electrical connection parts ( 7 , 8 ) are electrically conductively connected to the conductor tracks ( 3 ) of the printed circuit board ( 2 ) by soldering points ( 5 , 6 ).

The illustrated in Fig. 1 to the left electrical connection part (7) is electrically conductively connected to the positive pole of a supply voltage source, not shown in FIG. 1 via the solder joint (5) and the conductor tracks (3).

The illustrated in Fig. 1 to the right electrical connection part (8) is conductively connected via the soldering joint (6) and the conductor track (3) with a negative pole of a supply voltage source, not shown in FIG. 1. The connecting part ( 7 ) is larger than the connecting part ( 8 ).

In FIG. 2, the same or equivalent device parts as in FIG. 1 are provided with the same reference numerals. The electrical wiring of the electrical resistor ( 1 ), which is arranged as a measuring resistor in a load circuit, is also shown here. Thus, 2 is shown in FIG. Connected to the left side of the conductor track (3) via an electrical line to the positive pole of a supply voltage source (9) conducting, the negative pole of a electrical load (10), which is shown here as a light bulb, is electrically connected to the conductor track ( 3 ) shown on the right in FIG. 2. The electrical load current in this consumer circuit thus flows from the positive pole of the supply voltage source ( 9 ) via the conductor track ( 3 ) shown on the left in FIG. 2 and the solder joint ( 5 ), the electrical connection part ( 7 ), the electrical resistor ( 1 ), the electrical connection part ( 8 ), the solder joint ( 6 ), the electrical conductor track ( 3 ) in Fig. 2 on the right and the electrical consumer ( 10 ) to the negative pole of the supply voltage source.

In Fig. 2 it can be seen that the area of the solder joint ( 5 ) is designed to be substantially larger than the solder joint ( 6 ). In Figs. 1 and 2, the electrical resistance (1), which is stamped as a stamped part from a strip-shaped resistive material together with the electrical connecting parts (7, 8) integrally formed as a flat body. As a resistance material here z. B. a copper-nickel alloy can be used, which is particularly available under the trade name Constantan. These copper-nickel alloys have the advantage that their specific electrical resistance is comparatively little temperature-dependent. The conductor tracks can be designed as copper conductor tracks in order to keep the electrical resistance of the conductor tracks and thus the voltage losses on the conductor tracks low. The solder joints usually consist of a tin alloy, which is characterized by good flowability when heated and good adhesion both to the resistance material of the electrical resistor ( 1 ) and to the copper of the conductor tracks ( 3 ).

In the embodiment shown in FIGS. 1 and 2, there are thus two electrical transitions between different materials when the electrical current is conducted in the electrical device according to the invention. The first transition is the transition between the copper of the conductor track ( 3 ) and the tin alloy of the solder joint ( 5 ). The second transition is the transition between the tin alloy of the solder joint ( 5 ) and the copper-nickel alloy of the electrical resistance ( 1 ). The corresponding transitions can be found on the right-hand side in the figures of the connection points between the electrical resistor ( 1 ) and the printed circuit board ( 2 ). At all of the above-mentioned transitions, the so-called Peltier effect creates the Peltier heat, which loads or relieves the transitions mentioned in addition to the Joulschen heat generated by the electrical resistance. In the transitions in the figures between the left conductor track ( 3 ), the solder joint ( 5 ) and the electrical connection part ( 7 ), the transitions are additionally stressed by the Peltier heat in addition to the Joulian heat, so that the transitions mentioned also heat up. In the case of the conductor tracks ( 3 ) shown on the right in the figures, the solder joints ( 6 ) and the electrical connection part ( 8 ), which are connected to the negative supply voltage source, the corresponding amount of heat generated by the Peltier effect is subtracted from the Joulschen heat, so that the transitions there are less thermally stressed.

Due to the correspondingly larger design of the electrical connection part ( 7 ) and the solder joint ( 5 ), the larger amount of heat, which loads the transitions located there, due to the larger contact area between the electrical connection part ( 7 ), the solder joint ( 5 ) and in the figures, left-hand conductor tracks ( 3 ) are removed without melting the solder joint ( 5 ) as in the prior art and thus breaking the electrically conductive connection between the conductor track ( 3 ) and the electrical connecting part ( 7 ) and generating short-circuits liquid solder of the solder joint ( 5 ) and vagabonding of the solder on the printed circuit board ( 2 ) should be feared. According to the enlargement of the electrical connection part ( 7 ) which is connected to the positive pole of the supply voltage source ( 9 ) and the solder joint ( 5 ), the solder joint ( 6 ) and the electrical connection part ( 8 ) can be reduced accordingly, so that the electrical device does not takes up additional space. Due to the different sizes of the connection parts ( 7 , 8 ) or solder joints ( 5 , 6 ), space can possibly even be saved by correspondingly advantageous routing of the conductor tracks ( 3 ) on the circuit board ( 2 ).

The electrical device according to the invention is not manufacturing and more expensive than the previously known electrical device, so that with essentially cost-neutral means electrical device can be made more reliable and Can withstand higher thermal and electrical loads can be interpreted.

Claims (10)

1. Electrical device, with a printed circuit board which has conductor tracks, with an electrical resistor which has electrical connecting parts which are electrically conductively connected to the conductor tracks and with a supply voltage source, characterized in that with the positive pole of the supply voltage source ( 9 ) connected connector ( 7 ) is larger than the connector ( 8 ) connected to the negative pole of the supply voltage source ( 9 ). 2. Electrical device according to claim 1, characterized in that the electrical resistor ( 1 ) together with the electrical connecting parts ( 7 , 8 ) is integrally formed as a flat body. 3. Electrical device according to claim 2, characterized characterized in that the flat body as a stamped part a band-shaped resistance material is punched out. 4. Electrical device according to claim 3, characterized characterized in that the resistance material is a Copper-nickel alloy, especially constantan, is. 5. Electrical device according to claim 1, characterized in that the conductor tracks ( 3 ) are copper conductor tracks. 6. Electrical device according to claim 1, characterized in that the electrical connection parts ( 7 , 8 ) by solder joints ( 5 , 6 ) with the conductor tracks ( 3 ) are electrically conductively connected. 7. Electrical device according to claim 6, characterized in that the solder joints ( 5 , 6 ) have a tin alloy. 8. Electrical device according to claim 6, characterized in that the solder joint ( 5 ) connected to the positive pole of the supply voltage source ( 9 ) is larger than the solder joint ( 6 ) connected to the negative pole of the supply voltage source ( 9 ). 9. Electrical device according to claim 1, characterized in that the circuit board ( 2 ) has openings ( 4 ) through which the electrical connection parts ( 7 , 8 ) are inserted. 10. Electrical device according to claim 1, characterized in that the electrical resistor ( 1 ) has three electrical connecting parts.