EP4059130A1 - Mechanical device for converting direct current into alternating current - Google Patents

Abstract

The invention relates to a mechanical device (3) for converting direct current into three-phase alternating current for driving a dynamoelectric rotating machine, said device comprising: at least one contact unit having at least two receiving regions (12, 13) for receiving electrical energy in the form of direct current and having at least three output regions (9, 10, 11) for outputting electrical energy in the form of alternating current, a first receiving region being designed for contacting a positive terminal of a direct current feed, a second receiving region being designed for contacting a negative terminal of a direct current feed, a first output region being designed to provide a first alternating current, a second output region being designed to provide a second alternating current, a third output region being designed to provide a third alternating current; and at least one contacting unit for receiving the direct current and/or for outputting the alternating current. The invention further relates to a dynamoelectric rotating machine having a device of this kind.

Description

description

MECHANICAL DEVICE FOR THE CONVERSION OF DIRECT CURRENT INTO ALTERNATING CURRENT

The invention relates to a mechanical device for the conversion of direct current into three-phase alternating current for driving a dynamo-electric rotary machine.

The invention also relates to a dynamoelectric rotary machine with such a mechanical Vorrich device.

DC voltage networks are enjoying increasing popularity in industrial networks. A power supply with direct current offers enormous savings potential and is particularly suitable for drives in production. In vehicles, robots, exoskeletons and other battery networks, only one direct voltage is usually available.

In order to be able to operate a dynamo-electric rotary machine with a multiphase stator winding in a direct voltage network, also referred to as a DC network, electronic circuits are used which generate a multiphase alternating voltage from a direct voltage. This enables a multi-strand winding of the dynamo-electric rotary machine to be fed. Such electronic circuits are particularly complex and lossy.

Since such electronic circuits also have a certain complexity, the invention is based on the object of reducing the complexity in the conversion of direct current into three-phase alternating current for driving a dynamo-electric rotary machine.

The object is achieved by claim 1, ie a mechanical device for converting direct current into three-phase alternating current for driving a dynamo-electric rotatory machine, having at least one contact Unit with at least two receiving areas for receiving electrical energy, in the form of direct current and with at least three output areas for delivering electrical energy in the form of alternating current, a first receiving area being designed to contact a positive pole of a DC power supply, with a second receiving area for Contacting a negative pole of a direct current feed is formed, a first output area being designed to provide a first alternating current, a second output area being designed to provide a second alternating current, a third output area being designed to provide a third alternating current, and at least one Contacting unit for receiving the direct current and / or for delivering the alternating current.

Furthermore, the object is achieved by a dynamoelek tric rotary machine with such a mechanical device.

A dynamo-electric rotary machine has a rotor and a stator. The invention can be used both for permanently excited or electrically excited synchronous machines and for reluctance machines.

Further advantageous designs emerge from the subclaims.

In an advantageous embodiment of the invention, the contact unit can be plugged onto a shaft of a dynamo-electric rotary machine.

This offers the advantage that an existing dynamo-electrical rotary machine with a multi-strand, in particular three-strand, stator winding can be used, since the mechanical device is designed to be plugged onto the shaft in a simple manner. In a further advantageous embodiment of the invention, the mechanical device is designed as a hollow cylinder.

This has the advantage that, on the one hand, the mechanical device can be designed to be plugged onto the shaft and, on the other hand, can be adapted to the dimensions of the dynamo-electric rotary machine.

In a further advantageous embodiment of the invention, the first and / or the second receiving area lies on at least one sliding track arranged at least essentially concentrically around a center point.

This is advantageous because the consumption of electrical energy is associated with a rotation of the rotor.

In a further advantageous embodiment of the invention, the first and / or the second and / or the third dispensing area lies on at least one sliding track arranged at least essentially concentrically around the center point.

This is advantageous because the output of electrical energy is associated with a rotation of the rotor.

In a further advantageous embodiment of the invention, the contact unit is designed as a disk.

This sometimes offers the advantage of a compact design of the dynamo-electric rotary machine.

In a further advantageous embodiment of the invention, the first delivery area lies on a first sliding path, the second delivery area lies on a second sliding path and the third delivery area lies on a third sliding path.

In a further advantageous embodiment of the invention, the first and the second receiving area lie on exactly one fourth sliding track, the first receiving area being a nem first section of the fourth sliding track, wherein the second receiving area lies on a second section of the fourth sliding track.

The sections, in particular a section size, are advantageously dependent on a number of poles p of the machine. The following can be specified as an example: = 120 ° / p

The device described is preferably designed as a sliding contact switch.

In a further advantageous embodiment of the invention, the contacting unit is designed for connection to the shaft of the dynamoelectric rotary machine and has at least three contacting elements, a first contacting element following the first sliding path when the shaft rotates, such that the first contacting element connects the first delivery area alternately with the first receiving area and with the second receiving area, a second contacting element following the rotation of the shaft following the second sliding path, such that the second contacting element alternates with the first receiving area and with the connects the second receiving area, wherein a third contacting element is designed following the rotation of the shaft of the third sliding track, in such a way that the third contacting element alternates between the third delivery area and the first receiving area area and connects to the second recording area.

This has the advantage that, through this embodiment, the direct voltage is controlled by a rotor position and is switched to the multi-strand stator winding at a fixed angle via the contacting elements.

For example, for an angle _mech between two strands with a number of strands m: _mech = oi _ei / p, where _ei = 360 ° / m A number of sections 2-p is exemplary.

In a further advantageous embodiment of the invention, the first receiving area lies on a first receiving grinding path, the first receiving grinding path being arranged on an outer circumference of the contact unit designed as a hollow cylinder, the second receiving area lying on a second receiving grinding path, the second receiving grinding path on the outer circumference the contact unit is arranged.

This is advantageous because the consumption of electrical energy is associated with a rotation of the rotor.

In a further advantageous embodiment of the invention, the first delivery area and the second delivery area and the third delivery area are arranged on exactly one delivery grinding track, the delivery grinding track being arranged on the outer circumference of the contact unit designed as a hollow cylinder, the first delivery area lying on the first section of the delivery grinding track wherein the second dispensing area lies on a second portion of the dispensing abrasive web, where the third dispensing area lies on a third portion of the dispensing abrasive web.

For example, the sections have 120 ° electrical. Advantageously there are 3-p sections in scope.

Such a design is particularly suitable for a Re luctance machine.

For this purpose, the rotor is constructed as a reluctance rotor and thus has different magnetic conductance values in the d and q axes.

The direct current is preferably transmitted via stationary brushes to a commutator fastened on or on the rotor. There the current is preferably over in the correct position Transfer brushes to the stator winding. As a result, the machine does not require any rotor position sensors.

This has the advantage that a reluctance machine can be operated directly on direct current networks. A machine with a robust rotor structure, compact dimensions and an affordable price can thus be operated directly on a direct current network.

The reluctance machine has no windings on the rotor and preferably comprises stamped metal sheets. This results in fewer losses on the rotor. The reluctance machine has a lower inertia and it is inexpensive. The robust design also enables applications in the high temperature range, e.g. with fans for smoke gas ventilation or fresh air overpressure in the event of a fire. In these applications in particular, battery-buffered DC networks are preferred. Dispensing with converters on the one hand and position sensors in the machine on the other hand are particularly advantageous in such applications.

In a further advantageous embodiment of the invention, the first output area is on a first output sanding track and the second output area is on a second output sanding track and the third output area is on a third output sanding track, the first output sanding track and the second output sanding track and the third output sanding track on the outer circumference of the designed as a hollow cylinder contact unit are designed.

In a further advantageous embodiment of the invention, the first delivery area is divided into a plurality of delivery area sections, the second delivery area being divided into the plurality of delivery area sections, the third delivery area being divided into the plurality of delivery area sections.

In a further advantageous embodiment of the invention, the majority of the delivery area sections correspond to one Number of poles of a stator winding of the dynamo-electric rotary machine, a first delivery area section being connected to the first receiving area, an adjacent second delivery area section being connected to the second receiving area.

The mechanical device described in this embodiment preferably includes at least one sliding contact for each phase and at least one sliding contact for each pole of the DC voltage, so in a machine with three-phase stator winding at least five sliding contacts, preferably designed as brushes.

The sliding contacts are preferably designed as stationary brushes and the mechanical device rotates with the rotor when the rotor rotates. The fixed brushes are pressed onto the assigned receiving or output grinding paths with pretension, so that the flow of current is optimally guaranteed.

In this embodiment, the mechanical device is preferably designed to be rotatable or adjustable in relation to the stator winding and / or in relation to the rotor, so that the phases are supplied with current for optimum rotor position. The position of the fixed brushes and the arrangement of the sliding tracks determine the optimum current feed into the multiphase stator winding. For example, with a three-phase stator winding, the current is fed in with an electrical offset of 120 ° C.

The invention offers the advantage that the use of direct current machines can be dispensed with. As a result, good heat dissipation of the rotor and thus of the machine can be achieved, whereas in DC machines the winding is located in the rotating machine part and the rotor can therefore be cooled more poorly. The invention also made light a higher speed stability than with direct current machines. In the following, the invention is described and explained in more detail with reference to the exemplary embodiments shown in the figures. Show it:

1 shows a dynamo-electric rotary machine, FIG. 2 shows a first embodiment of the mechanical device,

3 shows a result of the conversion of direct current into three-phase alternating current,

FIG 4 shows another embodiment of the mechanical Vorrich device,

FIG 5 shows another embodiment of the mechanical Vorrich device,

FIG. 6 shows an embodiment of an internal interconnection of the embodiment of the mechanical device shown in FIG. 5,

7 shows a device for suppressing brush fires at high current loads,

8 shows the device from FIG. 7 in a different perspective.

1 shows a dynamo-electric rotary machine in the form of a motor.

The multi-strand motor 1 is coupled to the mechanical device 3 according to the invention. The mechanical device 3 in FIG. 1 is a sliding contact switch which is fed with direct current from the DC supply 5. In FIG. 1, both the motor 1 and the sliding contact switch 3 are coupled to a shaft 2.

FIG. 2 shows a first embodiment of the mechanical device 3.

FIG. 2 shows the mechanical device 3 designed as a disk or contact disk. The mechanical device 3 is suitable for fixing on a stator of a dynamo-electric rotary machine. The mechanical device 3 is designed as a contact disk in FIG. 2, a contact disk being an embodiment of a hollow cylinder.

The mechanical device 3 has a first delivery area 9, a second delivery area 10 and a third delivery area 11. In FIG. 2, the first delivery area 9 is designed as a sliding path for a first phase LI, the second delivery area 10 as a sliding path for a second phase L2 and the third delivery area 11 as a sliding path for a third phase L3.

Furthermore, the mechanical device 3 in FIG. 2 comprises a first receiving area 12 and a second receiving area 13. The two receiving areas 12 and 13 lie on exactly one sliding path which at least partially follows a circular path arranged concentrically around a center point M.

The first receiving area 12 is designed for contacting a positive pole of a DC supply. The second receiving area 13 is designed for contacting a negative pole of a DC supply.

The sliding tracks 9, 10, 11 at least partially follow a circular track arranged concentrically around a center point M.

FIG. 2 shows that the contact disk 7 is coupled to the shaft 2. The contact disk 7 is preferably firmly connected to the stator.

FIG. 2 also shows a connecting element 92, a connecting element 102 and a connecting element 112.

A contacting element 91 is connected to the connecting element 92. A contacting element 92 is connected to the binding element 102 connected. A contacting element 111 is connected to the connecting element 112.

By means of the connecting elements 92, 102 and 112, the con tacting elements 91, 101 and 111 can be connected to the shaft 2.

When the shaft 2 rotates, z. B. the contacting element 91 the delivery area 9 with the receiving area 13 and later the delivery area 9 with the receiving area 12. In other words: the contacting element 91 connects the sliding track for LI to the negative pole and later the sliding track for LI to the positive pole.

The same applies: The contacting element 101 connects the sliding track for L2 with the negative pole and later the sliding track for L2 with the positive pole. The contacting element 111 connects the sliding track for L3 with the negative pole and later the sliding track for L3 with the positive pole.

The length of the receiving areas 12 and 13 on the sliding track is selected so that a three-phase alternating current is formed.

A multi-strand stator winding can be fed by means of the mechanical device 3, a sliding contact switch.

The connecting elements are preferably designed as brushes, in particular special carbon brushes.

As already explained, the contacts 91, 101 and 111 are connected to the shaft 2 via the connecting element and thus to the Ro tor.

If the receiving areas 12 and 13 are contacted with direct voltage, a position of the rotor controls which output area can provide which current. A delivery area can be designed as a contact ring. A receiving area can be designed as a commutation ring.

FIG. 3 shows a result of the conversion of direct current into three-phase alternating current. FIG. 3 shows how a three-strand winding of a dynamo-electric rotary machine can be fed by the mechanical device 3, based on a direct current feed.

3 shows the supply of the three strands LI, L2 and L3, with A indicating one revolution in a two-pole motor.

The figure shows that the positive current ranges of the individual strings are phase-shifted by 120 ° C., as is usual with a three-phase alternating current.

FIG. 4 shows a further embodiment of the mechanical device 3.

FIG. 4 shows a commutator with sliding contacts 8 which can be plugged onto a shaft. The mechanical device 3 is designed as a hollow cylinder. The mechanical device 3 has a first receiving area for contacting a positive pole of a direct current feed 12 and a second receiving area for contacting a negative pole of a direct current feed 13.

In FIG. 4, the first receiving area at a front axial end V of the hollow cylinder is designed as a path running around an outer circumference of the hollow cylinder. In FIG. 4, the second receiving area at a rear axial end H of the hollow cylinder is designed as a path running around the outer circumference of the hollow cylinder.

4 also shows three delivery areas 9, 10 and 11, wel che by 60 ° C mechanically (60 ° mechanically corresponds to 180 ° elec trically) are arranged offset on the circumference. The delivery areas 9 and 10 are advantageously verbun with DC +, the delivery area 11 with DC-.

FIG. 4 shows that each receiving area and each dispensing area can be contacted via a contact 20 and a spring 30. The first receiving area 12 and the second receiving area 13 are connected to the spei send DC system via contact 20 and spring 30. This is shown in FIG. 4 with DC + and DC-.

The three output areas 9, 10 and 11 can be contacted via spring 30 and contact 20 with phases LI, L2 and L3, which represent the power supply of the motor.

FIG. 4 shows a mechanical device 3 which is suitable for a three-strand dynamo-electric rotary machine with six poles.

FIG. 5 shows a further embodiment of the mechanical device 3.

The mechanical device 3 is designed as a hollow cylinder and can be coupled to a shaft of a dynamic rotary machine by means of the shaft adapter 41. The mechanical cal device 3 should not be rotatably mounted when coupled to a shaft. FIG. 5 shows an insulator 40. Furthermore, FIG. 5 shows a first receiving area 12, a second receiving area 13 and three delivery areas 9, 10 and 11.

FIG. 5 shows that each receiving area and each dispensing area can be contacted via a contact 20 and a spring 30. The first receiving area 12 and the second receiving area 13 are connected to the spei send DC system via contact 20 and spring 30. This is shown in FIG. 5 with DC + and DC-. FIG. 5 shows a mechanical device 3 which is suitable for a three-strand dynamo-electric rotary machine with six poles.

The first delivery area 9 is divided into a plurality of delivery area sections in the figure. The second delivery area 10 is divided into the same plurality of delivery area sections. The third delivery area 11 is divided into the same plurality of delivery area sections.

The number of delivery area sections preferably corresponds to the number of poles of a stator winding of the dynamo-electric rotary machine, a first delivery area section 9A being connected to the first receiving area 12, an adjacent second delivery area section 9B being connected to the second receiving area 13. This is described in more detail in FIG.

FIG. 6 shows an embodiment of an internal interconnection of the embodiment of the mechanical device shown in FIG.

The first delivery area section 9A is connected to the first receiving area 12, and the adjacent second delivery area section 9B is connected to the second receiving area 13. Another adjacent third delivery area section 9C is also connected to the second receiving area 13.

A delivery area section 9D is connected to the first receiving area 12 in the figure. This system can be transferred to the other two sliding tracks.

FIG. 7 shows a device for suppressing brush fires when there is a high current load.

The mechanical device described in the previous figures in various embodiments can develop brush fire at high current load. Such brush fire he should be largely suppressed. FIG. 7 shows an insulating body 50 and sliding tracks 53, 52 and 51 as well as a direction of movement R. FIG. 7 shows a brush bridge 55 which has free-wheeling diodes D for suppressing brush fire. The figure also shows contacts K, which are coupled to DC + or DC- or LI, L2 or L3.

This has the advantage that brush fires, which for example lead to high wear, are suppressed. The freewheeling diodes D, which are arranged in the brush bridge, allow freewheeling currents to be diverted without causing sparks.

FIG. 8 shows the device from FIG. 7 in a different perspective, so to speak in a rolled-out perspective.

8 shows the sliding tracks 53, 52 and 51, the brush bridge 55 and the freewheeling diodes D for suppressing brush fire. The figure shows the stator winding in star connection 54 and an arrangement of the contacts K1 ... K4.

The device is suitable for a six-pole, three-phase machine.

Claims

Claims

1. Mechanical device (3) for converting direct current into three-phase alternating current for driving a dynamoelectric rotary machine's rule, having

- At least one contact unit with at least two receiving areas (12, 13) for receiving electrical energy in the form of direct current and with at least three Abgabebe range (9, 10, 11) for delivering electrical energy in the form of alternating current, with a first receiving area for Contacting a positive pole of a direct current feed is formed, wherein a second receiving area is designed for contacting a negative pole of a direct current feed, wherein a first output area is designed to provide a first alternating current, wherein a second output area is designed to provide a second alternating current, a third output area for Providing a third alternating current is formed, and

- At least one contacting unit for receiving the direct current and / or for delivering the alternating current, the contact unit being attachable to a shaft (2) of a dynamo-electric rotary machine.

2. Mechanical device (3) according to claim 1, wherein the contact unit is designed as a hollow cylinder.

3. Mechanical device (3) according to one of claims 1 to

2, wherein the first and / or the second receiving area (12, 13) lies on at least one sliding path arranged at least essentially concentrically around a center point (M).

4. Mechanical device (3) according to one of claims 1 to

3, wherein the first and / or the second and / or the third delivery area (9, 10, 11) on at least one at least in Essentially concentrically around the center (M) arranged grinding path lies.

5. Mechanical device (3) according to one of claims 1 to

4, the contact unit being designed as a disk.

6. Mechanical device (3) according to one of claims 1 to

5, wherein the first delivery area (9) lies on a first sliding path, the second delivery area (10) lying on a second sliding path, the third Abgabebe rich (11) lying on a third sliding path.

7. Mechanical device (3) according to claim 6, wherein the first and the second receiving area lie on exactly one fourth sliding path, the first receiving area lies on a first section of the fourth sliding path, the second receiving area on a second section of the fourth sliding path lies.

8. Mechanical device (3) according to one of claims 6 or 7, wherein the contacting unit is formed for connection to the shaft of the dynamoelectric rotary machine, the contacting unit having at least three contacting elements, a first contacting element upon rotation of the shaft of the first sliding track is executed in such a way that the first contacting element connects the first delivery area alternately with the first receiving area and with the second receiving area, wherein a second contacting element is designed following the rotation of the shaft of the second sliding track, such that the second contacting element the second Abgabeebe rich alternately connects with the first receiving area and with the second receiving area, wherein a third contacting element is designed to follow the shaft of the third sliding track when the shaft rotates, such that the third contacting element the third Abgabebe- rich alternately connects with the first receiving area and with the second receiving area.

9. Mechanical device (3) according to one of claims 2 to 4, wherein the first receiving area is on a first receiving grinding track, wherein the first receiving grinding track is arranged on egg NEM outer circumference of the contact unit formed as a hollow cylinder, the second receiving area on a second Receiving grinding path lies, wherein the second receiving grinding path is arranged on the outer circumference of the contact unit.

10. Mechanical device (3) according to one of claims 2 to 4 or 9, wherein the first dispensing area and the second dispensing area and the third dispensing area lie on exactly one output grinding path, wherein the output grinding path is arranged on the outer circumference of the contact unit designed as a hollow cylinder, wherein the first dispensing area lies on a first portion of the dispensing abrasive path, the second dispensing area lies on a second portion of the dispensing abrasive path, the third dispensing area lying on a third portion of the Ab supplying abrasive path.

11. Mechanical device (3) according to one of claims 2 to 4 or 9, wherein the first delivery area on a first delivery grinding path and the second delivery area on a second delivery grinding path and the third delivery area on a third delivery grinding path, wherein the first Abga grinding path and the The second output grinding path and the third output grinding path are arranged on the outer circumference of the contact unit, which is designed as a hollow cylinder.

12. The mechanical device (3) according to claim 11, wherein the first delivery area is divided into a plurality of delivery area sections, the second delivery area being divided into the plurality of delivery area sections, wherein the third delivery area is divided into the plurality of delivery area sections.

13. Mechanical device (3) according to claim 12, wherein the plurality of delivery area sections corresponds to a number of poles of a stator winding of the dynamo-electric rotary machine, a first delivery area section being connected to the first receiving area, an adjacent second delivery area section being connected to the second receiving area connected is.

14. Dynamoelectric rotary machine having a mechanical device (3) according to one of claims 1 to 13.