DE3410926A1 - Protection circuit arrangement for an electric motor - Google Patents

Abstract

A protection circuit arrangement for an electric motor which is supplied from a voltage source and whose rotation direction can be reversed and which has a manually operable polarity-reversal switch and a switching element, which interrupts an operating circuit in the event of the electric motor being overloaded, is intended to be constructed preferably for both rotation directions of the electric motor such that the electric motor can be driven in the one direction when it is blocked in the other direction and the switching element has triggered. This is achieved in that two switching elements are provided, of which the one can be short-circuited in the one polarity direction of the electric motor and the other in the other polarity direction of the electric motor. Both switching elements switch as a function of the current flowing through them and are not subject to the heat of the electric motor.

Description

Treasure circuit arrangement for an electric motor

The invention is based on a protective circuit arrangement for a from a SpanltlllCsque7lc 0 fed, direction of rotation reversible EJ.st.romotor with an actuatable reverse pole switch and with a switching element that switches off in the event of an overload of the electric motor interrupts an operating circuit.

Such protective circuit arrangements are used, for example, in motor vehicles for drives of various types for adjusting seats, window panes, sunroofs, etc. used. DC electric motors are usually used. Often is The switching element is a thermal switch that is connected in series with the electric motor and interrupts the operating circuit in both directions of rotation of the electric motor, if the engine heats up excessively because it hit a stop, without being switched off, or because the adjustment part jams for a long time or is stiff is. If the thermal switch has interrupted the circuit, it is also activated of the electric motor in the opposite direction is not possible until the thermal switch closed again.

The aim is therefore to keep the dwell time, i.e. the time that the motor can be blocked without being damaged and in which the thermal switch disconnects the electrical circuit does not interrupt to make long. However, this is relatively expensive tied together. It has also been shown that the holding times are made shorter and shorter must, the better and higher a motor is used.

The object of the invention is to provide a protective circuit arrangement with the Features from the preamble of claim 1 to further develop that also with short holding times of the switching element a high level of ease of use is possible.

This object is achieved in that in a protective circuit arrangement, which has the features from the preamble of claim 1, the switching element is only effective in one direction of rotation of the electric motor. Through this design the protective circuit arrangement, it is possible to turn the electric motor in one direction of rotation to start again, even if it had previously run in the other direction of rotation and was blocked and the switching element interrupted the circuit Has. It does not have to be the switch-back time of the switching element, that is the time that passes until the switching element returns to its initial state, waited will.

Advantageous refinements of the invention can be found in the subclaims remove. For bridging the switching element, there are embodiments according to the claims 2 to 4 preferred.

One switching element only for one direction of rotation of the electric motor is preferred primarily when there is a risk of the electric motor blocking is very low in the other direction of rotation. Can the electric motor turn in both directions are overloaded, it is advantageous if, according to claim 5, a second switching element is provided that can be bridged in the other polarity direction of the electric motor is. If you would then arrange both switching elements so that they are dependent on the heating of the electric motor switch, it could happen that with a Blocking of the electric motor in one direction of rotation, one or the other also open both switching elements. The electric motor can then under certain circumstances in the other direction of rotation cannot be controlled. Therefore switch according to claim 5 the two switching elements depending on the amount flowing through them Current.

This ensures that in one direction of rotation of the electric motor only one and in the other direction of rotation of the electric motor only the other switching element opens. If thermal switches are used as switching elements, the t5ber-1 Atstrom, which can be ten times the normal operating current, a warming in the thermal switch that is on it opens.

If the protective circuit arrangement is used in an adjustment device, when the electric motor is locked in one direction of rotation for some reason an early control of the electric motor in the reverse anyway Direction of rotation is not provided or desired, so the one switching element be exposed to the heat developed in the electric motor.

The claims 7 to 10 contain features that are advantageous Developments of the protective circuit arrangement with regard to the mutual arrangement of the two switching elements for the two directions of rotation of the electric motor.

Should the electric motor turn in one direction with another load are switched off than in the other direction of rotation, according to claim 11 the two switching elements are expediently designed for different loads.

Both switching elements can be integrated directly into the polarity reversal switch will. The size thus remains small and the additional expense compared to a protective circuit arrangement with only one switching element practically only refers to the one additional Switching element. In addition, there is also all the effort involved in protecting the electric motor less than with purely electronic solutions.

It can happen that because of the sluggishness of the adjustment part or because of the design of the electric motor this is not blocked, he but for a long time it draws a very high current that is not sufficient, to switch a switching element. The engine could then run for a long time Excessive heating of flowing, very high currents and damage. Therefore it is advantageous if, according to claim 14, in series with the electric motor there is a unbridgeable one Schal tel ement, preferably a thermal switch, which is in Depending on the heating of the electric motor switches.

Several exemplary embodiments of a protective circuit arrangement according to the invention are shown in the drawing. Based on the figures in this drawing, the e Invention will now be explained in more detail.

They show: FIG. 1 an embodiment in which one thermal switch in each case between two fixed contacts connected to the same pole of a voltage source of the polarity switch is, Fig. 2 shows an embodiment in which the parallel connection cines thermal switch and a diode in series for parallel connection of a second Thermal switch and a second diode, and Fig. 3 shows an embodiment in the the series connection of a diode and a thermal switch parallel to the series connection a second diode and a second thermal switch.

erxtT by permanent magnets For all circuit arrangements shown includes a direct current electric motor 10 with the two connections 11 and 12.

The electric motor 10 can be controlled via a polarity reversal switch 13, the has two movable contacts 14 and 15 coupled to one another, the middle one Have rest position and two lateral working positions. The contact 14 is permanent with a connection 16 and the contact 15 continuously with a connection 17 of the polarity switch tied together. The polarity reversal switch 13 also has four fixed contacts 18, 19, 20 and 21 on, of which the fixed contacts 18 and 19 with each other and with the positive pole 22 one Voltage source and fixed contacts 20 and 21 also with each other and are connected to the negative pole 23 of the voltage source. In one working position of the pole reversal switch 13, the movable contact 14 acts on the fixed contact 18 and the movable contact 15 the fixed contact 21.

In the other working position, the moving contact acts 14 the fixed contact 20 and the movable contact 15 the fixed contact 19. In the one The working position is therefore the connection 16 with the positive pole 22 and the connection 17 connected to the negative pole 23 of the voltage source. In the other working position it's the other way around.

In the embodiment according to FIG. 1, connection 17 is the polarity switch 13 directly to the connection 12 of the electric motor 10 and the connection 16 of the polarity switch via a switch 30, which will be discussed in more detail below, with the connection 11 of the electric motor 10 connected. Two are integrated into the polarity reversal switch 13 Thermal switches 31 and 32. The thermal switch 31 is located between the two fixed contacts 18 and 19 and is connected upstream of the fixed contact 18 with respect to the positive pole 22, the in the first working position of the pole reversal switch 13 from the movable contact 14 is applied. The thermal switch 32 is located between the two fixed contacts 20 and 21 and is connected upstream of the fixed contact 20 with respect to the negative pole 23, the in the second working position of the pole reversal switch 13 from the movable contact 14 is applied.

In the first working position of the pole reversal switch 13 there is thus Via the positive pole 22, the thermal switch 31, the fixed contact 18, the movable one Contact 14 and the connection 16 of the pole reversal switch 13, the switch 30, the electric motor 10, the connection 17, the movable contact 15 and the fixed contact 21 of the polarity switch 13 and the negative pole 23 of the voltage source form a closed circuit. The electric motor turns in one direction. If it is now blocked, a very high flow will flow Current which leads to the opening of the thermal switch 31 before the switch 30 opens. Then becomes the polarity switch brought into the second working position, this creates a closed circuit outside of the thermal switch 31 in which the thermal switch 32 is. The electric motor 10 can thus in the other direction of rotation can be controlled even if the thermal switch 31 is open. The holding time of the Thermal switches 31 and 32 can be selected very short, since regardless of whether one thermal switch is open or closed for the other direction of rotation of the electric motor can be closed via the other thermal switch can. Only the second thermal switch is relevant for the changed direction of rotation, through which only the operating current flows that does not trigger the switch. Only when the motor starts up against the second stop does the second also open Thermal switch. In the meantime, however, the first thermal switch has cooled down, so that a return is possible without interruption. When choosing the hold time the thermal switch 31 and 32 is only to ensure that the thermal switch do not trigger by the starting current of the electric motor.

A thermal switch 33 in polarity reversal switch 13 is shown in dashed lines in FIG. 1 indicated by which the thermal switch 32 could be replaced. The thermal switch 33 is in series with the thermal switch 31 between the two fixed contacts 18 and 19, but is connected upstream of the fixed contact 19 with respect to the positive pole 22. As the thermal switch 32 could of course also the thermal switch 31 by one of the Fixed contact 21 upstream thermal switch must be replaced.

In the embodiment according to FIG. 2, the Festkontaktel8 and 19 are as well the fixed contacts 20 and 21 of the polarity switch 13 are connected directly to one another. Man could therefore of course with a corresponding design of the movable contacts 14 and 15 combine each connected pair into a single fixed contact. The connection 17 of the pole reversal switch 13 is no longer directly connected to the connection 12 of the electric motor 10 vcr1vunden. Vielllle} lr lies in this Now connect the parallel circuit of the thermal switch 31 with a diode 35 in series with the parallel connection of the thermal switch 32 and a diode 36. The both diodes 35 and 36 are connected in opposite directions.

In the first working position of the pole reversal switch 13 there is a positive pole 22 the voltage source from a closed circuit via the fixed contact 18, the movable contact 14 and the terminal 16 of the pole reversal switch 13, the switch 30, the electric motor 10, the parallel connection of the thermal switch 32 and the diode 36, the thermal switch 31 and the terminal 17, the movable contact 15 and the Fixed contact 21 of the pole reversal switch 13 to the negative pole 23 of the voltage source. That I the current in the parallel connection. the thermal switch 32 and the diode 36 divides, The full current does not flow through the thermal switch 32 even in the event of an overload. this however, this is the case with thermal switch 31. In the event of an overload, the thermal switch therefore opens 31 in front of the thermal switch 32. This interrupts the circuit.

If the polarity switch 13 is now brought into the second working position, so the thermal switch 31, if it is still open, is bridged by the diode 35. The same applies to the thermal switch 32. Also in the embodiment according to FIG. 2, the thermal switches 31 and 32 and the diodes 35 and 36 can be in the polarity switch 13 be integrated.

The polarity reversal switch of the embodiment according to FIG. 3 corresponds to the polarity reversal switch according to FIG. 2. In contrast to the embodiment according to FIG. 2, however, it is now in the connection between the terminal 17 of the pole reversal switch 13 and the terminal 12 of the electric motor a series connection of the thermal switch 31 and the diode 36 in parallel with the series connection the thermal switch 32 and the diode 35. In one direction of rotation of the electric motor 10 therefore the current flows through the thermal switch 31 and the diode 36 and in the other direction of rotation through the thermal switch 32 and the diode 35, so that a closed circuit is possible in one direction of rotation is open even if the thermal switch assigned to the other direction of rotation is open Has.

In the embodiment according to FIG. 3, the full operating current only flows by a thermal switch while the other is de-energized.

It is therefore guaranteed in any case that if the electric motor in which one direction of rotation is blocked, the thermal switch assigned to this direction of rotation opens. In the embodiment according to FIG. 2, normally flows through both thermal switches a current, the current through one being less than that through the other. However, it is ensured in the embodiment of FIG. 2 that in normal operation no voltage drop across one of the diodes 35 and 36 occurs.

The switch 30 is also a thermal switch, which is located in the Located near the electric motor 10 and exposed to the heat developed in the motor is. It is essential mln that, in normal operation, the thermal switches 31 and 32 before Open thermal switch 30. It can now happen that the electric motor 10 over a longer period Time is kept in operation with a current that does not trigger any of the Thermal switch 31 and 32 leads, but over time it heats up the engine so much that that the engine can be damaged. In this case, the thermal switch opens beforehand 30th

The protective circuit arrangement according to the invention is with a Expenditure on costs and space requirements that are less than with electronic ones Solutions to get a high level of ease of use.

L e r s e i t e

Claims (14)

Protective circuit arrangement for an electric motor Patent claims: (i) Protection circuit arrangement for a reversible direction of rotation fed from a voltage source Electric motor (10) with an actuatable polarity reversal switch (13) and with a switching element (31,32), which interrupts an operating circuit when the electric motor (10) is overloaded, characterized in that the switching element (31, 32) only works in one direction of rotation of the electric motor (10) is effective. 2. Protection circuit arrangement according to claim 1, characterized in that that the switching element (31,32) by a parallel-connected flow valve, in particular a diode (35,36) can be bridged. 3. Protection circuit arrangement according to claim 1, characterized in that that the switching element (31,32) in the one working position of the polarity switch (13) is outside the operating circuit. 4. Protection circuit arrangement according to claim 3, characterized in that that the polarity reversal switch (13) has two fixed contacts connected to the same connection (22,23) (18,19,20,21) and that the switching element (31,32) between the one fixed contact (18.20) and the other fixed contact (19.21). 5. Protection circuit arrangement according to one of claims 1 to 4, characterized characterized in that a second switching element (31, 32) is provided which has an in the other direction of rotation of the electric motor (10) is effective, and that at least a switch learning jit switches depending on the current flowing through it. 6. Protection circuit arrangement according to claim 5, characterized in that that the second switching element (31,32) by a parallel connected flow valve, in particular a diode (35, 36) can be bridged. 7. Protection circuit arrangement according to claim 6, characterized in that that the parallel connection of a switching element (31) and a flow control valve (35) in series with the parallel connection of the other switching element (32) and the other flow control valve (36) lies. 8. Protection circuit arrangement according to claim 6, characterized in that that the series connection of a switching element (31) and a flow control valve (36) in parallel for series connection of the other switching element (32) and the other flow control valve (35) lies. 9. Protection circuit arrangement according to claim 5, characterized in that that the second switching element (31,32) is in the other working position of the pole switch (13) is outside the operating circuit. 10. Protection circuit arrangement according to claim 9, characterized in that that each switching element (31,32) is connected between two with the same terminal (22,23) Fixed contacts (18,19; 20,21) of the pole reversal switch (13) is located and that the one switching element (31) a fixed contact (18), which is in one working position of the pole switch (13) is acted upon, and the other switching element (32) a fixed contact (20) upstream is that in the other working position of the pole switch (13) is applied. 11. Protection circuit arrangement according to one of claims 5 to 10, characterized in that the two switching elements for different loads are designed. 12. Protection circuit arrangement according to one of the preceding claims, characterized in that at least one, preferably each bypassable switching element (31,32) is integrated into the polarity reversal switch (13). 13. Protection circuit arrangement according to one of the preceding claims, characterized in that at least one, preferably each bypassable switching element is a thermal switch (31,32). 14. Protection circuit arrangement according to one of the preceding claims, characterized in that in series with the electric motor (10) an unbridgeable Switching element (30), preferably a thermal switch (30), is dependent on from the heating of the electric motor (10) switches.