DE3631298A1 - Reversible pole three-phase motor for underground operation, especially a squirrel-cage rotor motor - Google Patents

Abstract

In the case of a reversible pole three-phase motor for underground operation, especially a squirrel-cage rotor motor having two three-phase stator windings which are connected to each alternating current phase of the driving three-phase current by means of in each case one electrically controlled switching device, remotely controllable, electromagnetic switching devices being provided for DC isolation of the wires of the motor supply lead carrying the alternating currents of each phase, it is provided according to the invention that thyristors (20 to 29) are used as electrically controlled switching devices of the two stator windings (12, 17). These thyristors (20 to 29) are installed in the motor housing (2) together with their controller (30, 31). A motor supply lead (5) having three single-phase alternating-current wires (I1 to I3) is also provided, which wires are connected by means of the remotely controllable, electromagnetic switches (contactor) (16 to 18) to the single-phase alternating currents (L1 to L3) of the driving three-phase current (15) and, in the motor housing (5), are connected by means of a wire (I1) to in each case one stator terminal (20, 21) of a stator winding, and by means of the two other wires (I2, I3) to in each case two stator terminals (22 to 25), which are provided with a thyristor (26 to 29), of each stator winding (Figure 2). <IMAGE>

Description

The invention relates to a pole-changing Three-phase motor according to underground operation the preamble of claim 1.

These electrical machines are used for Power transmission preferred in most drives wise stationary underground machines, including what removable equipment such as planers and cutters plants with their sponsors and feasible Machines are understood to be conveyors tapes or mining machines in mining or used in tunneling. In particular The invention relates to squirrel cage motors which mainly because of their simple and robust Rotor structure and its commutatorless circuit are preferred to slip ring motors. The squirrel cage motors are for the underground operation particularly suitable in the with ignitable Gas mixtures must be expected. That applies in special dimensions for hard coal mining. It is essential that the motor cable, which with particularly isolated and mostly with Protective conductors provided cables will and the engine with the stationary, however after the dismantling of the driving line AC connects, switched off can be what a galvanic isolation assumes.  

In underground operation, pole-changing devices become Motors used in which the three-phase Stator winding as slow speed and the other three-phase stator winding as high-speed Motors is used. Let it this way on the motor side e.g. to start a Low speed conveyor serving Speed and another, for the duration intended operation, operating at higher speed Realize engine speed. The in general mean in drives of the designated machines necessary gears and clutches can be used simplify. For example complicated and difficult to automate manual transmissions become superfluous. Often it is necessary, but at least desirable, that Switch the rotor in both directions of rotation to be able to. That should be in at least one, in the But usually be possible in both speed levels. E.g. you need the reverse run of a moveable Chen conveyor with low engine speed to Move conveyor belts or chain belts together. Reversible machines, e.g. Planing systems, requ on the other hand, both rotations in both directions payment levels. The invention is applicable to them pole-changing motors.

The invention is based on a known type pole-changing three-phase motors of the underground operating out. Here is each of the two three-phase stator windings over its own Motor supply lines to the electrically controlled  Switching devices connected. These switching devices are as so-called shooters, so are as electromagnetic circuit breakers designed, which due to the complete galvanic isolation the necessary between control and contact circuit Disconnection of the motor supply lines is possible lichen.

On the one hand, it is disadvantageous that the Breakers due to their through the six Stand clamps predetermined number of times need space, difficult underground can be made available. The housing must be based on the respectively prescribed Degree of protection is usually very difficult become what with the large number of electro magnetic switches to considerable overall weights of such a switchgear leads. Another disadvantage is that it is considerable Number of design-related wear caused by the electromagnetic switching elements, as well as the one thereon based high installation effort.

In addition, it is disadvantageous that each pol switchable three-phase motor two motor cables needed. These lines are not only expensive playful, they are also difficult to accommodate and  safe to lay, especially when it comes to Trailing cable, which is a planer or Conveyor belt drive pulls behind. In particular the operational safety thereby suffers of such a pole-changing three-phase motor.

The invention has for its object a pole-changing three-phase motor of the underground to create operations, which with reduced Weight a reduced space requirement and one has greater operational reliability, the However, the supply line can be switched voltage-free.

According to the invention, this object is achieved with the Features of claim 1 solved. Purpose are moderate embodiments of the invention Subject of the subclaims.

The new motor switches both stator windings with thyristors, including their Gate controls in or on the motor housing are grown and from a common motor line with the alternating currents of the driving Three-phase current. That’s it possible, remote controlled, electromagnetic Switching devices only in this motor cable to provide for their electrical isolation. As a result, both the number is reduced the contactor as well as that of the motor cables the half. This is made possible by the inventor  circuit according to the invention, in which is in the engine branch the chamfers so that over the Gate control of the thyristors the stator terminals one or the other stator winding can be switched.

The invention has the pole changing for use stable three-phase motors underground Advantage that the external, i.e. the outside of the motor housing arranged installations are significantly reduced in scope. The requires less space for the switchgear, reduces their weight and avoids difficult with multiple parallel cables Motor leads are connected. Consequently wear and installation costs are reduced. In addition, the invention has the advantages of Thyristors versus electromagnetic switches. With these flow valves in the invent circuit according to the invention in both stator windings Speed control of the motor via the gate Enable control of the thyristors.

Preferably and with the features of the patent Claim 2 can be the demand for rotation Change of direction in the new engine bill wear.  

The invention is shown in the drawings. Show it

Fig. 1, left side view and right in front view of a squirrel cage induction motor of the downhole operation according to the invention,

Fig. 2 shows a first embodiment of the invention, wherein only the circuit is shown,

Fig. 3 shows a second embodiment of the invention in Fig. 2 corresponding representation and

Fig. 4 is a circuit diagram of the embodiment of FIG. 3.

The cage rotor motor shown in FIG. 1, generally designated ( 1 ), has a cylindrical motor housing ( 2 ) with a flange ring ( 3 ) and a supply box ( 4 ) for a motor supply line ( 5 ) with a flexible, externally insulated cable. The cage rotor ( 6 ) is led out of the housing with its shaft ( 7 ) at ( 8 ).

On or in the housing ( 2 ) behind the box ( 4 ) is a schematically represented circuit ( 9 ). The parts of this circuit are identified in FIG. 2 by a dash-dotted line, while it is indicated in FIG. 3 by a dashed line.

The cable ( 5 ) connects the circuit ( 9 ) to a switching device ( 10 ), which is shown in particular in the representations of FIGS. 2 and 3.

According to the illustration of FIG. 2 is a two-speed motor with two dreifasigen stator windings (12 and 14). The three alternating currents of the driving three-phase current ( 15 ) are denoted by (L 1 , L 2 and L 3 ). One contactor ( 16 to 18 ) each of the motor control unit ( 10 ) enables electrical isolation of the three others carrying the alternating currents ( I 1 to I 3 ). The remote control of the contactors ( 16 to 18 ) is indicated at ( 19 ).

Of the total of six motor terminals, the motor terminals ( 20 and 21 ) of the stator windings ( 12 and 14 ) are permanently connected to the chamfer ( L 1 ) in the circuit diagram according to FIG. 2. Each of the two further stator terminals (22, 23) of the stator winding (12, 14 or 24, 25) via in each case a thyristor (26 to 29) to a respective branching of the veins (I 2 and I 3, and L 2 or L 3 ) of the driving three-phase current. The gate controls ( 30 and 31 ) can be switched remotely via a control line ( 32 ).

As can be seen from the illustration in FIG. 3, four thyristors ( A 1 to A 4 and B 1 to B 4 ) are provided for each of the two (W 1 and W 2 ) three-phase stator windings; the gate control of these thyristors is shown broken off. In the illustration of Fig. 3, the stator winding of the slow gear is reproduced (W 1) with its three stator terminals at (A 1 to A 3). The stator winding ( B 2 ) of the overdrive also has three stator terminals ( B 1 to B 3 ). Each stator terminal has a current branch, in each of which a thyristor is installed.

When the slow gear is switched on, the three-phase stator winding ( W 1 ) is switched on accordingly. If a clockwise rotation is required, the control unit ignites the gates of the thyristors ( A 1 and A 4 ), as a result of which the currents (IA 1 , IA 4 and IA 3 ) can flow. For a reversal of direction of rotation (counterclockwise rotation), the thyristors ( A 2 and A 3 ) are ignited accordingly, so that the currents (IA 2 , IA 3 and I 3 ) flow.

If the overdrive is switched on, the thyristor group labeled (B) is ignited by the control. Depending on the required direction of rotation, either the thyristors ( B 4 and B 1 ) or the thyristors ( B 2 and B 3 ) become conductive.

As shown, the designated thyristors are in anti-parallel connection and can both positive and negative half waves conduct currents.

Becomes the phase entry control of the thyristors controlled, a speed control is possible, the in addition to switching the motor on and off is.

Claims (3)

1. pole-changing three-phase motor of underground operation, in particular squirrel-cage motor with two three-phase stator windings, which are connected to each alternating current of the driving three-phase current, each with an electrically controlled switching element, remotely actuable electromagnetic switching elements being provided for the electrical isolation of the cores of the motor supply line carrying the alternating currents, characterized,
that serve as electrically controlled switching elements of the two stator windings ( 12 , 17 ) thyristors ( 20 to 29 ), which are installed together with their controller ( 30 , 31 ) in the motor housing ( 2 ), and
that a motor lead ( 5 ) with three AC wires ( I 1 to I 3 ) is provided, which with the remotely operable, electromagnetic switches (contactor) ( 16 to 18 ) to the AC currents ( L 1 to L 3 ) of the driving three-phase current ( 15 ) are connected and in the motor housing ( 5 ) with one wire ( I 1 ) to each stator terminal ( 20 , 21 ) of a stator winding and with the other two wires ( I 2 , I 3 ) to two each with a thyristor ( 26 to 29 ) provided stator terminals ( 22 to 25 ) of each stator winding. 2. pole-changing three-phase motor according to claim 1, characterized in that the thyristor-controlled stator terminals ( A 1 to A 3 ; B 1 to B 3 ) have a thyristor pair arranged in a current branch ( A 1 to A 4 ; B 1 to B 4 ) and the Thyristors are anti connected in parallel, the gate controls assigned to a stator winding ( W 1 , W 2 ) each having a thyristor of a stator terminal ( A 1 to A 3 ; B 1 to B 2 ) being switchable together to reverse the direction of rotation. 3. pole-changing three-phase motor according to one of claims 1 or 2, characterized in that on or in the motor housing with the thyristors ( 26 to 29 ; A 1 to A 4 ; B 1 to B 4 ) equipped control ( 9 ) is housed.