DE3012506C2 - Commutator motor with two commutators - Google Patents

Description

The invention relates to a commutator motor with two commutators on the shaft of the rotor according to the preamble of claim 1.

A commutator motor with two commutators on the shaft of the rotor is already known from CH-PS 3 29 880. The commutator motor contains a first rotor winding, the winding ends of which are connected to the first commutator, and also a second rotor winding, the winding ends of which are connected to the second commutator. The stator contains two stator windings and a switching device with the aid of which the two rotor windings can be connected in parallel to a voltage source, while the stator windings can be connected in parallel to one another to a voltage source when the commutator motor is operated at a low voltage. Furthermore, with the aid of the switching device, the two motor windings can be connected to a voltage source in series with one another and the stator windings can also be connected to a voltage source in series with one another, in which case the commutator motor is operated at a high voltage.

The basic circuit of a converter motor is known from the magazine "Bulletin Oerlikon", 1962 , pages 36 and 37 , in which two armature current branches of the motor can be switched from parallel to series together with the starting resistors in order to switch to two voltage ranges corresponding to 1500 V and 3000 V. However, the excitation circuit always remains unchanged and the excitation winding of the excitation circuit supplies the series excitation and the external excitation at the same time. The excitation winding is connected in series with the armature and the reversing pole windings, but it is not switched when switching to the two voltage ranges mentioned. The motor is connected as a shaft voltage motor and can absorb the full shaft voltage. The exciter in the external excitation circuit consists of a regulating machine which generates a rapidly increasing voltage when the speed only increases slightly and can thus keep the speed and thus the frequency almost constant.

Finally, from the "Siemens Magazine", 1941 , pages 44 to 45 , it is known to arrange two commutators on a rotor. However, a fundamental distinction is made between the windings of the commutator or the two windings on the rotor and the so-called main field winding, which corresponds to a stator winding and can be made up of two parts, whereby part of the main field winding can also be short-circuited. In this known design, the two motor windings can either be connected in series or can be connected in parallel, so that, for example, when driving at approximately half speed, the two motor windings are connected in series. In this case, part of the main field winding is switched off to weaken the motor field. With this known drive motor, it is also possible to switch from the series settings to the parallel settings without interrupting the circuits, since both motor windings or rotor windings are connected in a bridge circuit with one resistor group each.

The object underlying the invention is to provide a commutator motor with two commutators on the shaft of the rotor of the specified type, which can be easily manufactured and in which the magnetic core of the rotor can be made relatively small. can be made and thus the entire commutator motor can be made small and light in its dimensions, while on the other hand no sparking should occur during commutation.

This object is solved by the characterizing features of claim 1.

Since, according to the invention, the first rotor winding is located in the slot base and the second rotor winding is located in the outer region of the slots of the rotor, the second rotor winding can be wound into the slots of the rotor core after the first rotor winding has been completely wound. For this reason, no specially designed winding machine is required for winding the two windings and a conventional winding machine and a conventional winding method can also be used. The commutator motor according to the present invention can therefore be manufactured particularly easily.

Particularly advantageous embodiments and further developments of the invention emerge from the subclaims 2 to 4 .

In the following, the invention is explained in more detail using exemplary embodiments with reference to the drawing. It shows

Fig. 1 shows the circuit diagram of the windings of a conventional commutator motor for operation with two voltages, with (A) the supply being at low voltage and (B) the supply being at high voltage;

Fig. 2 shows a first embodiment of the commutator motor according to the invention;

Fig. 3A and 3B are circuit diagrams of the windings of the commutator motor of Fig. 2 when supplied with low and high voltage respectively; and

Fig. 4 shows the rotor of the commutator motor from Fig. 2 in side view at (A), in view from the left at (B) and in view from the right at (C);

Fig. 5 shows another embodiment of the engine in side view at (A), in view from the left at (B) and in view from the right at (C);

Fig. 6 shows a second embodiment of the commutator motor according to the invention;

Fig. 7A and 7B are circuit diagrams of the windings of the commutator motor of Fig. 6 when connected to low and high voltage respectively;

Fig. 8 is an axial longitudinal section through a fan equipped with the commutator motor according to the invention;

Fig. 9 is a plan view of the blower motor of the blower of Fig. 8;

Fig. 10 is an exploded section showing a brush holder of the motor of Fig. 8 to explain how the brushes are inserted; and

Fig. 11 is a plan view of a conventional blower motor comparable to that of Fig. 9.

A motor according to Fig. 1 is usually used for electrical appliances, for example vacuum cleaners, in which the motor must run very fast. When such an appliance is exported, it is sometimes necessary to switch the commutator motor to 110 V mains voltage via 220 V mains voltage, depending on the area to which the export is made. In conventional commutator motors, which can be used either for low or high voltages, the rotor has only one commutator and one rotor winding, while the stator is equipped with two stator windings. If such a commutator is used at the low voltage, the stator windings 1 and 2 are connected in parallel, as shown in Fig. 1A, with the rotor winding 3 then being connected in series with them. On the other hand, when the conventional commutator motor is operated on a higher voltage power source, as shown in Fig. 1B, the two stator windings 1 and 2 and the single rotor winding 3 are connected in series, and a three-terminal bidirectional thyristor 4 , such as a triac, is connected in series with the windings.

The reason for using such a thyristor 4 is as follows: when two stator windings 1 and 2 are connected in series, the power supplied to the commutator motor from the high voltage power source is too large. Therefore, the power supplied to the commutator motor must be controlled by the thyristor 4 so as to reduce the input power to the motor.

Furthermore, in a conventional commutator motor, when fed from the low voltage power source, the ratio of the ampere-turns (magnetic flux) of the two stator windings 1 and 2 to the magneto-flux of the rotor winding 3 is 1 or less, so that good commutation which suppresses sparking cannot be carried out. To overcome this defect, one could think of increasing the number of turns of the stator windings 1 and 2 or reducing the number of turns of the rotor winding 3. However, if the number of turns of the stator windings 1 and 2 is increased, the power supplied to the commutator motor at low voltage becomes too small. On the other hand, if the number of turns in the rotor winding 3 is reduced, the power absorbed by the commutator motor at high voltage is too large. Such a change in the number of turns is therefore not feasible.

In order to make the magnetic flux ratio equal to 1 or more, the number of turns in the rotor winding 3 has been generally reduced and the thickness of the rotor core has been increased, thereby preventing the power supplied to the commutator motor from becoming too large when a high voltage is applied. As a result, a conventional commutator motor which can be used selectively for two different voltages is inevitably large in size. In addition, because of the use of the thyristor 4 , the input wave is not sinusoidal, and therefore the magnetic noise of the motor is higher.

First, the first embodiment of the commutator motor with features according to the invention is considered in connection with Figs. 2 to 4. This commutator motor has a rotor 5 and a stator 6. The rotor core 8 is attached practically in the middle of the shaft 7 of the rotor 5. A first commutator 9 and a second commutator 10 are each attached to one side of the rotor core 8 on the rotor shaft. A first pair of brushes 11 and a second pair of brushes 12 are placed on the commutators 9 and 10 respectively. The rotor shaft 7 is supported by bearings 13 at both ends.

A first rotor winding 14 and a second rotor winding 15 are inserted into the slots of the laminated core 8. The winding ends 14 ' of the first rotor winding 14 are connected to the first commutator 9 , the winding ends 15 ' of the second rotor winding 15 are connected to the second commutator 10. A first stator winding 17 and a second stator winding 18 are arranged in parallel in the winding spaces of a stator laminated core 16. The representation of the stator windings 17 and 18 and their arrangement in the stator laminated core 16 is highly schematic in the asymmetrically drawn form. A switching device 19 has two movable switching arms, a first 20 and a second 21, which are locked against each other.

When the commutator motor is supplied with a low voltage, the switching arms 20 , 21 are in the position shown in solid lines in Fig. 2, with a first connection terminal 22 , which is firmly connected to the first switching arm 20 , being connected by the latter to a first changeover terminal 23 , while a second fixed connection terminal 24 , which is connected to the second switching arm 21 , being connected by the latter to a second changeover terminal 25. When the commutator motor is connected to a higher voltage, the switch connections shown in dashed lines apply, with the first fixed connection terminal 22 , which is connected to the changeover arm 20 , being connected by the latter to the changeover connection terminal 25 , while the second fixed connection terminal 24 is connected to the third changeover connection terminal 26 through the changeover arm 21 .

The first fixed connection terminal 22 is connected to one brush of the second brush set 12. The second fixed connection terminal 24 is connected to one pole of a voltage source 27 and to one end of the second stator winding 18. The first changeover connection terminal 23 is connected to the second pole of the voltage source 27 and to one end of the first stator winding 17. The second changeover connection terminal 25 is connected to a brush of the first brush set 11. The third changeover connection terminal 26 , on the other hand, is empty. The second end of the second stator winding 18 is directly connected to the second brush of the second brush set 12 , while the second end of the first stator winding 17 is connected to the second brush of the first brush set 11 .

Thus, when the switching device 19 with its switching arms 20 , 21 is in the solid position shown in Fig. 2, the switching connection according to Fig. 3A prevails, in which the first rotor and the first stator winding 14 and 17 on the one hand and the second rotor and the second stator winding 15 and 18 on the other hand are in series and these two series connections are connected in parallel. This switching state applies to supply with the low voltage value.

If the switching device is switched to the position shown in dashed lines in Fig. 2, the circuit diagram according to Fig. 3B applies, in which all the winding parts in the stator and rotor 4 , 15 , 17 and 18 are connected in series. Even if a voltage of twice the value of the low voltage is applied to the two ends of the series connection, the partial voltage on the individual windings 14 , 15 , 17 , 18 is not higher than that when the motor is supplied with the low voltage value. By switching the switching device 19 between the two possible switching positions, the speed can be changed when supplied with one and the same voltage, so that the commutator motor can also be used as a motor with two speeds. Next, the arrangement of the rotor windings 14 and 15 is considered using the illustrations in Fig. 4. First, the first rotor winding 14 is inserted into the lower portions of the slots of the rotor core 8 , and its ends 14 ' are connected to the segments of the first commutator 9 , respectively. Then, the second rotor winding 15 is inserted thereover into the upper portion of the slots, and then the respective coil ends 15 ' are connected to the corresponding segments of the second commutator 10. Since two rotor windings 14 and 15 are inserted into the lower and upper portions of the slots, respectively, the voltage difference between adjacent portions a and b of the upper winding coil or the lower winding coil is small, as shown in Fig. 4C, so that the withstand voltage characteristics in the individual portions of the motor are improved.

It is also possible to wind the first rotor winding 14 with a conventional coil winding machine and then wind the second rotor winding 15 with it, turning the rotor core 8 over. In this way, a conventional coil winding machine can be used to advantage, which favors the conditions for mass production. However, with this structure, there is a large voltage difference between the upper second rotor winding 15 and the lower first rotor winding 14 , so that an insulating paper interlayer should be inserted.

It should be noted here that when the rotor winding shown in Fig. 4 is used with the low voltage power source, the output power of the commutator is slightly reduced. The output power P of the commutator motor is given by the following equation:
P=k( ? ₁ I ₁ + ? ₂ I ₁ ) +k( ? ₁ I ₂ + ? ₂ I ₂ )
wherein
Φ ₁ is the magnetic flux generated by the first stator winding 17 ,
Φ ₂ is the magnetic flux generated by the second stator winding 18 ,
I ₁ is the current flowing through the first rotor winding 14 and
I ₂ is the current flowing through the second rotor winding 15 .

If the reactances of the first and second rotor windings 14 and 15 are taken into account, the reactance value for the first rotor winding 14 , which is located in the lower section of the slot of the rotor core 8 , is greater than the reactance value for the second rotor winding 15 , which is located in the upper slot section. Even if Φ ₁ and I ₁ are in phase and Φ ₂ and I ₂ are in phase, the phase positions of Φ ₂ and I ₁ or Φ ₁ and I ₂ do not match. In this case, the vector products Φ ₂ I ₁ and Φ ₁ I ₂ are smaller than when Φ ₂ and I ₁ or Φ ₁ and I ₂ are in phase. This means that the output power of the commutator motor is reduced.

Another possibility for the winding structure in the rotor, consisting of the rotor windings 14 and 15 , will now be described with reference to Fig. 5. The choice of reference symbols does not differ from that in Fig. 4.

When inserting the rotor winding into the slots of the rotor core 8 , two copper wires are always guided in parallel. The coil ends 14 ' of the first rotor winding 14 , which is formed by one of the copper wires, are connected to the first commutator 9. In the same way, the coil ends 15 ' of the second rotor winding 15 , which is formed by the other copper wire, are connected to the second commutator 10. Since two copper wires are introduced simultaneously into the slot which then forms the rotor windings 14 and 15 , the reactances for these two windings are practically the same, so that the magnetic flux Φ ₂ generated by the second stator winding 18 also has the same phase as the current I ₁ flowing in the first rotor winding 14 , while the magnetic flux Φ ₁ of the first stator winding 17 is in phase with the current I ₂ of the second rotor winding 15. Even when using this commutator motor, the maximum value is not reduced, but rather the maximum value can be taken.

The winding parts a and c made of the two copper wires are located close to each other, as shown in Fig. 5C, so that in the circuit according to Fig. 3B there is a large voltage difference between these winding sections. There is therefore a risk of short circuits if the insulation of the wires is damaged, so great care must be taken during manufacture.

The following description is directed to a second embodiment shown in Figs. 6 and 7, wherein the elements which do not differ from the parts in Figs. 2 and 3 bear the same reference numerals. The structure of the rotor 5 and stator 6 is as in the example in Fig. 2; there is a difference in the design and the connections of the switching device 28 .

The switching device 28 has four switching arms, a first switching arm 29 , a second switching arm 30 , a third switching arm 31 and a fourth switching arm 32. If the commutator motor is to be operated at a low voltage, the switch position shown in solid lines in Fig. 6 applies. A first fixed connection terminal 33 is connected to a first changeover terminal 34 through the first switching arm 29 ; a second fixed switch terminal 35 is connected to a second changeover terminal 36 through the second switching arm 30 ; a third fixed switch terminal 37 is connected to a third changeover terminal 38 through the third switching arm 31 ; a fourth fixed switch terminal 39 is connected to a fourth changeover terminal 40 through the fourth switching arm 32 .

If, however, the commutator motor is to be connected to a high voltage, the switch position is shown in dashed lines in Fig. 6. In this case, the first fixed switch terminal 33 is switched to an empty fifth switch terminal 41 by the first switch arm 29 , while the second fixed switch terminal 35 is connected to the first switch terminal 34 via the switch arm 30. The third fixed switch terminal 37 is connected to a sixth, empty switch terminal 42 via the third switch arm 31 , and the fourth fixed switch terminal 39 is connected to the third switch terminal 38 via the fourth switch arm 32 .

The first fixed switch terminal 33 is connected to a pole of the voltage source 27 to which a brush of the second brush pair 12 is also connected. The second fixed switch terminal 35 is connected to the other brush of the second brush pair 12. The third fixed switch terminal 37 is connected to the second pole of the voltage source 27 and also to one end of the second stator winding 18. The fourth fixed switch terminal 39 is connected to the other end of the second stator winding 18. The first changeover terminal 34 is connected to a brush of the first brush set 11. The second changeover terminal 36 is connected to one end of the first stator winding 17 as well as to the second brush of the first brush set 11 and also to the fourth changeover terminal 40. The third changeover terminal 38 is connected to the other end of the first stator winding 17. The fifth and sixth changeover terminals 41 and 42 are, as already mentioned, empty.

When the switching device 28 is in the solid position shown in Fig. 6, the two rotor windings 14 and 15 are parallel to each other, and the same applies to the two stator windings 17 and 18. These parallel circuits are then connected in series with each other, as shown in Fig. 7A. This circuit applies to supplying the commutator motor in the second embodiment from a voltage source with a low voltage value.

If the motor is to be operated from a voltage source with a high voltage value, the switching device 28 is switched to the position shown in dashed lines in Fig. 6. All windings of the rotor and stator are then in series as shown in Fig. 7B. The individual windings 14 , 15 , 17 and 18 therefore have the same partial voltage values when supplied with the high voltage as when supplied with the low voltage.

The following description concerns a fan driven by the commutator motor according to the invention and refers to Figs. 8 to 10.

An electrically driven fan 43 has a motor housing 44 made of sheet metal, which is produced by drawing. A bearing plate 45 with an enlarged diameter covers one opening side of the motor housing 44 and is fastened thereto with screws or the like. The shaft 7 of the rotor 5 is held in embossed central recesses of the bearing plate 45 and another bearing plate on the other side of the bearing housing 44 by ball bearings 13. The shaft 7 protrudes from the bearing plate 45 with one shaft end. A centrifugal fan wheel 46 is placed on the shaft end.

An air guide plate 47 is located between the fan wheel 46 and the bearing plate 45. The bearing plate 45 has a protruding edge flange 48 in the edge area, which overlaps the motor housing 44 at a radial distance. The opening of the fan housing 49 is placed over the edge flange 48. The fan housing 49 has an air inlet opening 50 in its center. Ventilation openings 51 and 52 are provided in the bearing plate 45 , through which the interior of the motor housing 44 is ventilated.

When the fan rotates, air is drawn in through the air inlet 50 and blown through the ventilation openings 51 into the motor housing 44 after passing around the guide plate 47 where the rotor 5 and stator 6 are then cooled before the air is discharged again from the ventilation openings 52 on the other side of the motor.

As already mentioned earlier, a pair of brushes 11 rests on the first commutator 9 , which is located at the rear end of the rotor 5 in the direction of air flow, while a further pair of brushes 12 rests on the second commutator 10 at the front end of the rotor 5. These brushes 11 and 12 are held and guided in brush holders 53 and 54 as in a conventional commutator motor and are pressed against the commutator by helical springs, which also serve as conductors, the brush holders 53 , 54 being formed by metal guide tubes which are inserted into insulating bodies. The motor housing 44 has holes 55 and 56 on its circumference into which the brush holders 53 , 54 are inserted. These holes 55 and 56 lie on a line parallel to the shaft 7 of the rotor 5 so that they can be fitted in the motor housing 44 by a single punching operation during manufacture of the motor. The bores 55 and 56 are located near the ends of the motor housing 44. Since the edge flange 48 of the bearing plate 45 extends over the front bores 56 , the insertion of the brush holders 54 is hindered by the edge flange. Recesses 57 are therefore provided where the edge flange 48 extends over the bore 56 .

Fig. 10 shows a top view of the motor before the fan housing 49 is fitted, with a brush holder 54 being inserted into the corresponding hole 56 through the recess 57 and then secured to the motor housing 44 by a screw 58 , so that a brush 12 of the second pair of brushes is then attached. The rear brush holders 53 are inserted into the holes 55 and then secured to the motor housing 44 by screws 59. When the fan housing 49 is then attached to the motor housing 44 after the front brush holders 54 have been inserted and secured, the recesses 57 are covered by the fan housing 49 and are therefore invisible. If the fan housing 49 is to be removed, an impact tool can easily be placed at the location of the recesses 57 in the edge flange 48 , which makes dismantling particularly easy during maintenance or repair work on the blower 43 . Fig. 9 shows that the width W ₂ of the recesses 57 is greater than the width W ₁ of the brush holders 54 , which facilitates the insertion of the brush holders 54 .

A top view of the housing of a conventional motor or fan is shown in Fig. 11. Since no recesses 57 are provided in the edge flange 48 of the bearing plate, the motor housing 44 must have a length L up to the edge flange 48 which enables the brush holders 54 to be inserted without interference.

In contrast, the total length of the motor in the embodiment according to Fig. 8 to 10 can be shortened by the distance l ₁ , the axial length of the bearing plate, which means a shortening of the total length of the fan.

The commutator motor designed in the manner according to the invention enables both the stator windings and the rotor windings to be connected either in parallel or in series, so that it can be operated at low and high voltage and has essentially the same output power and does not require a thyristor, as is the case with conventional motors. The magnetic core of the laminated core does not need to be particularly thick in the motor, and commutation takes place without sparks. The small laminated core thickness required allows the motor to be built small and light. If the first rotor winding is accommodated in the lower slot area and the second rotor winding in the upper slot area of the stator laminated core, the potential difference between adjacent coils is small, so that the risk of winding breakdown is not increased. Since the winding can also be inserted using conventional winding machines, the commutator motor is also suitable for mass production. Furthermore, two parallel wires can be wound simultaneously into the slots of the laminated core, so that the first and second rotor windings lie one inside the other, as it were, whereby they then have practically the same reactance values and the same maximum output power is available at the shaft for both types of circuit, so that the motor has a very good utilization factor.

The commutator motor according to the invention can be connected to an electric fan. A large diameter bearing plate can be attached to one end of the motor housing and the fan housing can be fitted onto the outer edge of the bearing plate. The outer edge of the bearing plate overlaps the motor housing at a radial distance. At diametrically opposite points, recesses are provided in the edge flange where the motor housing has holes on its circumference for inserting the commutator brushes, which are axially aligned with the holes for the commutator brushes at the other end of the motor housing. The recesses make it easier to insert the brush holders and, although the number of commutators is increased, it is not necessary to extend the motor housing. In addition, the recesses make it easier to remove the fan housing for repairs.

Claims (4)

1. Commutator motor with two commutators on the shaft of the rotor, a first rotor winding, the winding ends of which are connected to the first commutator, a second rotor winding, the winding ends of which are connected to the second commutator, further with a stator with two stator windings and a switching device by means of which two rotor windings can be connected in parallel to one another to a voltage source and the stator windings can be connected in parallel to one another to a voltage source when the commutator motor is operated at low voltage and by means of which the two rotor windings can be connected in series to one another to a voltage source and the stator windings can be connected in series to one another to a voltage source when the commutator motor is operated at high voltage, characterized in that a) the first rotor winding ( 14 ) is located in the slot base and the second rotor winding ( 15 ) is located in the outer region of the slots of the rotor ( 5 ), b) when the commutator motor is operated at low voltage, the parallel circuit of the two rotor windings ( 14 , 15 ) can be connected in series with the parallel circuit of the two stator windings ( 17 , 18 ) by the switching device ( 19 ; 28 ), and c) when the commutator motor is operated at high voltage, the series connection of the two rotor windings ( 14 , 15 ) can be connected in series with the series connection of the two stator windings ( 17 , 18 ) by the switching device ( 19 ; 28 ). 2. Commutator motor according to claim 1, characterized in that when the motor is operated at low voltage with the switching device ( 19 ), a rotor winding ( 14 ) and a stator winding ( 17 ) can be connected in series with one another and the second rotor winding ( 15 ) and the second stator winding ( 18 ) can also be connected in series with one another and the two series circuits can be connected in parallel with one another. 3. Commutator motor according to claim 1 or 2, characterized in that a commutator ( 9 , 10 ) is located on both sides of the rotor core ( 8 ). 4. Commutator motor according to claim 1, characterized in that at one end of a motor housing ( 44 ) a bearing plate ( 45 ) with a large diameter is attached, onto the edge flange ( 48 ) of which the housing ( 49 ) of a fan can be plugged, that the edge flange ( 48 ) overlaps the motor housing ( 44 ) at an axial distance, that recesses ( 57 ) are arranged diametrically opposite in the edge flange ( 48 ), that holes ( 56 ) aligned with these recesses ( 57 ) are provided in one end of the motor housing ( 44 ) and two further holes ( 55 ) are provided at the other end of the motor housing and that brush holders ( 53 , 54 ) for the brushes ( 11 , 12 ) of the commutator are inserted into the holes ( 55 , 56 ).