DE102011003133A1 - Machine holder in a vehicle - Google Patents

Abstract

The present invention relates to an engine mount for an engine in a vehicle. The machine holder has a housing, the inner shape of which essentially corresponds to an outer shape of the machine, and a fastening device for fastening the machine to the vehicle, the fastening device having a holding device which spans the housing.

Description

The present invention relates to a machine mount, in particular a compressor mount, in a vehicle.

Known refrigerant compressors for vehicles have a housing with flanges, which serve to secure the refrigerant compressor to the vehicle. As a rule, such refrigerant compressors are fixed by means of bolts to an engine block or transmission block of the vehicle. Furthermore, elastic buffers are used in known vibration-damping fasteners of machines by means of bolts.

It is the object of the present invention to provide a machine mount which is improved in terms of the decoupling of vibrations with low weight.

This object is achieved by a machine holder according to claim 1

A machine mount according to the invention for an engine in a vehicle or for an engine of a vehicle has an enclosure, the inner shape of which essentially corresponds to an outer shape of the machine, and a fastening device for fastening the machine to the vehicle. The fastening device has a holding device which spans the housing.

Due to the fact that the inner shape of the enclosure essentially corresponds to the outer shape of the machine, the housing is located on a large area of the machine. This embeds the machine in the enclosure.

The holding device in turn spans or surrounds the enclosure. A re-clamping of the housing can mean that the holding device engages around the housing in such a way that the housing is immovable relative to the fastening device and is thus spatially fixed with respect to each direction. The enclosure can thus be positively held by the holding device.

The fact that the fastening device with the holding device spans the housing and the housing in turn rests against the machine, there is no direct connection of the fastening device with the machine. Thus, the fastening device, the attachment of the machine bracket to z. B. a vehicle body or other elements of the vehicle is decoupled from the machine over a large area, so that a transmission of structure-borne noise, d. H. Vibrations from the machine to the vehicle is clearly suppressed. Furthermore, the enclosure dampens airborne noise generated by the machine.

According to a further development, the enclosure of the machine mount according to the invention can as far as possible completely encase the machine and thus essentially completely surround it. Essentially complete means that the enclosure completely surrounds the machine with the exception of cutouts, d. H. Openings, in the enclosure z. B. for machine connections, such as electrical connections and fluid mechanical connections. Thus, the machine can be held positively in the enclosure.

According to a development, the housing of the machine mount according to the invention may consist of a vibration-damping material, in particular a foamed material. In particular, the material may be a plastic. For example, a polyurethane foam material may be used for the enclosure.

As a result, the emission of airborne sound and structure-borne noise from the machine is further reduced.

According to a further development of the machine holder according to the invention, an inner shape of the holding device essentially corresponds to an outer shape of the housing. For example, the holding device surrounds the housing substantially completely.

Essentially completely in this context means that the holding device surrounds the predominant part of the housing. This means that the holding device can also have recesses on which the holding device does not bear against the housing, so that the housing is exposed at the recesses

According to a further development of the present invention, the housing of the machine mount has stiffening sections which, at least in a state in which the machine mount is mounted on the machine, form stiffer sections than remaining sections of the enclosure.

Other sections of the enclosure are all sections of the enclosure that do not belong to the stiffening sections. The stiffening sections have a higher rigidity than the other sections.

In the region of the stiffening sections, the material of the housing is stiffer at least in the mounting state of the machine mount, so that the housing in the region of the stiffening sections has a higher support effect than in the other sections of the enclosure.

The stiffening sections of the enclosure may be in the machine mount in abutment with the machine in the installed state of the machine. Additionally or alternatively, the stiffening portions of the housing may be in contact with the holding device.

The above-described stiffening portions may advantageously have compressible protrusions projecting from an inner side of the housing other than the outer shape of the machine. This means that the collapsible protrusions protrude from the inside of the housing in a non-installed state, but in an installed state of the housing to the machine, are compressed by the machine so that they no longer represent projections and lie flat against the machine.

The described stiffening portions may also be compressible protrusions projecting from an outer side of the housing deviating from an inner contour or an inner shape of the holding means. This means that the collapsible protrusions project from the outside of the housing in a non-installed state, but are compressed in a mounting state of the holding device to the housing by the housing so that they no longer represent projections and rest flat against the holding device.

The housing may also have a combination projections on the outside and on the inside.

In each of the cases described, compression of the protrusions creates areas of higher material density, resulting in increased stiffness in these areas in the form of stiffening sections. The stiffening sections then form pressure points or pressure surfaces.

This makes it possible with simple means to form stiffening sections on or in the enclosure.

The stiffening sections can be made of the same material as the other sections of the enclosure. This advantageously facilitates production of the enclosure.

The stiffening sections can also be formed integrally and thus form a single stiffening section.

This requires a very simple production, in particular if the stiffening sections are designed as compressible projections as described above. This means that the stiffening sections can be formed integrally with the other sections of the housing.

Alternatively, the stiffening sections may be made of a different material than the other sections of the enclosure. As a result, by targeted choice of material, a desired stiffening effect can be achieved.

Preferably, the stiffening sections are arranged at locations which are close to a center of gravity of the machine to be held. In particular, the stiffening sections can be arranged at locations through which main axes of the machine which intersect the center of gravity of the machine run. The main axes can z. B. be a longitudinal axis and transverse axes of a machine, the main axes are perpendicular to each other.

As a result, in the area of the center of gravity, the machine to be held is held somewhat more firmly, which has a positive effect on the vibration damping properties of the machine mount.

In the machine mount according to the invention, the housing can be formed at least in two parts. For example, the enclosure may consist of two half-shells.

As a result, the attachment of the housing to the machine is facilitated and it is possible to einhausen as completely as possible with the housing, d. H. to surround.

In the machine mount according to the invention, the fastening device may be at least two parts. For example, the fastening device may consist of two half-shells.

This allows the machine with the surrounding housing particularly easy to be fixed in all directions, so that the machine can not slip out of the machine holder. Furthermore, the fastening device can be easily mounted.

In the case of an at least two-part fastening device, the holding device can have mounting flanges in order to mount the at least two parts of the fastening device to one another.

The fastening device may further comprise mounting flanges for mounting the machine mount to a vehicle.

1 is a schematic side view of a machine holder 1 according to an embodiment of the present invention.

2 is another schematic side view of the machine holder 1 according to the embodiment of the present invention.

3 is a schematic plan view of the machine holder 1 according to the embodiment of the present invention.

4a is a schematic section of the machine holder 1 according to the embodiment of the present invention along the line AA in 1 without machine.

4b is a schematic section of the machine holder 1 according to the embodiment of the present invention along the line AA in 1 with a machine.

5a is a schematic section of the machine holder 1 according to the embodiment of the present invention along the line BB in 2 without machine.

5b is a schematic section of the machine holder 1 according to the embodiment of the present invention along the line BB in 2 with the machine.

An exemplary embodiment of the present invention will be described below with reference to the figures.

A machine 2 of the embodiment is, for example, an electrically driven refrigerant compressor for an air conditioning system in a motor vehicle and is shown schematically in the figures as a cylinder with a circular cross section without any connections. The machine 2 however, it may have any other geometric shape.

1 to 3 show a machine holder 1 according to the embodiment of the present invention in various exterior views.

4a shows a section along the line AA in 1 without a machine to be kept. On the contrary shows 4b a section along the line AA in 1 , where the machine holder 1 on a machine 2 is mounted. According to 4a and 4b has the machine holder 1 a first damping shell 3 and a second damping shell 4 that form an enclosure according to the invention. As in 4b are shown are the first damping shell 3 and second damping shell 4 on their insides to the outer contour of the machine 2 , in particular of the machine housing, adapted and surrounded the machine 2 almost complete and as far as possible. The damping shells 3 and 4 each have a part of a cylinder jacket and an end face / end face of a circular cylinder. As in 4a is shown, the first damping shell 3 and the second damping cup 4 on their cylinder jacket inner surfaces deviating from the outer contour of the machine 2 pressure pad 11 on, form the stiffening sections according to the invention. The Drurck pads 11 are in an area around the machine 2 arranged around, which is close to a center of gravity S of the machine 2 located. A focal point S of the machine 2 The present embodiment is located at a geometric center of the machine. In the figures, a longitudinal axis x, a vertical axis y and a transverse axis z of the machine run 2 through the center of gravity S. The pressure pad 11 are in a range of intersections of the vertical axis y of the machine 2 with the damping shells 3 and 4 arranged. Furthermore, as in 5a shown is pressure pad 12 in the region of points of intersection of the longitudinal axis x with both inner end faces of the damping shells 3 and 4 arranged The pressure pad 11 and 12 for example, have a height of 1 to 2 mm.

in modifications of the embodiment can also on the outside of the damping shells 3 and 4 be arranged in the region of the intersections with the vertical axis y and the longitudinal axis x corresponding pressure pad. Alternatively, the inner pressure pad 11 and 12 be omitted. Furthermore, pressure pads in the region of points of intersection of the transverse axis z with the damping shells 3 and 4 be arranged.

Furthermore, the first and the second damping shell 3 and 4 Not shown in the figures recesses in places where are connections of the machine 2 are located. The machine 2 So it is almost completely in the first and second damping shell 3 and 4 embedable and is thus form-fitting over the outer contour of the machine 2 supported.

The first damping shell 3 and the second damping cup 4 consist of a PU foam material that is open-pored, lightweight and soft. In a modification of this embodiment, the first and second damping shell exist 3 and 4 from an integral foam, which is closed-pore and has a higher density than the PU foam material. The integral foam, z. B. also consisting of polyurethane, is harder and mechanically stable than the open-pore PU foam material and less easily absorbs water through the closed pores. The damping properties of the open-pored PU foam material are better than the closed-cell integral foam.

Furthermore, the machine holder 1 a first holding cup 5 and a second holder 6 on, the mounting flanges at their ends 7 exhibit. The holding cups 5 and 6 and the mounting flanges 7 form a holding device according to the invention a fastening device. The first holding cup 5 and the second holder 6 are in their shape of the outer contour of the first damping shell 3 and the second damping shell 4 customized. The first holding cup 5 has a part of a cylinder jacket surface and on a front side a cylinder end face. The second holder 6 has the other part of a cylinder jacket surface and on the other end face a cylinder end face. The cylinder end face of the second holding shell 6 is particular in 1 to see. The cylinder end face of the first holding circuit 5 is trained accordingly. The mounting flanges 7 each have through holes 9 on. As in 4b can be seen, are in the mounted state, the mounting flanges 7 with the through holes 9 the first holding cup 5 and the mounting flanges 7 with the through holes 9 the second holder 6 opposite each other and are by means of screws passing through the through holes 9 the mounting flanges 7 are performed and not shown in the figures, connected to each other.

The first holding cup 5 and the second holding shells 6 consist of a stiff compared to the material of the damping shells material such. As metal or plastic.

The mounting flanges shown in the figures 7 also serve to attach the machine holder 1 including the machine 2 on a vehicle such as a vehicle body. This could include further through holes in the mounting flanges 7 be provided for attachment to the vehicle body or the existing through holes 9 could be used for this purpose. In addition to the holding device with the holding shells 5 and 6 and the mounting flanges 7 For example, the attachment means may comprise separate attachment flanges for attachment to the vehicle. Such mounting flanges can be mounted as needed and installation situation in the vehicle.

When assembling the machine 2 According to the first embodiment in the vehicle, first the first damping shell 3 and the second damping cup 4 to the machine 2 created. Thereupon, the first holding cup 5 and the second holder 6 on the outsides of the first damping shell 3 and the second damping shell 4 put on so that the mounting flanges 7 opposite each other, as already described above. Then the screws are in the through holes 9 introduced and tightened. When tightening the screws are the first and the second holder 5 and 6 attracted to each other, so that the first damping shell 3 as well as the second damping shell 4 in contact with the machine 2 come. This will be the pressure pad 11 and 12 that the machine 2 touch, squeezing, until the entire interior of the first damping shell 3 and the second damping shell 4 at the machine 2 is applied.

When assembled, the pressure pads form 11 and 12 in the first damping shell 3 and in the second damping shell 4 Areas of increased material density, so that these areas stiffer than other areas of the damping shells 3 and 4 and thus have a greater support effect than the other areas. After the pressure pad 11 and 12 near the intersections of major axes passing through the center of gravity of the compressor 2 are arranged, is a transmission of vibrations of the machine 2 minimized to the vehicle body.

The machine holder according to the invention is the machine 2 not directly connected to the body, but a large area in the soft damping shells 3 . 4 embedded, in turn, from the large-scale holding shells 5 . 6 are encompassed or in the holding shells 5 . 6 are embedded. Only the holders 5 . 6 yourself - or one of these holding shells 5 . 6 - are directly attached to the vehicle This is a transmission of vibrations from the machine 2 to the vehicle, in particular to the vehicle body, effectively prevented or at least significantly attenuated.

In a modification of the above-described embodiment, the damping shells 3 and 4 , in particular the outer sides of the damping shells 3 and 4 , for improved damping effect specifically by constructive measures, such as grooves, weakened.

Claims (10)

Machine holder for a machine ( 2 ) in a vehicle, wherein the machine mount ( 1 ) an enclosure ( 3 . 4 ) whose inner shape is essentially an external shape of the machine ( 2 ), and a fastening device for fastening the machine ( 2 ) to the vehicle, wherein the fastening device comprises a holding device ( 5 . 6 . 7 ) housing the enclosure ( 3 . 4 ). Machine support according to claim 1, wherein the housing ( 3 . 4 ) from a vibration damping material, in particular a foamed material exists. Machine holder according to one of the preceding claims, wherein an inner shape of the holding device ( 5 . 6 ) substantially an outer shape of the enclosure ( 3 . 4 ) and, for example, the enclosure ( 3 . 4 ) completely completely surrounds. Machine mounting according to one of the preceding claims, wherein the housing ( 3 . 4 ) Stiffening sections ( 11 . 12 ), which is at least in a condition in which the machine mount ( 1 ) at the machine ( 2 ), stiffer sections than remaining sections of the enclosure ( 3 . 4 ) train. A machine mount as claimed in claim 4, wherein the stiffening sections are compressible projections (Fig. 11 . 12 ) deviating from the external shape of the machine ( 2 ) from an inside of the enclosure ( 3 . 4 ) protrude and / or deviating from an inner shape of the holding device ( 5 . 6 ) from an outside of the enclosure ( 3 . 4 ) protrude. Machine support according to claim 4 or 5, wherein the stiffening sections ( 11 . 12 ) of the same material as the other sections of the enclosure ( 3 . 4 ) and / or wherein the stiffening sections ( 11 . 12 ) of a different material than the other sections of the enclosure ( 3 . 4 ) consist. Machine support according to one of claims 4 to 6, wherein the stiffening sections ( 11 . 12 ) are arranged at locations which correspond to a center of gravity of the machine to be held ( 2 ) are close. Machine mounting according to one of the preceding claims, wherein the housing ( 3 . 4 ) is formed at least in two parts, in particular from two half-shells. Machine mounting according to one of the preceding claims, wherein the fastening device ( 5 . 6 . 7 ) is formed at least in two parts, in particular from two half-shells. Machine with a machine holder according to one of claims 1 to 9.

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