EP3440354B1 - Control assembly, fastening assembly, compressor device, and method for controlling a compressor device - Google Patents

Description

The present invention relates to a control arrangement for regulating or controlling a compressor device, a fastening arrangement and a compressor device with a control arrangement. The present invention also relates to a method for controlling a compressor device.

In the case of a compressor, gases are usually compressed into fluids, which are then used in various processes. For example, in refrigeration and air conditioning technology, certain refrigerants such as CO ₂ are used, which are compressed in a circuit. In particular in the case of air conditioning compressors used in motor vehicles, the compression takes place with the aid of an electric drive. In order to make favorable use of the limited installation space available in the motor vehicle, it is desirable to connect or integrate control circuits, in particular also circuit boards or printed circuit boards, which carry corresponding control electronics, with the compressor housing.

One difficulty here is, for example, that the housing surfaces of the compressor can bend or move due to pressure fluctuations. If possible, no bending stress should be transferred to the mechanical and electronic elements of the control electronics.

The US 2012/0113603 A1 discloses an electrical device with a circuit board, a semiconductor component, a housing, several rubber sleeves under the circuit board, an aluminum plate above the circuit board and a Insulating film. The rubber sleeves arranged between the circuit board and the housing clamp the external aluminum plate, the insulating film, the semiconductor module and the circuit board together vertically in the assembled state.

Against this background, the object of the present invention is to create a favorable possibility of fastening an electronic control device for a compressor device on a deformable surface.

This object is achieved by an arrangement having the features of independent claim 1 and a method according to claim 15.

Accordingly, a control arrangement for regulating or controlling a compressor device, which has a housing for a compressed fluid, is proposed. A deformable structural element of the housing is arranged between a first pressure area and a second pressure area of the compressor device. The control arrangement comprises an electrical power module, a cooling plate for dissipating heat from the electrical power module, which is thermally coupled to the cooling plate, and a fastening arrangement for the cooling plate. The fastening arrangement has a plurality of spacer elements which space the cooling plate from the structural element, the spacing elements being arranged in such a way that a transfer of the deformation of the structural element to the cooling plate is reduced, in particular prevented.

The power module is in particular part of an electronic control device for the compressor device. The control device can include further electronic components, such as power semiconductors, switches, processors, memories and the like. In embodiments, the electronic control device has printed circuit cards or boards with conductor tracks, which with the aid of the fastening arrangement and the cooling plate protected from bending stresses on the one hand and thermal stresses on the other.

The cooling plate is preferably spaced from the structural element with the aid of the spacer elements in such a way that no additional force application point arises between the structural element and the cooling plate even if the structural element is maximally deformed or arched during normal operation of the compressor device. This has the advantage that the cooling plate - and other elements mechanically coupled to it - are not exposed to any additional bending stress. A deformation in the manner of a curvature of the flat structural element, for example, is then not transferred to the cooling plate, because the deformation of the structural element surface in the axial direction can occur as an evasive movement between the positions of the spacer elements without additional stresses being generated in the cooling plate. The cooling plate is preferably free of inelastic obstacles in the direction of the evasive movement. To this extent, the control arrangement is robust and integrated in or on the housing of the compressor device at low cost.

The first pressure range is, for example, a low pressure range of a compressor, and the second pressure range is an atmospheric pressure range. The structural element can, for example, correspond to a housing base which is deformed, shaped, deformed, arched or bent due to pressure fluctuations between the pressure present inside the compressor and the external atmospheric pressure. For example, when the compressor device is in operation, a pressure change within the housing from 3 MPa to 8.5 MPa or 30 bar to 85 bar is brought about. The area of the structural element or the housing base that is deformed, shaped, deformed, arched or bent due to the changing pressure load can also be called the "breathing area".

Furthermore, for example, the pressure in the low pressure range when filling the compressor with a refrigerant is almost zero, so that the structural element or the housing base can also deform, shape, deform, bulge or bend in the "other direction" or inward, as the atmospheric pressure is higher. In contrast, a test pressure of 150 MPa or 15 bar can be applied to the low-pressure area, for example.

In the control arrangement, the cooling plate is in particular spaced apart in the axial direction, that is to say essentially normal to the cooling plate and the surface of the structural element, preferably exclusively by the spacer elements. A transfer of the deformation of the structural element to the cooling plate is reduced or prevented at least compared to a flat fastening of the cooling plate to the housing.

The cooling plate can in particular be arranged so that it can move easily laterally relative to the spacer elements. "Lateral" means running in the plane of the cooling plate. The control arrangement can be designed in such a way that a laterally floating mounting of the cooling plate is possible. This means that there is no tension in the plane of the cooling plate.

The cooling plate and the, in particular, flat structural element preferably run parallel to one another. Furthermore, the cooling plate is preferably an aluminum plate, aluminum oxide plate, ceramic plate, copper plate, DCB plate (English: Direct Bonded Copper - DCB) or laminate plate. The electrical power module is preferably a module with a bipolar transistor with an insulated gate electrode (English: insulated-gate bipolar transistor - IGBT) and / or metal-oxide-semiconductor field effect transistor.

The service life of the cooling plate and the electronic components and conductor tracks can thus be significantly extended. The spacer elements are preferred Arranged around an arching or deformation center in such a way that the spacer elements are moved symmetrically during the arching or deformation of the structural element, so that the cooling plate only experiences a translational movement. The spacer elements serve as punctiform support points for the cooling plate. The spacer elements are preferably arranged at a point at which the slightest deformation of the structural element is to be expected.

The holding plate designed as a cooling plate is preferably made of an electrically conductive material, so that, in addition to the function of holding and dissipating heat, there is also electrical shielding. The control arrangement thus also meets safety requirements for control electronics in motor vehicles that are operated at 12, 48 volts or more as a low voltage (up to 60 volts).

The spacer elements are preferably arranged symmetrically around a region of greatest axial or normal deflection of the structural element. A predetermined distance between the cooling plate and the structural element is kept constant, particularly in the area of the spacer elements, by the multiple spacing elements provided, for example, symmetrically. This enables the use of flat heat-conducting elements, which can implement particularly good heat transfer from the cooling plate to the structural element.

In embodiments, the electrical power module for dissipating heat from the electrical power module to the cooling plate is arranged on a side facing away from the structural element.

Thus, at least the cooling plate is arranged between the power module and the structural element. Consequently, the dissipation of heat to the structural element can be achieved with the aid of the cooling plate, without Curvatures or deformations of the structural element affect the power module mechanically.

In embodiments, the control arrangement comprises at least one heat-conducting element which is arranged between the structural element and the cooling plate, so that heat can be dissipated from the cooling plate to the structural element with the aid of the heat-conducting element.

Since the heat-conducting element is also arranged between the cooling plate and the structural element, this improves the cooling of the power module. The heat-conducting element preferably consists of a more flexible material than the cooling plate and / or the structural element. The heat-conducting element is also preferably designed to be elastic and / or flexible.

The heat-conducting element is made, for example, at least partially from an elastomer. Furthermore, the heat-conducting element can be applied to the structural element in the form of a gel, jelly or a paste. This can be done, for example, with the aid of a dispenser.

In embodiments, the heat-conducting element has a flat geometry with a cutout, in particular a centrally arranged cutout, so that an area of the structural element that experiences the greatest deformation is arranged in the area of the cutout.

In the present case, the largest deformation can also be understood as the largest formation, curvature or deformation. With the aid of the recess, space is created for the structural element, which can extend into the recess during the deformation, deformation or curvature. As a result, a transfer of the deformation of the structural element to the heat-conducting element is prevented or kept to a minimum. This has the advantage that the heat-conducting element is used gently. More preferably, displacement spaces are provided so that the heat-conducting element, due to the deformation of the structural element is squeezed, has room to evade. This can be achieved, for example, by subdividing the heat-conducting element or creating additional spaces. A part of the structural element preferably extends into the recess.

In embodiments, the heat-conducting element has recesses through which the spacer elements extend.

The provision of the recesses for the spacer elements in the heat-conducting element enables the use of a large heat-conducting element which is, for example, longer and / or wider than a distance between the spacing elements. At the same time, the cutouts can also be used to secure against rotation for the heat-conducting element relative to the structural element. The spacer elements preferably extend through the cutouts to the cooling plate.

The heat conducting element or elements can be present in the form of pads between the cooling plate and the generally flat structural element. The spacer elements, which are subjected to a pressing force, ensure an essentially constant spacing, so that contact between the pad and the holding plate or cooling plate on the one hand and the housing base or structural element on the other hand is guaranteed in the area, for example, around the spacer elements.

In embodiments, the housing base has one or more recesses for receiving one or more heat-conducting elements.

In embodiments, the control arrangement has at least one spring element, with the aid of the spring element a pressing force being applied from the cooling plate to the structural element via the spacer elements.

For example, the spring element is designed as an elastomer spring, in particular with a flat geometry. The spring element can in particular be arranged on the inside of a housing cover and exert the contact pressure on the rest of the control arrangement.

A plurality of spring elements, in particular at least three, are preferably provided. For example, a spring element is provided on an attachment means which attaches the cooling plate to the structural element. The spring element is in particular a disc spring and rests on an upper side of the cooling plate, the structural element in particular having at least one screw-on dome which extends in particular into a continuous opening in the cooling plate, in particular a fixing element, e.g. a disk, with the aid of a fastening means, e.g. a screw or a bolt, is screwed to the screw-on dome and engages behind the cooling plate, the spring element being pretensioned against the cooling plate and the fixing element.

As an alternative or in addition, the cooling plate is held with the aid of an axial pressing force, which is generated in particular with the aid of a screwable or latchable cover of the compressor device which is releasably attached to the structural element. An axial pressing force can in particular be transmitted via further holding means.

Both the screw-on dome and the fixing element have, in particular, radial play within the, in particular, circular opening of the cooling plate, so that slight displacements or movements of the screw-on dome radially to the opening do not induce any stresses in the cooling plate. Thus, the provision of several screw-on domes would also allow, in particular, slight lateral movements between the structural element and the cooling plate. With the help of the pretensioned spring element, the cooling plate is pretensioned in the direction of the structural element, so that in particular a pressing or displacement of the spacer elements due to a deformation, deformation, shaping or bending of the structural element by means of Compression of the spring element or the spring elements can be compensated. The preload also ensures that the cooling plate rests in a stable manner on the spacer elements, in particular that there is no axial play between the cooling plate and the spacer elements. In particular, the spring element is to be designed in such a way that it can compensate for the up and down movement of the cooling plate.

In embodiments, the structural element forms an area, in particular a circular area, and the spacer elements are arranged symmetrically around a geometric center point of the area.

The spacer elements for spacing the cooling plate are preferably provided in the edge region of the cooling plate and the, in particular, circular surface of the structural element. For example, the spacer elements can be provided at regular angular intervals, in particular 120 °, around the center point. A stable bearing surface of the cooling plate on the spacer elements can thus be achieved. The geometric center point is preferably the point that experiences maximum shaping during the deformation or curvature of the structural element.

In embodiments, the spacer elements are at least partially cylindrical.

For example, circular cylinders with a height between 0.1 and 2 mm can be provided. The height of the spacer elements specifies at least a distance between the cooling plate and the structural element.

In embodiments, the spacer elements are molded onto the structural element.

There is then an integral body made up of a structural element and spacer elements. The integral body preferably consists of one material. More preferred the integral body is cast and / or manufactured with the help of machining manufacturing processes. As a result, the spacer elements do not have to be positioned, aligned or fastened in a complex assembly process.

In embodiments, the spacer elements are molded onto the cooling plate. Then there is an integral body made of spacer elements and cooling plate.

In particular, a fastening arrangement for a cooling plate on a deformable structural element is proposed, which is arranged between a first pressure area and a second pressure area of a compressor device, the cooling plate being set up to dissipate heat from an electrical power module which is thermally coupled to the cooling plate , wherein the cooling plate is spaced apart from the structural element with the aid of a plurality of spacer elements, the spacer elements being arranged in such a way that the deformation of the structural element is prevented from being transmitted to the cooling plate.

In addition, a compressor device is proposed with a control arrangement as described above or below, a housing part which comprises a housing base as a structural element, the housing base having a first pressure range from a second pressure range which has a lower pressure than the first pressure range , separates, the cooling plate being fastened on the low-pressure side to the housing base in the axial direction with the aid of the fastening arrangement.

The pressure difference can be between 3 and 8.5 MPa, for example, so that the bottom of the housing of a compressor can be arched by a few tenths of a millimeter during operation. Bending of the cooling plate is, however, avoided by the control arrangement or fastening arrangement. The compressor device is set up, for example, for CO ₂ or CFC (Chlorofluorocarbon) to compress. In embodiments, it is a cooling compressor for CO ₂ as a coolant,

In embodiments, the housing base has a positioning aid, a centering device and / or an anti-rotation device for the cooling plate. This simplifies the manufacture and manufacture of the compressor device. Furthermore, a floating fastening is made possible, in which, in particular, a lateral movement relative to the spacer elements is made possible.

In embodiments, the compressor device has a low-pressure area for collecting fluid to be compressed and a high-pressure area in which compressed or compressed fluid is held. In embodiments, the structural element as the housing bottom delimits the low-pressure area from the atmospheric pressure present outside the compressor device. In the low-pressure chamber, the fluid is usually significantly cooler than in the high-pressure area, so that the housing bottom can serve for cooling better than when the cooling plate is arranged on a housing wall that delimits the high-pressure area.

Furthermore, a method for attaching a cooling plate to a deformable structural element, which is arranged between a high-pressure area and a low-pressure area of a compressor device, is proposed. The cooling plate is spaced apart from the structural element with the aid of spacer elements. The method uses in particular a control arrangement, as described above, or a fastening arrangement, as described above, or a compressor device, as described above.

In embodiments, the structural element is set up such that, due to a pressure increase in areas in which the spacer elements are arranged, it moves less away from a zero level than in an area between the spacer elements. For example, the structural element bulges in an area between the spacer elements due to an increase in pressure.

In embodiments, the control arrangement, fastening arrangement or compressor device comprises a printed circuit board, in particular a printed circuit card. The power module can be arranged between the cooling plate and the circuit board, but also on the side of the circuit board facing away from the cooling plate and the structural element. This also prevents the deformation of the structural element from being transmitted to the printed circuit board with the aid of the cooling plate and its fastening.

In embodiments, in particular at the center point or a predetermined area around the center point, which is often exposed to a particularly strong axial deflection due to a deformation of the structural element, no spacer element is provided for fastening the cooling plate. In alternative embodiments of the fastening arrangement and / or the control arrangement, which are not according to the invention and which are only used for illustration, the cooling plate is replaced by a holding plate. The holding plate then only optionally has a heat-dissipating function and serves mainly as holding or carrier elements for the electronic components and / or a printed circuit board or circuit board.

In one embodiment, the housing base has a pressure-tight passage for at least one connection line from the first pressure area to the second pressure area on the holding plate or cooling plate.

There are preferably no further fastening means, so that the holding plate or cooling plate practically always retains its flat shape even if the structural element is deformed. It can be said that the holding plate or cooling plate is held or supported in a floating manner on the structural element, which is particularly flat.

In embodiments, the structural element is designed, for example, as a housing bottom of an air conditioning compressor, which is made from a material with good thermal conductivity. For example, an aluminum material, stainless steel or even a composite material is conceivable. Furthermore, the structural element can additionally have a cooling function because the refrigerant present in the second pressure range is mostly below the operating temperatures of the power semiconductor. Line semiconductor chips, for example, develop temperatures between 100 and 150 ° C, while the refrigerant in the compressor is well below 60 ° C.

The embodiments and features described for the proposed control arrangement apply accordingly to the proposed fastening arrangement, the proposed compressor device and the proposed method. The embodiments and features of the proposed compressor device also apply to the fastening arrangement, control arrangement and method.

Further possible implementations of the invention also include combinations, not explicitly mentioned, of features or embodiments described above or below with regard to the exemplary embodiments. The person skilled in the art will also add individual aspects as improvements or additions to the respective basic form of the invention.

Fig. 1

zeigt eine stark vereinfachte Schnittansicht einer ersten Ausführungsform einer Ansteueranordnung;

Fig. 2

zeigt eine vereinfachte Schnittansicht einer zweiten Ausführungsform der Ansteueranordnung;

Fig. 3

zeigt die Ansteueranordnung gemäß Fig. 2 in einer perspektivischen Darstellung;

Fig. 4

zeigt eine Aufsicht eines Strukturelements mit einem Wärmeleitelement;

Fig. 5

zeigt eine perspektivische Ansicht eins Wärmeleitelements;

Fig. 6

zeigt eine perspektivische Ansicht einer Kühlplatte mit einem Leistungsmodul; und

Fig. 7

zeigt eine perspektivische Ansicht einer Leiterplatte.

Further advantageous configurations and aspects of the invention are the subject matter of the subclaims and of the exemplary embodiments of the invention described below. The invention is explained in more detail below on the basis of preferred embodiments with reference to the attached figures.

Fig. 1

shows a greatly simplified sectional view of a first embodiment of a control arrangement;

Fig. 2

shows a simplified sectional view of a second embodiment of the control arrangement;

Fig. 3

shows the control arrangement according to Fig. 2 in a perspective view;

Fig. 4

shows a plan view of a structural element with a heat-conducting element;

Fig. 5

shows a perspective view of a heat conducting element;

Fig. 6

shows a perspective view of a cooling plate with a power module; and

Fig. 7

Figure 3 shows a perspective view of a circuit board.

In the figures, elements that are the same or have the same function have been given the same reference symbols, unless otherwise stated.

In the Fig. 1 is a greatly simplified sectional view of a first embodiment of a control arrangement 1. The control arrangement 1 is suitable for regulating or controlling a compressor device which has a housing for a compressed fluid and wherein the fluid is compressed with the aid of an electric drive. The control arrangement 1 couples electronic components, such as an electrical power module 3 and conductor tracks (not shown), via a cooling plate 2 to an in particular elastically deformable structural element 4 of the compressor device with the aid of spacer elements 5, which distance the cooling plate 2 from the surface 4A of the structural element 4. The structural element 4 is, for example, a housing bottom of a compressor housing for receiving compressed fluid. The compressor device can be used, for example, in an electric or hybrid vehicle and with a voltage of 100 to 400 volts or 400 to 1000 volts can be operated. The range of use is preferably above the low voltage. The cooling plate 2 can alternatively be designed as a holding plate for electronic components and / or a circuit board of an electronic control device for the compressor drive.

In Fig. 1 one recognizes the deformable structural element 4, which has a flat geometry and can be, for example, the housing bottom of a compressor device. The, in particular elastically deformable, structural element 4 is arranged between an atmospheric pressure area P and a low pressure area N and separates them from one another. The low-pressure area N has a higher pressure than atmospheric pressure during the operation of the compressor device under consideration. The cooling plate 2 has an underside 2A and an upper side 2B, the cooling plate 2 being thermally coupled to the electric power module 3 at the upper side 2B for dissipating heat from the latter. The structural element 4 likewise has a top side 4A, which faces the bottom side 2A of the printed circuit board 6, the spacer elements 5 being located between the bottom side 2A and the top side 4A, and a bottom side 4B, which faces the printing area N. Due to the pressure difference, the structural element 4 can bulge or deform from an initial position. This is indicated by the dashed illustration of the top 4A 'and bottom 4B'. The cooling plate 2, the electrical power module 3 and the spacer elements 5 are not deformed, arched or deformed and are indicated by dashed outlines in order to illustrate the behavior of the control arrangement 1 during the deformation or arching of the structural element 4.

So that the cooling plate 2 is not subjected to the same deformation or curvature, a fastening arrangement for the cooling plate 2 with the plurality of spacer elements 5 is provided, which spaced the cooling plate 2 from the structural element 4, the spacer elements 5 being arranged in such a way that a transfer of the deformation or Curvature of the structural element 4 on the cooling plate 2 is largely prevented but at least reduced. The Spacer elements 5 are arranged, for example, around a deformation, a curvature, a curvature high point or curvature center point, that they move the cooling plate 2 preferably only translationally during the corresponding movement due to the deformation and the cooling plate 2 is not subjected to any additional bending or tension. Correspondingly, the spacing of the control arrangement 1 is designed in such a way that with maximum deformation, deformation, shaping or bending of the structural element 4, for example during operation of the compressor device, no additional pressure point arises between the structural element 4 and the cooling plate 2.

In particular, it is possible to use the control arrangement 1 in a compressor arrangement, such as an air conditioning compressor for motor vehicles.

The Figures 2-7 show several representations of an embodiment for a compressor device 23 with a control arrangement in which a cooling plate is fastened as a holding plate with the aid of a fastening arrangement. In the Fig. 2 and 3rd a section of a compressor device 23 is shown in cross section. The Fig. 4 shows essentially a plan view of a housing base top, Fig. 5 a perspective view of a thermal pad, and Fig. 6 shows part of the compressor device from an oblique perspective view of the top of the cooling plate. The Fig. 7 Figure 3 is a perspective view of a circuit board.

Fig. 2 FIG. 4 shows a simplified sectional view of a second embodiment of the control arrangement 1. In contrast to FIG Fig. 1 the control arrangement 1 comprises a heat-conducting element 7, which is arranged between the structural element 4 and the cooling plate 2, so that heat can be dissipated from the cooling plate 2 to the structural element 4 with the aid of the heat-conducting element 7. The heat-conducting element 7 has a flat geometry with a centrally arranged recess, so that a region of the structural element 4 that experiences the greatest deformation is arranged in the region of the recess. Furthermore has the heat-conducting element 7 has recesses through which the spacer elements 5 extend, which are molded onto the structural element 4, so that a one-piece integral body 4, 5 composed of structural element 4 and spacer elements 5 is present. The top of the integral body 4, 5 is at least partially designed as a negative shape of the heat-conducting element 7.

Furthermore, the control arrangement 1 has at least one spring element 8, with the aid of the spring element 8 a pressing force being applied from the cooling plate 2 via the spacer elements 5 to the structural element 4. The spring element 8 is in particular a disc spring and rests on an upper side 2B of the cooling plate 2, the structural element 4 having at least one screw-on dome 9 which extends into a continuous opening 10 of the cooling plate 2, with a fixing element 11, in particular a disk, by means of a screw 12 is screwed onto the screw-on dome 9 and engages behind the cooling plate 2, the spring element 8 being pretensioned against the cooling plate 2 and against the fixing element 11. Both the screw-on dome 9 and the fixing element 11 have radial play within the, in particular, circular opening 10, so that slight displacements or movements of the screw-on dome 9 radially to the opening 10 do not induce any stresses in the cooling plate 2. Thus, the provision of a plurality of screw-on domes 9 would allow, in particular, slight lateral movements between the structural element 4 and the cooling plate 2. With the help of the pretensioned spring element 8, the cooling plate 2 is pretensioned in the direction of the structural element 4, so that a pressure or displacement of the spacer elements 5 due to a deformation, deformation, shaping or bending of the structural element 4 is compensated for by means of the spring element 8 or the spring elements 8 being compressed can be. The bias also ensures that the cooling plate 2 rests on the spacer elements 5 in a stable manner, in particular that there is no axial play between the cooling plate 2 and the spacer elements 5.

In Fig. 2 only one spacer element 5 is shown, the other spacer elements 5 being located in other cross-sectional planes of the control arrangement 1 or not being visible in the plane shown. The heat-conducting element 7 consists in particular of a more flexible material than the structural element 4 and / or the cooling plate 2 and / or is in particular a heat-conducting pad. The heat-conducting element 7 preferably consists of a flexible and / or elastic material.

Fig. 3 shows the control arrangement according to Fig. 2 in a perspective view.

In order to prevent damage to the electrical power module 3 and the printed circuit board or printed circuit card or circuit board 6, these were mounted on the cooling plate 2. The heat-conducting element 7 is mounted as a heat-conducting pad between the cooling plate 2 and the housing base 4. The heat-conducting element 7 requires a defined distance from the housing base 4, which is filled by the material of the heat-conducting pad 7. As a result, the heat generated in the electrical power module 3 or from the circuit board 6 is transferred to the housing base 4 via the cooling plate 2. The housing bottom 4 is cooled by the refrigerant in the pressure chamber N.

Fig. 4 shows a top view of a structural element 4 with a heat-conducting element 7. Three spacer elements 5 and three screw-on domes 9 are arranged on the structural element 4 around a center point M at an angular distance of 120 °. In order to ensure uniform support and movement of the cooling plate 2 with the structural element 4, in particular the housing base, the spacer elements 5 are distributed symmetrically around the center of the deflection of the structural element 4, in particular the housing base. In the middle of the structural element 4, the heat-conducting element 7 has been cut out, since at this point 15 the up and down movement of the structural element 4, in particular the housing base, is greatest due to the changing pressure load.

Furthermore, the structural element 4 or the housing base has four fixing elements 22, which are arranged radially outside at an angular distance of 90 ° and are provided as a positioning aid for the cooling plate 2, which has openings 21 corresponding to the fixing elements 22. The fixing elements 22 are designed in particular as fixing spikes and extend in the axial direction, that is to say essentially normal to the cooling plate 2 in the installed position.

Fig. 5 FIG. 11 shows a perspective view of the heat conducting element 7 from FIG Fig. 4 . The heat conducting element 7 has an annular geometry. Furthermore, the heat-conducting element 7 has recesses (only one of which is provided with reference numeral 16) for the cylindrical spacer elements 5 and at least partially for the cylindrical screw-on domes 9. The recesses 16 for the spacer element 5 have an angular spacing of 120 ° from one another. The recesses 17 for the screw-on domes 9 also have an angular spacing of 120 ° and each correspond in the radial direction to a recess 16 for one of the spacer elements 5, but lie radially further outward.

Fig. 6 shows a perspective view of a cooling plate 2 with an electronic IGBT power module 3. The electrical power module 3 is mounted on the cooling plate 2 with the aid of a screw connection 13 and tabs 20. Furthermore, four screw-on domes 14 are provided for fastening the printed circuit board 6 to the cooling plate 2. The openings 21 are at least partially designed as a negative shape of the fixing elements 22, so that the cooling plate 2 can rest on the structural element 4 in a form-fitting and twist-proof manner as soon as the fixing elements 22 engage in the openings 21. The openings 21 are designed as elongated holes.

Fig. 7 shows a perspective view of a circuit board 6. The circuit board 6 is mounted over the electrical power module 3 and is in contact with it. The electrical power module 3 is to the circuit board 6, for example a Circuit board or printed circuit as a carrier for electronic components 18 of the corresponding control circuit connected. One also speaks of a printed circuit board, printed circuit board, circuit board or PCB (English: Printed Circuit Board). To the screw connection 14 (cf. Fig. 6 ) 6 handling openings 20 are provided in the circuit board.

The control circuit or control device for the corresponding air conditioning compressor is implemented on a printed circuit board 6 with the aid of electronic components 18, in particular with the aid of power semiconductors 3. The circuit board or circuit board 6 has in the illustration of Fig. 7 electrical components 9 on the upper side. Furthermore, the power semiconductors or modules 2 (covered), which can develop temperatures between 100 and 150 ° C., are arranged on the underside.

Although the present invention has been described on the basis of a few exemplary embodiments, it can be modified. In particular, the number of spacer elements can be varied. It is also possible to achieve the pressing force by other, for example, resilient elements. Furthermore, the shape and geometry of the housing base is not necessarily circular. Oval or other shapes are also conceivable. The structural element does not necessarily have to be a housing bottom of the compressor device. Furthermore, the materials and dimensions mentioned are variable and can be adapted to the respective installation situation of a structural element or a compressor device. The pressure specifications can also vary and depend on the refrigerant compressed with the aid of the compressor device.

REFERENCE LIST

1

Control arrangement

2

Cooling plate

2A

bottom

2 B

Top

3

electrical power element

4th

Structural element

4A

Top

4B

bottom

5

Spacers

6th

Circuit board

7th

Heat conducting element

8th

Spring element

9

Screw-on dome

10

opening

11

Fixing element

12th

screw

13th

Screw connection

14th

Screw-on dome

15, 16, 17

Recess

18th

electronic component

19th

Handling opening

20th

Fastening tab

21st

Omissions

22nd

Fixing elements

23

Compressor device

N

Low pressure area

M.

Focus

P

Atmospheric pressure range

Claims (16)

1. A compressor device (23), comprising:

   a housing for a compressed fluid, wherein a deformable structural element (4) of the housing is arranged between a first pressure area (N) and a second pressure area (P) of the compressor device (23), and

   a drive arrangement (1) for regulating or controlling the compressor device (23), the drive arrangement (1) comprising:

   an electric power module (3),

   a cooling plate (2) arranged to dissipate heat from the electric power module (3) thermally coupled to the cooling plate (2), the cooling plate (2) being arranged between the structural element (4) and the power module (3), and

   a mounting arrangement for the cooling plate (2) comprising a plurality of spacer elements (5) spacing the cooling plate (2) from the structural element (4), wherein the spacer elements (5) are arranged to reduce transmission of deformation of the structural element (4) to the cooling plate (2).
2. The compressor device according to claim 1, wherein the electric power module (3) for dissipating heat from the electric power module (3) to the cooling plate (2) is arranged on a side (2A) facing away from the structural element (4).
3. The compressor device according to claim 1 or 2, comprising a heat conducting element (7) arranged between the structural element (4) and the cooling plate (2), so that heat can be conducted away from the cooling plate (2) to the structural element (4) by means of the heat conducting element (7).
4. The compressor device according to claim 3, wherein the heat conducting element (7) has a planar geometry with a recess (15), in particular arranged centrally, so that a region of the structural element (4), which undergoes the greatest deformation, is arranged in the region of the recess (15).
5. The compressor device according to claim 3 or 4, wherein the heat conducting element (7) comprises recesses (16) through which the spacer elements (5) extend.
6. The compressor device according to any one of claims 3 to 5, wherein the heat conducting element (7) is made of a more flexible material than the cooling plate (2) and/or the structural element (4).
7. The compressor device according to any one of claims 1 to 6, comprising at least one spring element (8), wherein a contact pressure is applied from the cooling plate (2) via the spacer elements (5) to the structural element (4) with the aid of the spring element (8).
8. The compressor device according to claim 7, wherein the spring element (8) rests on an upper side (2B) of the cooling plate (2), wherein the structural element (4) comprises at least one screw-on dome (9) extending into a through opening (10) of the cooling plate (2), wherein a fixing element (11) is screwed to the screw-on dome (9) by means of a screw (12) and engages behind the cooling plate (2), and wherein the spring element (8) is preloaded against the cooling plate (2) and against the fixing element (11).
9. The compressor device according to one of claims 1 to 8, wherein the structural element (4) forms a surface, in particular a circular surface, and the spacer elements (5) are arranged symmetrically about a geometric center point (M) of the surface.
10. The compressor device according to one of claims 1 to 9, wherein
    the spacer elements (5) are cylindrical at least in sections and/or are integrally formed on the structural element (4) and/or are integrally formed on the cooling plate (2).
11. The compressor device according to one of the claims 1 to 10, wherein the structural element (4) is configured to move away less from a zero level due to a pressure increase in regions in which the spacer elements (5) are arranged than in a region between the spacer elements (5).
12. The compressor device according to any one of claims 1 to 11, comprising a circuit board (6), wherein the power module (3) is arranged between the cooling plate (2) and the circuit board (6).
13. The compressor device according to any one of claims 1 to 12, wherein the spacer elements (5) are arranged in such a way that a transmission of the deformation of the structural element (4) to the cooling plate (2) is prevented.
14. The compressor device (23) according to any one of claims 1 to 13, wherein the second pressure area (P) has a lower pressure than the first pressure area (P), and the cooling plate (2) is fixed on a low pressure side to the housing base (4) in axial direction by means of the mounting arrangement.
15. A method for driving a compressor device (23), in which a cooling plate (2) for dissipating heat from an electric power module (3) thermally coupled on a side (2A) of the cooling plate (2) opposite to a structural member (4) is fixed to the deformable structural member (4) which is arranged between a high-pressure region and a low-pressure region (N) of the compressor device (23), wherein the cooling plate (2) is spaced apart from the structural element (4) by means of spacer elements (5), and wherein the spacer elements (5) are arranged such that a transmission of the deformation of the structural element (4) to the cooling plate (2) is reduced.
16. The method according to claim 15, wherein the compressor device (23) is configured according to any one of claims 1 to 14.

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