FI71447B - ANORDINATION FOR OVERHEADING WITH ASYNCHRONOUS MOTOR WITH LIKSTROEMSBROMSNING - Google Patents

Description

1 71447

Device for monitoring an asynchronous motor during DC braking

The invention relates to a device for monitoring an asynchronous motor in direct current braking, the direct current being adapted to be supplied to the two poles of the motor after switching off the AC supply, and the braking time being adapted to be determined at the third pole of the motor in proportion to the induced rotor speed.

10 In previously known solutions, the braking time is based on preselection. The operation can be based on a certain time constant or on a so-called revolutionary basis. The disadvantage of all these known solutions is their complexity and high cost, as well as the fact that they do not take into account, for example, the variable speeds and masses of 15 machine tools, so that braking can be unnecessarily on in some situations. Examples of variable masses are centrifuges, mills, etc., the degree of filling of which can vary considerably.

Examples of previously known solutions are those described in DE-A-2,035,004, DE-A-1,148,320, U.S. Pat. No. 4,115,727 and U.S. Pat. No. 3,872,363. Em. the disadvantages of the solutions are their complexity and the fact that they can only be applied to certain engines.

The object of the invention is to provide a device which does not have the disadvantages of the above-mentioned known solutions.

The basic idea of the invention is to use the proportional motor rotation information generated automatically in DC braking, in which case expensive speed monitors and the like are not required.

Specifically, the device according to the invention is characterized in that the switch controlling the supply of alternating current, when opened, is adapted to close the switch for conducting a pulse to a monitoring circuit adapted to connect a floating voltage between the terminals by means of a switching circuit comprising a relay and a capacitor-5 connected in parallel with a diode having a suitable threshold voltage connected in series therewith and the monitoring circuit being adapted to close the DC supply control switch simultaneously adapted to connect the motor terminals its sul-10 boiled until the voltage between the connection point of the DC-supplied terminals and the third terminal is at the desired level.

The advantage of the method and device according to the invention is above all its simplicity and suitability for various motors. Namely, the motor can be, for example, a star, a triangle or a so-called Dahlander-connected and even equipped with multiple windings. Another advantage of the invention is its flexibility. The engine speed can be dropped to a constant speed or 20 complete stops, regardless of the masses and speeds. When exploiting the invention, the braking DC current can never be switched on unnecessarily, but only for as long as is necessary.

The invention will now be examined in more detail with reference to the accompanying drawing, which shows one embodiment of the invention.

In the solution of the drawing, the motor 1 is normally driven by the alternating current supplied to the terminals L1, L2 and L3 via the coil switch k1. At this point, switches k2 and k are naturally open. When using the engine, the above

In 30 ways, capacitor C2 is charged through resistors and R1 and diodes D2 and. As exemplary values for the components in the case shown in the drawing, the following values can be given, capacitor C2 0.47, F, resistors R3 10k.fl and Rf 56/1.

35 When entering the braking phase, the AC supply switch k ^ is opened, whereby the switch k is closed. The connection between switches 3 71447 and k is not indicated in the figure, but it can be implemented in several ways known per se. When the switch k is closed, the energy stored in the capacitor is discharged in the form of a pulse to the relay d 1, which drives. The relay d, j is adapted to cause the switch k-2 to be pulled (not shown in the drawing), whereby the direct current source is connected to the motor terminals and L 1. In this case, a direct current is supplied to the motor 1, which in a manner known per se results in the braking of the rotating rotor. The drawing illustrates precisely this step in which the switch k1 is open and the switches k and k2 are closed.

As the rotor rotates due to mass forces and at the same time braking as noted above, a voltage proportional to the rotation of the rotor is induced at the motor hub.

15 In this solution only the rms value of the voltage has been utilized, but a solution based on frequency monitoring is of course also possible.

Em. the voltage is monitored by the monitoring circuit T. In the solution of the example, the monitoring circuit is formed of resistors R.j and R2, relays d1, diodes, D4, and capacitor C.j, which are connected as shown in the drawing. As exemplary values for the components, the following values can again be mentioned: resistors R1 and R2 820.il and capacitor C.j 100 / O / F. The relay d 1 is, of course, in this pulled state at this stage due to the pulse discharged from the capacitor C 1. Em. the coupling senses a voltage proportional to the rotor speed obtained from, so it actually follows the rotation of the rotor. When the rotor stops, the voltage between the terminals and L · ^ at the connection point 2 and 30 is zero, whereby the relay d, and at the same time the switch k2 opens, whereby the DC power supply is disconnected from the terminals and L ^. After this, the motor can be restarted, for example, by closing switch k ^, whereby switch k opens at the same time.

35 In this connection, it should be noted that, of course, the motor does not need to be braked to a standstill, 4 71447, but braking can easily be carried out at a certain speed, after which the DC power supply to be braked is disconnected. This is due to the fact that the voltage induced at the hub is precisely dependent on the speed of rotor speed 5, whereby, for example, the relay d 1 is easy to react when the voltage has dropped to a predetermined value.

In the accompanying drawing, the so-called relay implementation, but the invention is not limited thereto. Within the framework defined by the claim, the corresponding function can be implemented e.g. electronically in several different ways. In this case, for example, the switches do not have to be so-called. coil switches but any known switches and similar components can be used.

Claims (1)

71447 Claim: Apparatus for monitoring an asynchronous motor in direct current braking, wherein the direct current is arranged to be supplied to the two poles (L2 / L3) of the motor (1) after switching off the alternating current supply, and the braking time is adapted to be determined at the third pole (L 1) monitoring the voltage induced by the rotor rotation in proportion to the rotor speed, characterized in that the switch (k1) controlling the supply of alternating current is adapted to close to switch the pulse to conduct a pulse to the monitoring circuit (T), which is adapted to connect the L ) through resistors (1 * 2, Rj) at point (2) and which monitoring circuit 15 (T) is adapted to monitor the voltage floating between the connection point (2) of the DC input terminals L3) and the third terminal (L ^) of the motor (1) by means of a relay (d 1) and a capacitor (C1) connected in parallel and in series with them 20 k a suitable threshold voltage diode (D 1) and that the monitoring circuit (T) is adapted to close the DC supply control switch (k2) »which is simultaneously adapted to connect the motor terminals (L 1, L 2) to the monitoring circuit (T) and hold it closed until the voltage 25 between the connection point (2) of the DC-supplied terminals (L2, L1) and the third terminal (L1) is at the desired level.