NL1027899C2 - Emergency protective circuit for preventing electric motor from switching on in event of power failure, has auxiliary switch formed by memory switch controlled semiconductor switch - Google Patents

Abstract

The circuit contains an auxiliary switch formed by a semiconductor switch (4) and controlled by a memory switch. A mains switch (2) which can be blocked is connected in series with the motor (1). The auxiliary switch is connected in series with the motor and mains switch. The memory switch memorizes whether the mains switch is on or off in order to control the auxiliary switch and comprises a relay (6) with its coil connected in series with an auxiliary contact (5) between the voltage source connections. An independent claim is also included for an electrical device with this circuit.

Description

% »

Device for preventing the unintentional switching on of a device after the supply voltage has ceased

The present invention relates to a device for preventing the unintentional switching on of a device provided with an electric motor and a lockable switch after the power supply has been cut out, comprising an electric motor, a lockable mains switch connected to the electric motor in series, and a switch with the electric motor and the mains switch in series connected auxiliary switch and a memory circuit for storing the position of the lockable mains switch and for controlling the auxiliary switch.

Such a device is generally known in devices which are provided with switch-on protection. Such a circuit serves as protection against unintentional switching on of a device after the mains voltage has been lost or if, for example, the plug of the device has been pulled out of the wall socket. If the mains voltage returns or the plug is plugged into the wall socket again, the device would start operating again in the absence of such a device, which may entail hazards or other undesirable consequences.

In the devices belonging to the state of the art, the auxiliary switch is designed as a relay. Although such a device with a relay functions well, the use of a relay has a number of disadvantages, including the high price and the large dimensions. These are caused by the fact that such a relay must be dimensioned for the inrush current of the electric motor, which is considerable, to a value of a few tens of Amps, also in the case of mains-fed motors.

The object of the present invention is to provide such a device wherein the drawbacks of a relay are avoided.

This object is achieved in that the auxiliary switch is formed by a semiconductor switch and the memory circuit is adapted to control the auxiliary switch.

30 1027899% 2

The cost price of semiconductor switches has fallen considerably in recent years, so that they are available at a lower cost price, also for the current intensities required in the present application. Another advantage lies in the smaller dimensions and the lower weight of the semiconductors in comparison with relays. Moreover, due to the absence of moving parts, the service life of semiconductor switches is longer.

According to a first preferred embodiment, the memory circuit comprises a detector for the position of the mains switch. This fulfills the actual memory function; the main switch is lockable so that it will maintain its position even when the mains voltage is lost. The detector transmits this position to the other parts of the memory circuit that uses this information to control the auxiliary contact. This detector can for instance be designed as a Hall element or as an optical detector. The detector can be placed at the location of the switch, but can also be placed at another location where the position of the switch can be observed, such as at the operating rod of the switch.

According to a specific embodiment, the detector comprises an auxiliary contact, the position of the auxiliary contact being opposite to that of the mains switch. This is a constructively simple and inexpensive embodiment of the detector.

20

A further preferred embodiment provides the measure that the memory circuit comprises a relay whose coil is connected in series with the auxiliary contact between the terminals of the voltage source and that the relay is connected to a holding circuit for maintaining its switched-on position at supply voltage.

Although a relay is used here, this relay does not have to switch large powers; it rather fulfills a logical function. Therefore, no high demands are placed on the relay, so that a small and inexpensive relay will suffice. 30

Attention is also drawn here to another aspect of applying a relay. Legislation in a number of countries requires a galvanic isolation between the electric motor and the power supply when the main switch is switched off. In the present application, the control circuit forms a connection between the power supply and the electric motor. In the event of a defect in the control circuit, it cannot be excluded that a galvanic connection will be created between the power supply and the electric motor. This would not satisfy these legal requirements. By applying a relay that meets legal requirements, such as a minimum contact distance, such a galvanic isolation does arise.

As an alternative to the use of a relay, use can be made of a memory circuit comprising electronic components, the memory circuit being switched for detecting the position of the auxiliary contact and for maintaining its position with the supply voltage present.

In this case it is possible to design the circuit as a whole in semiconductor technology, which not only avoids the disadvantages of relays but which moreover offers the advantage of applying a single technology.

15

Without further measures, such a circuit from electronic components does not form a galvanic separation between the supply side and the electric motor. This does not satisfy the legal requirements applicable in some countries, so that the application of such a device is limited to countries in which such requirements do not apply.

In order to be able to make use of this embodiment also in countries where this provision does apply, a preferred embodiment provides the measure that the connection between the memory circuit and the auxiliary switch comprises a galvanic isolation.

Such a galvanic separation can be carried out in a large number of ways, for example by means of a transformer. However, it is more attractive to use an optical path such as galvanic separation. After all, components designed as a semiconductor are available at a low kot price in which such an optical path is implemented.

According to a simple embodiment, the auxiliary switch is adapted to take up only one of the switched-on and the switched-off states. This is a 1027899

"I

4 auxiliary switch that can only take two discrete positions. The auxiliary switch designed as a semiconductor switch acts as a replacement for the relay; no functionality is added. Therefore, few requirements are imposed on the control, so that the circuit can be implemented at low costs.

An alternative embodiment provides the measure that the auxiliary switch is adapted to continuously control the power supplied to the motor between the switched-off and fully switched-on position and that a manually operable control knob is adapted to control the power supplied to the motor .

This embodiment provides additional functionality, namely a control function. Compared to the above-mentioned discrete version, this provides extra functionality.

Compared to devices which also belong to the state of the art with a continuous controllability of the power supplied to the electric motor, the difference lies in the double use of the electronic switching elements required for this purpose, namely not only as a control element for the electric motor. power, but also as a switching element.

20

In a number of applications, such as a jigsaw, it is common for the power adjustment button to be separate from the switch for turning the motor on and off. In other applications, such as in a drilling machine, it is attractive that the control knob is integral with an operating element of the main switch.

The invention relates not only to a device or circuit in which the measures according to the invention are implemented, but also to an electrical device which is provided with a device according to one of the preceding claims. 30

Such a device is preferably formed by an electric hand tool.

Next, the present invention will be elucidated with reference to the accompanying drawings, in which: 1027899 »5

Figure 1: a circuit diagram of a first embodiment of the present invention; and

Figure 2; a circuit diagram of a second embodiment of the present invention.

Figure 1 shows a circuit diagram which is provided with an electric motor 1, a main switch 2 and a connection 3 for a supply voltage. The supply voltage will generally be formed by a mains voltage, that is to say an alternating voltage. The connection is then formed by a plug. The motor 3 can be switched on and off by means of the main switch 2. The main switch 2 can be locked in its switched-on position. Such a circuit is used with, for example, an electric tool, wherein control of the power supplied to the electric motor is less important, for example with a circular sawing machine.

In order to prevent unintentional reconnection after, for example, unintentional disconnection of the plug from the wall socket or the return of the mains voltage after a malfunction, the circuit is provided with means against reconnection. For this purpose the circuit comprises an auxiliary switch 4 which is placed between the electric motor and the main switch. According to the invention this auxiliary switch is formed by a semiconductor switch, for example by a triac. However, other types of semiconductor switches are not excluded. For controlling this auxiliary switch 4, a memory circuit is provided, which is formed by an auxiliary contact 5 placed on the main switch 2 and a relay 6. The position of the auxiliary contact is opposite to that of the main contact of the main switch 2. The coil 7 of the relay 6 is connected in series with the auxiliary contact 5 and the power supply connection 3. A first contact 8 of the relay 6 is connected to a holding circuit for holding the switched-on position of the relay 6. The second contact 9 of the relay 6 is connected to the semiconductor switch 4. Instead of the auxiliary contact shown, type detector, such as a Hall detector or an optical detector.

1027899 4 t 6

The operation of the above circuit will now be described. In a normal situation the user will plug the plug 3 into a wall socket. Because the auxiliary contact 5 functions opposite to the main contact of the main switch, the auxiliary contact 5 will be closed, so that when the supply voltage 5 is applied the relay 6 is energized. Due to the hold circuit of the relay 6, this relay will remain energized, also when the auxiliary contact 5 of the main switch 2 is opened. His second contact 9 remains closed by the energized relay 6. The electronic auxiliary switch 4 is hereby released. When the main switch is switched on, the current will flow through the main switch and the conductive auxiliary switch, so that the motor 1 will start running. The user can then carry out his work with the tools. When the main switch 2 is switched off, the motor 1 is stopped. The relay 6, however, remains energized by the hold circuit, so that the motor 1 can be switched on again.

15

The reactivation function of the invention is expressed in a situation in which the supply voltage has been lost, either due to a power failure or due to the plug 3 being unintentionally pulled out of the wall socket. In such a situation the switch 2 is locked in the switched-on position. The auxiliary contact 5 is therefore open. When the supply voltage fails, the relay 6 will fail.

However, switching on the supply voltage does not lead to the relay 6 being energized because the auxiliary switch 5 is open. As a result, the auxiliary switch 4 remains open and the motor 1 will not start running.

This blocked position can be canceled by unlocking the main switch 2. This switches off the main contact. However, the auxiliary contact 5 is switched on so that the relay 6 is energized again and the auxiliary switch 4 is released. Operating the main switch 2 again means that motor 1 will start running again. The latter, however, only takes place after the user 30 has intervened. In this way an unsafe situation as a result of the motor 1 turning without intervention of the user is prevented.

The invention uses a semiconductor element 4 as an auxiliary contact. Although this is not shown in the drawing, this semiconductor element can also be used as a regulator for the power to be supplied to the electric motor. A control circuit must therefore be added for this purpose.

7

Figure 2 shows a similar circuit that differs from the circuit shown in Figure 1 in that the relay 6 is replaced by a semiconductor circuit 10. This semiconductor circuit 10 can be provided with logic gates and memory elements such as flip-flops, but it can also be implemented in the form of a microprocessor.

In principle, it is of course possible for this semiconductor circuit to be directly connected to the auxiliary switch 4 in the form of a semiconductor. can turn with the main switch switched off.

15

To prevent this problem, a non-galvanic connection between the control circuit 10 and the auxiliary switch 4 is used. This may be in the form of an optical connection 11. The optical transmitter and receiver required for this are readily available, even in a single component.

20

In this embodiment too, the auxiliary switch provided with electronic switching elements such as triacs can be used to control the power supplied to the motor. For this purpose, an adjustable resistor 12 is added in Figure 2. This arrangement naturally requires further components. These components may be included in the auxiliary switch 4. In such a situation it is conceivable that the auxiliary switch also requires connection with "13" in the figure in order to function. However, this depends on the circuit used.

It will be clear that various changes can be made to the exemplary embodiments shown; measures of both embodiments can thus be combined.

1027899

Claims (12)

Device for preventing the unintentional activation of a device provided with an electric motor and a lockable switch after the supply voltage has been lost, comprising: - an electric motor; - a lockable mains switch connected in series with the electric motor; - an auxiliary switch connected in series with the electric motor and the mains switch; and - a memory circuit for storing the position of the lockable mains switch and for controlling the auxiliary switch, characterized in that the auxiliary switch is formed by a semiconductor switch and that the memory circuit is adapted to control the auxiliary switch. Device according to claim 1, characterized in that the memory circuit comprises a detector for the position of the mains switch. 3. Device as claimed in claim 2, characterized in that the detector comprises an auxiliary contact, wherein the position of the auxiliary contact is opposite to that of the mains switch. 4. Device as claimed in claim 3, characterized in that the memory circuit comprises a relay whose coil is connected in series with the auxiliary contact between the terminals of the voltage source, and that the relay is connected in a holding circuit for maintaining at supply voltage from its engaged position. 5. Device as claimed in claim 2, characterized in that the memory circuit comprises electronic components, that the memory circuit is switched for detecting the position of the main switch and for maintaining its position 30 with the supply voltage present. Device according to claim 5, characterized in that the connection between the memory circuit and the auxiliary switch comprises a galvanic isolation. 1027899 • « Device according to claim 6, characterized in that the non-contact path is formed by an optical path. 8. Device as claimed in any of the foregoing claims, characterized in that the auxiliary switch is adapted to take up only one of the switched-on and the switched-off condition. 9. Device as claimed in any of the claims 1-7, characterized in that the auxiliary switch is adapted to continuously control the power supplied to the motor between the switched-off and fully-switched-on position and that a manually operable control knob is arranged for controlling the power supplied to the motor. 10. Device as claimed in claim 9, characterized in that the control button is integral with an operating element of the main switch. Electric device, characterized in that the device is provided with a device according to one of the preceding claims. Electric device according to claim 11, characterized in that the device is formed by an electric hand tool. 1027899