EP3959802A1 - Electric machine - Google Patents

Abstract

The invention relates to an electric machine comprising a stator (2) having a winding (3), and at least one temperature sensor arrangement comprising a temperature sensor (19) for detecting the temperature in the region of the winding. The ends (7, 7a) of at least one part of the conductor (4) protrude from the winding (3). One part of said ends (7, 7a) is connected to an axial or radial interconnection ring (8) placed on the winding (3). The temperature sensor arrangement (16) is arranged on a conductor (15) and the temperature sensor is thermally coupled to at least one conductor (15).

Description

Electric machine

The invention relates to an electrical machine comprising a stator with a winding, and at least one temperature sensor arrangement comprising a temperature sensor for detecting the temperature in the area of the winding.

Electrical machines include a rotor and a stator and are used in different areas of application. The use of electrical machines for electric hybrid vehicles and electric vehicles or for hub drives is only mentioned as an example. If such an electrical machine is used as a drive machine, it is mostly designed as an internal rotor, which means that the stator surrounds the internal rotor. A wandering magnetic field is generated via the stator, which causes the rotor to rotate. For this purpose, the stator has a winding consisting of a large number of conductors, the conductors being assigned to one or usually several phases. The winding is guided around the stator teeth in a manner known per se.

Not only the number of phases goes into the design of the winding geometry, but also the number of wires per phase as well as the number of wires per slot within the stator toothing and the number of pole pairs. This variety of conductors and winding parameters creates a complex network of conductors that is built up using different winding technologies. Examples include the so-called hairpin or bar wave winding. Here, the conductors are formed by means of rods bent in a U-shape, which are put together to form a winding basket. The conductors are laid on a plurality of radial levels, with the conductors moving from level to level. You are to form quasi mäanderförmi ger, circumferential conductor at their ends to be connected accordingly, which is usually done by welding the conductor ends that are adjacent to each other. The conductor ends converge at one point or one winding side in the form of a so-called star, where they are connected to one another. In this area, the connection of the individual phases to an external power supply is also supply, i.e. a power connection that is used to generate the magnetic field.

During the operation of the electrical machine, the temperature of individual components must be monitored, for which purpose appropriate temperature sensors, e.g. PTC or NTC sensors can be used. One area in which the temperature is to be detected is that of the winding, since one of the hottest points of the stator of the electrical machine prevails in the area of the winding, where a temperature sensor can be installed. The hottest point of the stator is namely in the hairpin or rod wave winding area, precisely in the axial center of the Blechpa kets. However, since this point cannot be reached in order to integrate a temperature sensor, the outer area of the winding is selected. For this purpose, the temperature sensor is installed inside the stator, which means that it usually has to be installed at an early stage in the manufacturing process. In order to capture the temperature in the winding area as precisely as possible, it is desirable to attach the temperature sensor as close as possible to or on the winding or winding head, since media flows in the interior, such as water, air, oil, etc., can affect the temperature measurement and therefore with The measurement becomes imprecise as the distance between the temperature sensor and the winding or winding head increases.

The arrangement of the temperature sensor, in particular on a particularly tightly wound or compactly wound winding, such as a hairpin or a rod-shaped winding, is particularly complicated.

The invention is based on the problem of specifying a comparatively improved electrical cal machine.

To solve this problem, the invention provides for an electrical machine of the type mentioned at the outset that the ends of at least some of the conductors protrude beyond the winding, some of these ends being connected to an interconnection ring placed axially or radially on the winding, the Temperature sensor arrangement arranged on a conductor and the temperature sensor is thermally coupled to the conductor. In the electrical machine according to the invention, the temperature sensor arrangement is independent of a connection ring on a conductor, in the usual form egg ner busbar or a busbar, either between the connection ring and line electronics or on a so-called special wire. This is a conductor that is not designed like all common hairpins, geometrically and from the position. The temperature sensor can be designed, for example, as a PTC or NTC measuring sensor, which is in thermal contact with the conductor. This enables direct temperature detection on such a conductor or conductor rail, through which current flows and therefore heats up during operation, and thus in the immediate winding area, whereby the radial and axial position of the temperature sensor arrangement and thus the temperature sensor itself are reliable by fixing the temperature sensor arrangement on the conductor itself and is given with reproducible accuracy. By integrating the temperature measurement directly on this conductor, usually a copper conductor or a copper bar, an optimal heat transfer is achieved, so that undesired error influences and measured value deviations are reliably avoided. In addition, it is possible in the manner according to the invention to make the tempe temperature detection not only in a radially or axially outer edge region of the stator winding, which is subjected to a different operating temperature due to the increased heat dissipation than a current conductor, on which the measurement is now directly according to the invention .

The temperature sensor arrangement itself expediently has a housing in which the temperature sensor is received and through which the conductor stretches. The housing, which is placed on the conductor, serves to encapsulate the temperature sensor on the one hand, but also the measuring point on the other, so that very good protection against external influences that have a detrimental effect on the measurement, such as media flows of water, oil, air, etc. can advantageously be avoided and a very precise measurement is possible.

The housing itself expediently has a carrier on which the temperature sensor is fixed, and a cover which can be releasably fastened to the carrier and closes the housing. The housing is thus in two parts, so that it can easily be opened the conductor, which reaches through the housing, can be placed on or placed around the conductor. The cover is expediently attached to the carrier via a latching or clamping connection, which enables a very simple connection or simple closing of the housing. In addition to simple assembly, the latching or clamping connection also enables very simple dismantling in the event of maintenance or repair work, that is to say that the temperature sensor arrangement can easily be replaced even if necessary.

The temperature sensor itself is preferably arranged on a sensor carrier which has a form-fit contour or onto which a shrink tube having a form-fit contour is drawn, a counter-contour receiving the form-fit contour being provided on the carrier. This corresponding contouring of the sensor carrier or shrink tube and carrier enables the sensor carrier or the temperature sensor to be arranged in a reproducible, precise position on the carrier, which also simplifies assembly.

According to a particularly advantageous development of the invention, a Federele element is provided for springing the temperature sensor against the conductor. This spring element ensures that the temperature sensor is always brought into a defined thermal coupling to the conductor, as well as any geometric tolerances that can be easily compensated for. This means that the temperature sensor or the sensor carrier on the carrier is slightly movable so that it can be pressed against the spring element.

In this case, the spring element is preferably arranged on the cover and, when the cover is installed, positioned laterally adjacent to the sensor carrier, on the opposite side of which the conductor runs. This means that when the cover is closed or attached, the spring element presses against the sensor carrier or the shrink tubing surrounding it, so that this arrangement with the temperature sensor is pressed against the conductor. As described, the sensor carrier is arranged on the carrier so that it can move slightly, so that the spring element springs against the conductor, even with compensation for any small tolerances. A curved leaf spring is preferably used as the spring element, which is fastened to the cover in a suitable manner via appropriate fastening means such as latching or clamping sections.

The housing of the temperature sensor arrangement itself is preferably made of plastic, so it can be manufactured inexpensively in a very simple manner.

The invention is explained below using exemplary embodiments with reference to the drawings. The drawings are schematic representations and show:

FIG. 1 shows a basic illustration in the form of a partial view of an electrical machine according to the invention,

Figure 2 comprises a perspective view of a temperature sensor device

Sensor carrier and temperature sensor,

Figure 3 is a perspective view of a carrier as part of the temperature sensor arrangement,

FIG. 4 the mounted temperature sensor device on the carrier,

Figure 5 shows the temperature sensor arrangement, attached to the conductor to be detected in a temperature,

Figure 6 is a perspective view of a cover for attachment to the carrier,

FIG. 7 shows the temperature sensor arrangement according to the invention in the open state with the carrier arranged on the conductor and the cover detached,

FIG. 8 shows the arrangement from FIG. 7 from the other side,

FIG. 9 shows the closed temperature sensor arrangement, and FIG. 10 shows a sectional view through the temperature sensor arrangement with a continuous conductor according to FIG. 9.

FIG. 1 shows, in the form of a partial view, a basic representation of an electrical machine 1 according to the invention, comprising a stator 2 with a winding 3 comprising a plurality of conductors 4, which are assigned to three separate phases in the example shown. Each conductor 4 is designed, as it were, as a U-shaped bracket, a large number of such U-shaped conductors 4, often also called hairpins, being plugged together to form the winding 3, which can also be referred to as a winding cage. The large number of conductors 4 define different radial planes R, as shown in FIG. For this purpose, the conductors 4 extend, depending on the winding scheme, from one radial plane to another radial plane, for example an adjacent radial plane, in the area in which they are connected to the conductor ends of corresponding adjacent conductors 4 continuing the phase conductor.

The conductors 4 are guided or bent and laid in such a way that corresponding recesses 5 are produced which extend radially so that corresponding

Stator teeth 6 engage in these recesses 5 or the corresponding conductors 4 are wound between the corresponding grooves of the stator teeth 6. The basic structure of such a stator 2 or a winding 3 wound from the separate brackets described is basically known.

In the case of the stator 2 according to the invention, the ends 7 of the conductors 4 protrude axially, as long as the ends 7 end or are positioned on the inner circumference and the outer circumference of the annular winding 3, i.e. they protrude axially from the winding 3. These ends 7 are associated with individual conductors 4, which in turn are assigned un different phases, which is why the conductor ends are to be wired according to the laying scheme of the conductor 4. A connection ring 8 is used for this purpose, which in the example shown is placed axially on the end face of the winding 3 and is arranged between the conductor ends 7, or engages between them. The circuit ring 8 comprises, as will be discussed below, a plurality of corresponding conductors, which can also be referred to as line bridges and are formed from busbars or busbars, usually made of copper, and on connection sections 9 which protrude to the side from the housing 10 of the connection ring 8 and after inserting the connection ring 8, the connection sections 9 are precisely positioned next to the corresponding conductor end 7 with which they are to be connected. The connection is made by simple welding, so that all conductors 4 are correctly and phase-specifically connected to one another when they are connected. Furthermore, a Stromver supply 1 1 is provided, which is arranged radially next to the winding 3 in the region of the axial end thereof. The power supply 1 1, also called HV terminal, comprises a housing 12 in which corresponding busbars 13 are arranged, which protrude with their connection terminals 14 from the housing 12.

In the present case, as described, a three-phase stator is shown, which is why three such connection terminals 14 are also provided in the example shown.

Each connection terminal 14 is to be connected to one phase of the winding 3. This is implemented in a simple manner in the exemplary embodiment shown in that two conductor ends 7a per phase are guided or bent radially outward, as FIG. 1 clearly shows.

As described, several corresponding conductors, which form line bridges, are provided in the interior of the housing 10 of the interconnection ring 8, only one such conductor 15 being shown in dashed lines in the exemplary embodiment shown. On this Lei ter a temperature sensor arrangement 16 is arranged, that is, directly connected to the conductor 15 in order to directly measure the conductor temperature as a measure of the winding temperature.

The temperature sensor arrangement 16 comprises a temperature sensor device 17, as shown in FIG. The temperature sensor device 17 has a sensor carrier 18 on which a temperature sensor 19 and corresponding connecting lines 20 to a continuing cable 21 are arranged. A shrink tube 22 is pulled onto the sensor carrier 18, which has a defined shape in the front end. has closing contour 23 with two suitable undercuts, which are used to mount and position the sensor device 18 on a carrier 24.

Such a carrier 24 is shown in Figure 3 as a perspective view. The carrier 24 is made of plastic and has a cable holding section 25 and an engaging contour section 26 for the interlocking contour 23. In addition, two axially miteinan the aligned openings 27 are provided through which, which will be entered below, the conductor 15 runs in and out of the housing to be formed by means of the carrier 24 and a cover to be described in the following. Further lateral openings 28, 29 are also closed by means of the cover, which will be discussed below.

FIG. 4 shows an arrangement in which the temperature sensor device 17 is attached to the carrier 24. As can be seen, the cable 21 runs through the cable holding section 25, while the form-fitting contour 23 engages in the engagement contour section 26. The arrangement is such that the sensor carrier 18 is virtually vertical, so that the temperature sensor 19 is directed towards the interior of the carrier 24.

This arrangement is now coupled to the conductor 15, that is to say to the busbar 15. This is inserted into the open carrier from above, see arrow P1 in FIG. 5, so that it is arranged between the outer carrier wall 30 and the temperature sensor device 17 or the sensor carrier 18. The temperature sensor 19 is accordingly positioned directly adjacent to the flat, rail-shaped conductor 15.

A cover 31, which is shown in detail in FIG. 6, is then put on to form a closed housing. The cover 31 has several latching elements 32 by means of which it is latched on the carrier 24. Furthermore, a wall section 33 is provided, on which a spring element 34 is arranged here in the form of a leaf spring 35 which is directed towards the center of the cover. This leaf spring 35 serves to spring the temperature sensor device 17 or the sensor carrier 18 and thus the temperature sensor 19 against the conductor 15, which will be discussed below. A wall section 36, which is arranged adjacent to the wall section 33, is also provided. As FIG. 7 shows, the cover 31 is now placed on the carrier 24, as shown by the arrow P2. Here, the wall section 36 engages in the opening 28, while the wall section 33 engages in the opening 29. As FIGS. 7 and 8 show, the leaf spring 35 comes to lie directly adjacent to the temperature sensor device 17 so that it springs against the conductor 15, and thus the temperature sensor 19. The fixing takes place via the snap-in locking elements 32.

As FIG. 9 shows, a closed housing 37 is consequently obtained, FIG. 9 showing the fully assembled temperature sensor arrangement 16. The housing 37 is almost completely closed so that any disruptive influences cannot get into the actual measuring range.

As the sectional view according to FIG. 10 clearly shows, the temperature sensor device 17 or the sensor carrier 18 and thus also the temperature sensor 19 are pressed firmly against the conductor 15 via the leaf spring 35, which, as FIG. 10 shows, can be cast on the cover 31, so that an optimal thermal coupling for an exact measurement is possible. In addition, the closed housing 37 also provides ideal protection.

As simple as the assembly is, in the context of which only the temperature sensor device 17 is to be attached to the carrier 24, after which this arrangement is to be fixed to the conductor 15 and now only the cover 31 is clipped on, the dismantling is also simple in the event of maintenance .

List of references for electrical machine

stator

Winding

ladder

Recess

Stator tooth

The End

Interconnection ring

Connection section

casing

Power supply

casing

Busbar

Connection terminal

ladder

Temperature sensor arrangement

Temperature sensor device

Sensor carrier

Temperature sensor

Connecting line

electric wire

Shrink tubing

Form-fit contour

carrier

Cable holding section

Engagement contour section

opening

opening

opening

Support wall

cover 32 locking element

33 wall section

34 spring element

35 leaf spring

36 wall section

37 housing

R radial plane

P1 arrow

P2 arrow

Claims

Claims

1. Electrical machine comprising a stator (2) with a winding (3), and at least one temperature sensor arrangement comprising a temperature sensor (19) for detecting the temperature in the area of the winding, characterized in that the ends (7, 7a) at least one Some of the conductors (4) protrude beyond the winding (3), some of these ends (7, 7a) being closed on a connecting ring (8) placed axially or radially on the winding (3), the temperature sensor arrangement (16 ) arranged on a conductor (15) and the temperature sensor (19) is thermally coupled to the conductor (15).

2. Electrical machine according to claim 1, characterized in that the temperature sensor arrangement (16) has a housing (37) in which the Tem perature sensor (19) is received and through which the conductor (15) it stretches.

3. Electrical machine according to claim 2, characterized in that the housing (37) has a carrier (24) on which the temperature sensor (19) is fixed, as well as a cover (31) which can be releasably attached to the carrier (24) and which Housing (37) closes.

4. Electrical machine according to claim 3, characterized in that the cover (31) is attached to the carrier (25) via a latching or clamping connection (32).

5. Electrical machine according to claim 3 or 4, characterized in that the temperature sensor (19) is arranged on a sensor carrier (18) which has a form-fit contour or on which a form-fit contour (23) facing shrink tube (22) is drawn, a mating contour (26) receiving the form-fitting contour (23) is provided on the carrier (24).

6. Electrical machine according to one of the preceding claims, characterized in that a spring element (34) is provided for springing the temperature sensor (19) against the conductor (15).

7. Electrical machine according to claim 6 and one of claims 3 to 5, characterized in that the spring element (34) on the cover (31) is arranged and with the cover (31) mounted laterally adjacent to the sensor carrier (18) the opposite side of which the conductor (15) runs, is posi tioned.

8. Electrical machine according to claim 6 or 7, characterized in that the spring element (34) is a curved leaf spring (35).

9. Electrical machine according to one of claims 2 to 8, characterized in that the housing (37) is made of plastic.