RU2415354C1 - Resonator device installed in case of refrigerating unit - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: case forms compartment comprising compressor. The case consists of a pressure tight jacket and also an evaporating pan for defrosted water. The pan has a bottom wall designed for installation on an upper part of the jacket and periphery wall projecting on top from the bottom wall, At least one of periphery walls and the bottom wall of the evaporating pan bear a sound absorbing device turned in the direction of the noise generating zone of the said compartment. It is made with dimensions determining certain reactive impedance and certain impedance of absorption in medium of the compartment for a specified frequency range.

EFFECT: resonator deice efficiently damping noise generated with compressor and fan in wide frequency band without change of dimensions and thickness of compressor jacket.

47 cl, 28 dwg

Description

FIELD OF THE INVENTION

The present invention relates to a resonator device designed to be installed in a refrigeration unit case, namely: in that part in which the compressor of the refrigeration system of said refrigeration unit is located and in which, due to the operation of this compressor and / or fan, also installed in this part , usually noise is created. More specifically, the present invention relates to a resonator device for installing a defrosting system for refrigerating refrigeration systems in defrosting water in an evaporative drip tray, said evaporative dripping pan of this type being attached to a casing of a hermetic compressor of these refrigeration systems.

BACKGROUND OF THE INVENTION

The noise generated by the refrigerator can be determined in two spectral regions: at frequencies below about 2 kHz and at frequencies above this value.

In the first spectral range, determined by low frequencies, there is a strong interaction between the refrigerator and the compressor, through the excitation of the first acoustic resonances of the compartment located in the lower rear region of the refrigerator, in which the compressor of the refrigeration system of this refrigerator is installed. These frequencies mainly depend on the size of the specified compressor compartment, as well as on the spectral composition of the noise it generates. Another common source of noise in a refrigerator is a fan, which is usually located in the refrigerator in the same compartment as the compressor. In addition to generating high-frequency noise caused by air turbulence, the fan generates strong radiation with a frequency of passage of the blades, which is the product of the number of blades of the fan by the frequency of its rotation.

In the second spectral range, in which frequencies more than 2 kHz are usually generated, noise is generated directly by the compressor, without significant influence of the design or shape of the compartment of the refrigerator in which this compressor is installed.

The technical literature abounds with examples and applications of noise control technologies (Hansen H. "Engineering Noise Control", 2003, Spon Press; Lyon RH, "Machinery Noise and Diagnostics", 1987, Butterworth Publishers; Munjal ML "Acoustics of Ducts and Mufflers", 1987 , New York Wiley-Interscience).

In the prior art, the compartment 1 in which the compressor 2 is installed is usually covered with a soundproofing material MA (see FIG. 2), while the compartment 1 can also be covered with a plate P forming an end cap, also coated with a soundproofing material MA from the inside designed to cover a compartment whose inner walls, for example, as shown in FIG. 3, may not be covered by it. With this solution, the compressor after closing compartment 1 remains closed inside it.

When the control technologies described above cannot be used, this control must be carried out in the compressor itself by increasing the thickness of the casing or supplementing it with absorbing elements.

These technologies have some disadvantages, such as the high cost of soundproofing material for covering the compressor or closing the compartment, the need to make changes to the compressor, increasing its cost; compressor temperature increase; reduced fan efficiency; reduction in compressor efficiency; as well as the need to introduce additional operations in the production process of the refrigerator related to the placement and fastening of the cover and the element covering the compartment surrounding the compressor in the refrigerator.

Objectives of the invention

The first objective of the present invention is the creation of a resonator device for the refrigeration unit, which would effectively attenuate the compressor noise in a wide frequency band - at low and high frequencies.

The second objective of the present invention is the creation of the aforementioned resonator device, which would effectively attenuate the noise generated by a fan installed in the refrigerator in the region in which the compressor is located in a wide frequency band.

A third object of the present invention is to provide the aforementioned resonator device, which would effectively attenuate the noise generated by the cooling system in a wide frequency band.

A fourth object of the present invention is to provide the aforementioned resonator device, which would effectively attenuate resonance within the area of the refrigerator in which the compressor is located.

The fifth objective of the present invention is to provide the aforementioned resonator device, which would not require either a soundproof coating of the area of the refrigerator in which the compressor is located, or resizing of this area.

The sixth objective of the present invention is to provide the aforementioned resonator device, which would not require a change in the size and / or thickness of the compressor casing.

SUMMARY OF THE INVENTION

These and other objectives of the present invention are achieved by creating a resonator device for the refrigeration unit, the specified body forming a compartment in which it carries a compressor, which is a sealed casing, as well as an evaporation tray for defrosted water, comprising: a bottom wall for installation on the upper part of the compressor casing, as well as the peripheral wall protruding from the bottom of the bottom wall, and at least one of the peripheral wall and the bottom wall of the evaporation tray a set of sound-absorbing means on itself, basically at least one resonant channel, which is rotated in the direction of the noise generation zone in the said compartment and made with dimensions defining a specific reactive impedance and a certain absorption impedance in the compartment medium for a given frequency range.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will now be described with reference to the accompanying drawings, given as examples of possible embodiments of the present invention.

Figure 1 schematically represents a longitudinal section of a refrigeration unit, in the lower back of which there is a compartment with a refrigeration compressor installed in it, carrying an evaporation tray on top of it.

Figure 2 schematically represents a longitudinal section of the refrigeration unit shown in figure 1, but in which, in accordance with the prior art, the compartment with the refrigeration compressor installed therein is covered with sound-absorbing material.

Figure 3 schematically represents a local section of the refrigeration unit shown in figure 1 and having a refrigeration compressor compartment, covered by a sound-absorbing wall made in accordance with the prior art.

FIG. 4 is a schematic enlarged view of a refrigeration compressor bearing an evaporation tray shown in FIG. 1, but the evaporation tray itself is constructed in accordance with a first embodiment of the present invention.

Fig. 4a schematically represents a modification of a first structural embodiment of an evaporation tray in accordance with the present invention in the form in which it is shown in Fig. 4.

Figure 5 schematically represents a top view of the evaporation tray shown in figure 4.

FIG. 6 schematically represents a longitudinal section of the vaporization tray shown in FIG. 5 along the line VI-VI in FIG. 5.

FIG. 7 schematically represents a view of the device shown in FIG. 5 in accordance with a second structural embodiment of the present invention.

Fig. 8 is a schematic cross-sectional view of the evaporation tray shown in Fig. 6 along line VIII-VIII in Fig. 7.

Fig.9 schematically represents a view of the device shown in Fig.5, in accordance with the third and fourth structural embodiments of the present invention.

Figa schematically represents the view shown in Fig.9, in accordance with structural modifications of the third and fourth structural options shown in Fig.9.

Figure 10 schematically represents a section of the evaporation tray shown in Fig. 8, along the line XX in Fig. 9.

11 is a schematic view shown in FIG. 9 in accordance with a fourth structural embodiment of the present invention.

Fig. 12 schematically represents a section similar to that shown in Fig. 10, taken along the line XII-XII in Fig. 11.

Fig.13 schematically represents the view shown in Fig.9, in accordance with the fifth structural embodiment of the present invention.

Fig.14 schematically represents the view shown in Fig.13, along the second line XIV-XIV in Fig.13.

Figa schematically represents the view shown in Fig.8, in accordance with the sixth structural embodiment of the present invention.

Fig. 15b schematically represents the view shown in Fig. 15a, in accordance with a modification of the sixth structural embodiment of the present invention.

FIG. 15 c is a schematic view of FIG. 15 a, in accordance with another modification of a sixth embodiment of the present invention.

Fig. 15d schematically represents the view shown in Fig. 15a, in accordance with a seventh embodiment of the present invention.

FIG. 16a is a schematic cross-sectional view of FIG. 10 for an eighth structural embodiment of the present invention, taken along line XVI-XVI shown in FIG. 9.

Fig.16b schematically represents the view shown in Fig.16a, in accordance with a modification of the eighth structural embodiment of the present invention.

Fig. 16c schematically represents the view shown in Fig. 16a, in accordance with another modification of the eighth structural embodiment of the present invention.

FIG. 17a is a schematic cross-sectional view of FIG. 10 for a ninth embodiment of the present invention, taken along line XVII-XVII shown in FIG. 9.

Fig.17b schematically represents the view shown in Fig.17a, in accordance with the first modification of the ninth structural variant of the present invention.

FIG. 17 c is a schematic view of FIG. 17 a, in accordance with a modification of the ninth embodiment of the present invention.

Fig.17d schematically represents the view shown in Fig.17a, in accordance with the third modification of the ninth structural variant of the present invention.

Fig.17e schematically represents the view shown in Fig.17a, in accordance with the fourth modification of the ninth structural variant of the present invention.

DESCRIPTION OF ILLUSTRATED EMBODIMENTS

The present invention is a technical solution to the problem of reducing noise arising in the region of the aforementioned compartment 1, made in the lower rear part of the housing 3 of the refrigeration unit (for example, in the form of a refrigerator or freezer).

The compartment 1 is formed by a recess in the rear wall 3a of the housing 3 of the refrigeration unit.

As shown in the drawing, on top of the compressor 2 carries an evaporation tray 4, made in size with the possibility of receiving and containing water, resulting from the process of defrosting the refrigeration system of the refrigeration unit, and this evaporation tray 4 is a tray of the type that is mounted on a sealed casing 2a of compressor 2 of the refrigeration system.

In this design solution, the landing of the evaporation tray 4 on the casing 2a of the compressor 2 primarily allows the tray to be heated by the heat generated by the compressor 2 during its operation, thereby contributing to the evaporation of the accumulated water. The evaporation tray 4 is held on the compressor 2 by appropriate means, for example using glue, adhesive materials, etc., which is not the subject of the present invention.

As shown in the drawings, in one possible solution, the evaporation tray 4 is made of a heat-resistant plastic material, such as high-strength polypropylene, usually molded to give it a complete shape, including a bottom wall 4a, combined with a peripheral wall 4b having a height sufficient to the formation of the cumulative volume of defrosted water necessary for the operation of the refrigeration system to which it will be applied. In an optional design, the evaporation tray 4 is made as a single element.

In the bottom wall 4a of the evaporation tray 4, a lower recess (not shown) can be made, generally defined as a lower surface, with dimensions that allow it to sit for a certain length on the end surface of the casing 2a of compressor 2. It should be understood that the lower recess may have such a shape and dimensions that correspond to the contour of the upper part of the casing 2a of the compressor 2, so as to allow the vaporization tray 4 to fit and fit on the upper part of the casing 2a of the compressor 2, thereby increasing ju stable placement on the latter and increase heat transfer with compressor 2.

In accordance with the present invention, noise attenuation in the compartment 1 is achieved by installing an evaporation tray 10 carrying sound absorbing means, which is located, facing the direction of the noise generation region, in the aforementioned compartment 1, the sound absorbing means being sized to form a certain reactive impedance and a certain absorption impedance in the medium of compartment 1 for at least one particular frequency range or for all frequencies at which the generation takes place noise. The sound absorption means carried by the vaporization tray 10 can take a variety of forms within the framework of the concept presented here, some of which will be discussed later.

As described below, the present invention allows the attenuation of noise generated by the compressor 2 or other sources, such as fans, for example, installed in the compartment 1 of the refrigeration unit. In addition, the sound-absorbing means in accordance with the present invention can be used to completely or partially suppress the resonant effect that occurs in the compartment 1 of the housing 3 of the refrigeration unit.

The evaporation tray 10 in accordance with the present invention is represented by a bottom wall 11 and a peripheral wall 12, which are structurally made in a form similar to that of the vaporization tray 4 of the prior art.

In one embodiment of the present invention, the sound-absorbing means comprises at least one resonator channel 20 formed in the evaporation tray 10, located along the extension of at least one bottom wall 11 and the peripheral wall 12 of the evaporation tray 10, and this resonator channel 20, which is a structure in the specified evaporation tray 10, is formed in such a way that the first end 21 of the resonator channel 20 is located rotated in the direction of the noise generation region in the compartment 1. In addition o, resonator 20 has a second end 22 disposed opposite the first end 21 and remote from it.

Although the objectives of the present invention can be achieved using a single resonator channel 20, in the structural embodiments described here and illustrated in FIGS. 4-14, the vaporization tray 10 carries at least one of the bottom wall 11 and the peripheral wall 12 a sound-absorbing means consisting of a plurality resonator channels 20, at least part of which is the construction described above, in which the first end 21 of each resonator channel 20 is rotated in the direction of the noise generation region in about tseke 1.

Each resonator channel 20 is dimensioned so that it has a predetermined length and a predetermined diameter that are designed to create a specific reactive impedance and a specific absorption impedance in the medium of compartment 1 for at least one predetermined frequency range.

The length of the resonator channels 20 is calculated taking into account the frequency or frequency band that will need to be damped, and the difference between the lengths of the resonator channels 20 depends both on the bandwidth and the attenuation of noise necessary for each case, that is, for the characteristics of each compartment one.

In accordance with the present invention, at least a portion of the resonator channels 20 in any of the structures described herein may have a constant or variable cross section along their lengths, the shape and “behavior” of this cross section being determined depending on the desired effect of noise attenuation, on the possibility of their execution, etc. Some of the possible length cross-sections within the framework of the concept of necessary noise attenuation are as follows: cylindrical, conical, exponential or stepwise, and as for the shape, it can be ordinary, that is, rectangular, circular, polygonal or even irregular, as is the case with the use of fibrous pores materials.

To obtain the desired effect, the resonator channels 20 must be tuned to frequencies or frequency bands that represent the levels to be controlled, and this setting is determined by the length and type of completion of the second end 22, open or closed, of each of the resonator channels 20.

In a preferred embodiment of the present invention, the second end 22 of each of the resonator channels 20 is closed. However, it should be understood that in accordance with the present invention, the second end 22 may be open, and this condition is determined depending on the necessary attenuation characteristics, as well as on the location of the corresponding resonator channel 20 in the evaporation tray 10 and / or in another housing containing the specified a resonator channel 20, such as a tubular sleeve 30 or a peripheral ring 40, which will be described later.

The number of resonator channels 20 is calculated based on the consideration of the possibility of tuning each of them to different frequencies in order to coordinate the attenuation of noise generated by the compressor 2 at several different frequencies. These frequencies can either be very spaced apart or close, thus forming a weakening band.

The evaporation tray 10 carries the described sound-absorbing means made in the form of resonator channels 20, for example, incorporating them into the inner and outer surfaces of at least one of its bottom wall 11 and the peripheral wall 12, as shown in FIGS. 4, 4a, 7 and 8, in addition, each resonator channel 20 can be made in the thickness of the bottom wall 11 or the peripheral wall 12 (or both) of the evaporation tray 10, as shown in FIGS. 5 and 6.

The integration of each resonator channel 20 can be complete (see Figs. 4, 4a, 7 and 8), as in the case when the resonator channel 20 is made in the thickness of the corresponding wall of the evaporation tray 10, or partial (see Figs. 11-14 ) - in cases where at least part of the length of the resonator channel 20 by adjacent parts of the surface of the corresponding bottom wall 11 and / or the peripheral wall 12 of the evaporation tray 10, which contains these resonator channels 20, are formed as a single element. In these cases, the parts that form a cross section of the resonator channel 20 can be formed in one of the structural forms described below using a tubular sleeve 30, a peripheral ring 40, or, in addition, by connecting to each resonator channel 20 formed in the evaporation tray 10, the corresponding additional element, which completes the peripheral circuit of this resonator channel 20, as a result of which its closed section is created at least along the length of the resonator channel 20, tvechayuschego for attenuation of the noise in the frequency band for which the resonator 20 is designed.

Taking into account the distribution of attenuated noise in the compartment 1 for performing the described sound-absorbing means using the resonator channels 20, the present invention allows various configurations of the device of the resonator channels 20 in the evaporation tray 10, as well as the number of resonator channels 20 of the same configuration, the same size and design parameters in the evaporative pallet 10, which are calculated depending on the zone where the maximum noise in the compartment 1 is recorded, as well as on the bands s of the frequency at which attenuation is to be performed in this area. In one embodiment of the present invention, the resonator channels 20 have at least one of the diameter and length parameters being the same. However, it should be understood that the dimensions of the resonator channels 20 may be the same or different depending on the intended result of noise attenuation. Thus, if it is necessary to increase the bandwidth of the noise attenuation frequencies, then the resonator channels will differ in size from each other. If the noise attenuation should be more significant in a certain narrow frequency band, then the resonator channels 20 should have the same dimensions.

Resonator channels 20 are installed on the evaporation tray 10 in order to prevent or attenuate the propagation of sound waves in it, their reflection or scattering. Such resonator channels 20 alter the local impedance. When installed in the zones of maximum modal pressure, the resonator channels 20 operate with the extraction (dissipation) of energy from this zone of the compartment 1, reducing the resonant effect. In the general case, the resonator channels 20 increase the acoustic attenuation at the frequencies to which they are tuned.

It should be understood that the evaporation tray 10 may comprise resonator channels 20 directly formed in at least one of its bottom wall 11 and the peripheral wall 12, or also at least partially formed by a tubular sleeve 30 or a peripheral ring 40, as previously described.

Regarding any of the possible forms of the resonator channels 20, which carries the evaporation tray 10, it should be noted that, regardless of the size of the compartment 1 of the housing 3 of the refrigeration unit, the ends of the resonator channels 20 should be located above the evaporation tray 10, not protruding too much from its upper edge, preferably with maximum coincidence with the upper edge of the evaporation tray 10. The end of each resonator channel 20, located in the lower part of the evaporation tray 10, can be located behind the lower edge of the feriynoy wall 12 of said evaporating tray 10, unless such their projecting position does not affect the setting of the evaporating tray 10 onto the refrigeration compressor 1, nor its size or function.

In a design in which the evaporation tray 10 comprises a tubular sleeve 30, the latter is installed adjacent to one of the bottom wall 11 and the peripheral wall 12 of the evaporation tray 10, from the inside or outside, along the entire peripheral contour of the adjacent bottom wall 11 or the peripheral wall 12 while the cross section of at least one resonator channel 20 formed by parts of the evaporation tray 10 and the tubular sleeve 30 is partially determined in each of these parts.

The tubular sleeve 30 may surround at least a portion of the longitudinal length of the wall of the evaporation tray 10 that carries it, with each resonator channel 20 having a portion of its cross section that is formed by the opposite or adjacent surface of the specified wall of the evaporation tray 10 and the tubular sleeve 30.

In this embodiment of the present invention, at least a portion of the lengths of at least a portion of the resonator channels 20 are formed by a combination of two parts, one of which is formed in the wall of the evaporation tray 10, and the second is formed by a tubular sleeve 30 carried by the evaporation tray 10.

In the illustrated embodiments, the tubular sleeve 30 is a wall of a predetermined thickness predefined depending on the required structural rigidity and the cross section of the resonator channels, which it partially forms, said tubular sleeve 30 being an inner surface opposite to the surface adjacent to the evaporation tray 10 , and the contour and cross section of the resonator channels 20 are partially determined by each of the opposite adjacent surfaces tr roll sleeve 30 and the adjacent wall of the evaporation tray 10.

In accordance with the present invention, at least a portion of the length of at least one of the resonator channels 20 extends along a straight or curved path along the extension of the corresponding bottom wall 11 and / or the peripheral wall 12 of the evaporation tray 10 and / or tubular sleeve 30. In one embodiment of the present invention, the resonator channels 20 are straight for at least part of their extension.

In one structural embodiment of the present invention, at least two resonator channels 20 are parallel to each other or parallel to each other in the rows of resonator channels 20, and these resonator channels 20 are vertically or horizontally located relative to the corresponding part of the evaporation tray 10 and / or relative to the tubular sleeve thirty.

The location of at least a portion of the resonator channels 20 may also be inclined with respect to the longitudinal wall length of the evaporation tray 10 and / or tubular sleeve 30, where at least a portion of the resonator channel 20 is located, and this arrangement may, for example, be diagonal to said wall which resonator channels 20 are made. Such designs with a pronounced slope of the resonator channels 20 relative to the adjacent wall of the evaporation tray 10 can also be found in such a design x, in which these resonator channels 20 are partially or completely made in a tubular sleeve 30 or in a peripheral ring 40.

The shape of the resonator channels 20, for example parallel, horizontal, vertical, inclined, straight, curved or a combination thereof, depends on the desired attenuation effect, which these resonator channels 20 must produce in compartment 1, and / or on the direction of at least the first ends resonator channels 20 relative to the noise generation zone. In the embodiment of the invention shown in FIG. 4, the resonator channel 20 is arranged horizontally in the peripheral wall 12 of the evaporation tray 10, while the other resonator channels are arranged vertically. It should be understood that the location of the resonator channels 20 in their bearing part is determined depending on the necessary orientation of these resonator channels 20 relative to the area of the compartment 1 generating the attenuated noise. Thus, designs are possible in the form of groups of resonator channels 20 located on the evaporation tray 10 and / or tubular sleeve 30 in certain directions, formed in such a way that the first end 21 of the resonator channels 20 of each of their groups is directed to a predetermined area of the compartment 1 to be attenuation of noise, and the sizes of these groups of resonator channels are selected based on the band of attenuated frequencies of each zone of compartment 1, towards which the first ends of the 21 groups are directed.

The arrangement of the resonator channels 20 in accordance with the present invention allows you to tune each resonator channel to a different frequency, but very close to the frequency of another resonator channel 20, for example, adjacent resonator channel 20, in order to form a wide frequency range in which it is assumed to attenuate the noise by arranging these resonator channels 20.

In the constructive form in which the resonator channels 20 are at least partially held by a part of the adjacent surface of the corresponding wall of the evaporation tray 10, these resonator channels 20 can be made in the form of closed tubes attached to the wall surface of the evaporation tray 10, or these tubes can form part of the cross section of the resonator channel 20, while the other part is formed by the opposite adjacent part of the surface of the tubular sleeve 30 located on the evaporate in order to complete the peripheral contour of each resonator channel 20, formed by the parts of the evaporation tray 10 and the tubular sleeve 30. In this design, each resonator channel 20 is formed by a recess, which will be described later, made in at least one of the opposite surfaces evaporation tray 10 and tubular sleeve 30.

In the constructive embodiment shown in FIGS. 4-6, the resonator channels 20 are formed as a single part with the evaporation tray 10, for example, during its manufacture, that is, these resonator channels 20 are pre-formed in a mold designed to form the evaporation tray 10 It should be noted, however, that the resonator channels 20 can also be formed at the end of the formation of the evaporation tray 10, for example, by attaching, at least to its part of the peripheral wall 12, a plurality of tubes, each of which forms a reason the orifice channel 20. In this constructive embodiment, the peripheral wall 12 can either be hollow, and resonator channels 20 are placed and / or mounted in it, or it can hold the peripheral flange element surrounding part of the peripheral circuit of the peripheral wall 12 of the indicated evaporation tray 10 or all of this contour, and maintain the adjacent peripheral part of the edge of each resonator channel 20.

In the constructive embodiment shown in FIGS. 4, 4a, 7 and 8, the resonator channels 20 are made as a single part with the evaporation tray 10, for example, during its molding, as described above, or these resonator channels 20 are attached by appropriate means to the outer side of the peripheral wall 12. While various types of design of the evaporation tray 10, including the resonator channels 20, have the advantage of facilitating and cheapening the formation of these resonator channels 20, the structural I, associated with the retention, by installing and / or fixing the said resonator channels 20 in the evaporation tray 10, have the advantage of greater structural flexibility with respect to the formation of special configurations of the resonator devices designed for specified areas of compartment 1, presumably having a high the noise level to be attenuated, as well as for one or more frequency bands also subject to local attenuation. Another advantage of this design is that such configurations can be provided in already existing on the market evaporation trays 10.

In another constructive embodiment of the present invention described below, the evaporation tray 10 carries resonator channels 20 by installing around at least part of the contour of its peripheral wall 12 of the tubular sleeve 30, which is fully (see Figs. 9, 9a and 10) or partially (see 11-14) forms the resonator channels 20.

In the structural embodiment shown in Fig. 9a, a tubular sleeve 30 is mounted around the entire contour of the adjacent peripheral wall 12 of the evaporation tray 10 so that the inner surface is opposite the outer surface of the specified peripheral wall 12 of the evaporation tray 10, next to which this tubular sleeve 30 is mounted In this design, the tubular sleeve 30 is given such a profile that coincides with the profile of the peripheral wall 12 of the evaporation tray 10 so that it can either fit snugly around it, or sediment from it with a radial clearance predefined in the design.

In the construction shown in FIG. 9, the evaporation tray 10 carries at least around a portion of the contour of its peripheral wall 12 a tubular sleeve 30 that is secured by suitable means to this evaporation tray 10, for example by means of glue, clamps, pin-type fasteners - a socket mounted on the indicated parts of the evaporation tray 10 and the tubular sleeve 30, or by other suitable means. In the shown design, the mounting of the tubular sleeve 30 to the evaporation tray 10 is carried out by fitting the inner flange (not shown in the figure) to the adjacent edge of the peripheral wall 12 of the evaporation tray 10. This mounting is supported by appropriate fixing means, namely, mechanical interaction, clamps, screws, etc. d. The tubular sleeve 30 has an upper flange 30a, forming on the periphery of the edge of this tubular sleeve 30, external to the resonator channels 20.

In the constructive embodiment shown in FIGS. 11-14, the peripheral circuit of each resonator channel 20 is partially formed by the peripheral wall 12 of the evaporation tray 10, and partially by the adjacent opposite surface of the tubular sleeve 30 so that the closure of these circuits forms a cross section of each resonator channel 20 .

In the constructive embodiment shown in FIGS. 11 and 12, the tubular sleeve 30 is shaped so as to form a part of the contour of each resonator channel 20, for example, in the form of a recess 33, which forms the arc part of the corresponding resonator channel 20, the adjacent end surface of the peripheral wall 12 the evaporation tray 10 forms a rectilinear contour for each resonator channel 20. In this embodiment, the evaporation tray 10 has the same configuration as conventional evaporation trays 4, and the volume of each cut Nator channel 20 is determined by the shape of the tubular sleeve 30. Although the drawings show a design in which the contour of each resonator channel 20 is arc, it should be understood that other forms of the circuit are possible within the framework of the concept presented here.

In this design, the tubular sleeves 30 are made, for example, with arc recesses, each of which forms part of the corresponding resonant channel 20.

Each recess 33 can be made along the length of the corresponding peripheral wall 12 of the evaporation tray 10 or inclined relative to the plane of the rear wall of the housing 3 of the refrigeration unit, in which the compartment 1 is formed.

In the embodiment shown in FIGS. 13 and 14, the inner surface of the tubular sleeve 30, as well as the outer surface of the evaporation tray 10 are matched so as to form a part of the contour of each resonator channel 20. In this design, each part of the evaporation tray 10 and the tubular sleeve 30 has corresponding recesses 13, 33, as described above, each of which forms a corresponding part of the circuit of the resonator channel 20. In this design option, each of the recesses 13, 33 forms a part of the arc circuit, respectively stvuyuschego resonator 20.

It should be understood that the resonator channels 20 can be made only on a part of the length of the peripheral wall 12 of the evaporation tray 10 and / or tubular sleeve 30, and the positioning of the specified resonator channel 20 can also be performed with a certain direction for a specific noise attenuation or a certain predetermined frequency band. This design allows for a specific and directional installation of the resonator channels 20 in the area of the compartment 1 in accordance with the established need.

In accordance with the present invention, at least one of the parts of the bottom wall 11 and the peripheral wall 12 of the evaporation tray 10, the tubular sleeve 30 and at least one resonant channel 20 can also be formed of a porous or fibrous material (see Fig. 15d), provided that it forms pores. In such a solution, the part formed in the porous material can be obtained, for example, by directly introducing it into the porous material. In the case of the execution of the evaporation tray 10 in a porous material, it is introduced as a single part, for example, into a polymer or into a fibrous material. In those designs in which the evaporation tray 10 is defined as a single part with resonator channels 20, it can also be obtained by injecting a porous material, which also determines the noise absorption means in accordance with the present invention.

However, it should be understood that the effect of the desired noise attenuation can be obtained while at least one of these parts is covered with a porous material (see FIGS. 15a-15c). The coating can be performed, for example, with pieces in the form of plates of porous or fibrous material added to the corresponding part by appropriate fastening, and this coating material can be located in the specified part in any position and in any geometry determined depending on the area of occurrence to be weakened noise.

It should also be borne in mind that some of the previously mentioned elements should be coated with a porous material, while others can simply be made of a porous material having the required sound-absorbing characteristics that determine a specific reactive impedance and / or a certain absorption impedance in the medium of compartment 1 at least one predetermined frequency range.

In order to achieve the desired effect, the pore-provided part must be made or coated so that the pores located on the surface in contact with the water in the evaporation tray 10 are closed, while the opposite surface must have open pores. Pores are obtained during a special production process, and they must have dimensions, for example, more than 20 microns.

In one embodiment of the present invention, the considered porous materials may include materials such as polystyrene, polypropylene, as well as metallic materials, such as aluminum. In structures using non-metallic porous material, at least a portion of the pores of this material is open. However, in structures using a porous metal material, the pores of such a material are closed.

In another embodiment of the present invention, the sound-absorbing means comprise a peripheral ring 40 which is mounted on the evaporation tray 10, on the inside or on the outside of its peripheral wall 12, and provided with at least one resonator channel 20 of the type previously described. In the structure shown in FIGS. 9, 9a and 17a-17e, the peripheral ring 40 carries a plurality of resonator channels 20.

In accordance with the present invention, the peripheral ring 40 has a predetermined thickness in which at least a portion of the resonator channels 20 carried by this peripheral ring 40 can be formed. In embodiments of the present invention, the peripheral ring 40 is formed together with the vaporization tray 10 using an injection process . In this process, resonator channels 20 can also be formed by injection, all in the form of a single part. However, it should be understood that each part of the evaporation tray 10, the peripheral ring 40 and the resonator channels 20 can be produced - by an injection process or other suitable technology for this - and separately or by forming a single part, made in one form and from one material, while the rest details can be attached by appropriate means to them later.

The design of the peripheral ring 40 makes it possible to form the resonator channels 20 installed in this peripheral ring 40, after its manufacture or also after installing the specified peripheral ring 40 on the evaporation tray 10, for example, around its peripheral wall 12. Fitting and fixing the peripheral ring 40 to the evaporation tray 10, as well as the installation and fastening of the resonator channels 20 in the specified peripheral ring 40 can be performed, for example, using glue, clamps, welding, mechanical cutting by action, etc.

In the illustrated structural embodiments, the peripheral ring 40 is formed separately from the evaporation tray 10, and then attached to it, from the outside to the peripheral wall 12 of the evaporation tray 10, for example, near the upper edge of the specified peripheral wall 12, while at least in part of the peripheral rings 40 pockets are formed for receiving a plurality of resonator channels 20. In such a design, a peripheral ring 40 supports each resonator channel 20 from above. However, it should be understood that this design it is not limiting — it merely indicates a method of performing the present invention illustrated herein.

In another design, the peripheral ring 40 is installed in the middle around the peripheral wall 12 of the evaporation tray 10, and the resonator channels 20 are supported by this peripheral ring 40 in the middle or top, depending on the length of the resonator channels 20 and the desired location of their upper ends relative to the upper edge of the evaporation tray 10.

In another embodiment of the present invention, the peripheral ring 40 is made in the form of a single part with an evaporation tray 10, for example, from a peripheral flange 10a protruding radially from the peripheral wall 12 of the evaporation tray 10. In this embodiment, the peripheral flange (10a) protrudes outward from above peripheral wall 12. Although not shown, the peripheral contour of each resonator channel 20 can partially be formed by the peripheral wall 12 of the evaporation tray 10, and partially by the peripheral ring ohm 40 so that the completion of these circuits determines the cross section of each of the resonator channels 20. In this design, the peripheral ring 40 has a shape that could define a part of each resonator channel 20, for example, as previously described, in the form of a recess, forming the arc part of the corresponding resonator channel 20.

As previously described for designs with a tubular sleeve 30, the solution associated with the peripheral ring 40 can be applied to conventionally shaped evaporation trays and already available on the market, while the structural forms of the resonator channels 20 are the same as those that have already been discussed earlier. In this case, the peripheral ring 40 carries resonator channels 20 that are fully aligned with it, and in the case of partial coordination, a part of the circuit of each resonator channel 20 is formed by the adjacent part opposite the outer part of the surface of the peripheral wall 12 of the evaporation tray 10.

The peripheral ring 40, like the tubular sleeve 30, is held on the evaporation tray 10 using appropriate holding means - glue, welding, clamps, pins, mechanical interaction, etc.

In accordance with the present invention, at least one of the parts of the bottom wall 11 and the peripheral wall 12 of the evaporation tray 10, as well as the peripheral ring 40 and at least one resonator channel 20 are made of porous material. However, it should be understood that the effect of the required noise attenuation can be obtained while at least one of these parts is covered with a porous material. It should also be borne in mind that some of the above parts can be coated with a porous material, while others can simply be made of a porous material having the required sound absorption characteristics that determine a specific reactive impedance and / or a specific absorption impedance in the medium of compartment 1 at least one predetermined frequency range.

In one embodiment of the present invention, the materials in question may be porous materials formed from polystyrene, polypropylene, as well as a metal material, such as aluminum. In structures using non-metallic porous materials, at least a portion of the pores of this material is open. However, in structures using metallic porous materials, the pores of such a material are closed.

In another embodiment of the present invention, sound-absorbing means are formed by a plurality of pores 50, each of which has a first end portion 51 that is open and rotated in the direction of the noise zone in compartment 1, where the evaporation tray 10 is located, and the second end portion 52 is located opposite the first end portion 51 away from it, and each pore 50 is made with such dimensions as to have a predetermined internal cross-section, designed to receive a specific reactive impedance and / or a specific impedance absorption in the medium of compartment 1 for a given frequency range.

The pores 50 are formed in a porous material that is used to fabricate at least one of the peripheral wall 12 and the bottom wall 11 of the evaporation tray 10 or which is used to cover at least a portion of said vaporization tray 10 or, for example, at least one of the peripheral wall 12 and the bottom wall 11 of this evaporation tray 10, and this porous material is made of a material that is selected from materials such as polystyrene polymer, polypropylene, as well as metal materials s, for example aluminum.

However, it should be understood that the effect of the required noise attenuation can be obtained while some of the above parts are coated with a porous material, while others can be directly made of a porous material having the required sound absorption characteristics that determine a specific reactive impedance and / or a certain absorption impedance in the medium of the compartment 1 for at least one predetermined frequency range.

In structures using non-metallic porous materials, at least a portion of the pores of this material can be opened. However, in structures using metallic porous materials, the pores of such a material are closed.

Although only some of the above constructions are illustrated, it should be understood that the concept presented above is not limited to the drawings.

One of the advantages of the present invention is the increase in noise attenuation in the area of the compartment 1 of the housing 3 of the refrigeration units at individual frequencies or in the frequency ranges in which this negative phenomenon is observed.

The arrangement of the resonator channels 20 of the present invention allows the attenuation of the noise generated by both the compressor and the fan (due to air turbulence occurring on its blades when they rotate), both of which are installed in the compartment 1 of the refrigeration unit, as well as the noise of the refrigeration system, and, in addition, it makes it possible to attenuate the resonance that may occur in said compartment 1, and also to reduce costs compared with the prior art.

Structures in which the resonator channels 20 are made as a single part with an evaporation tray also have the advantage that no other components or materials are added to the compartment 1. In these structures, the presence of resonator channels 20, in each of which the corresponding second end is open, also makes it possible to use each of these resonator channels 20 as a storage of defrosted water.

Resonator channels 20 make it possible to produce them of various lengths, which makes it possible to perform noise attenuation at several separate frequencies or in a wide frequency band. The diameter of each resonant channel 20, as well as the shape of the corresponding cross-section, can be selected in accordance with the production process, as well as in accordance with its size and the degree of necessary noise attenuation. The choice of the diameters of the resonator channels — up to 1 mm or more — determines the character of attenuation of noise by a particular resonator channel, from completely dissipative (small diameters) to completely reactive (large diameters).

The resonator channels 20 can be distributed along the contour of the peripheral wall 12 so that their lengths have a stepwise distribution in the desired direction to attenuate a given frequency band or random, when there is no specific frequency range for noise suppression and these frequencies are random in compartment 1 way.

Although not shown, using the resonator device in accordance with the present invention, the attenuation of noise at tunable frequencies can reach from 5 to 20 dB.

Specific features of the present invention are shown in the figures of the attached drawings for convenience only. Each such feature may be combined with other features in accordance with the present invention. Those skilled in the art can develop alternative embodiments of the present invention, which are intended to be within the scope of the claims. Accordingly, the above description should be considered as illustrative, not limiting the scope of the present invention. All obvious changes and variations of the present invention are within the scope of the invention defined by the appended claims.

Claims (47)

1. A resonator device for a refrigeration unit case, said case (3) forming a compartment (1) in which it supports a compressor (2), which is a sealed casing (2a), as well as an evaporation tray (10) for defrosted water, containing a bottom wall (11) intended to be mounted on the upper part of the casing (2a) of the compressor (2), as well as a peripheral wall (12) protruding from above the bottom wall (11), characterized in that at least one of the peripheral wall ( 12) and the bottom wall (11) of the evaporation tray (10) carries on Sound absorbing means (20, 30, 40, 50) turned in the direction of the noise generation zone in the said compartment (1) and made with dimensions that determine a specific reactive impedance and a certain absorption impedance in the compartment environment (1) for a given frequency range. 2. The device according to claim 1, characterized in that the sound-absorbing means comprises at least one resonator channel (20) extending along the entire length of the corresponding wall (11), (12) of the evaporation tray (10). 3. The device according to claim 2, characterized in that each resonator channel (20) has a first end (21) that is open and rotated in the direction of the noise generation zone in said compartment (1), and a second end located opposite the first end ( 21) and remote from it, and each resonator channel (20) is made with such dimensions that it has a given length and a given diameter, which are designed to create a specific reactive impedance and a certain absorption impedance in the compartment medium (1) for one given frequency range. 4. The device according to claim 3, characterized in that at least one resonator channel (20) is at least partially made in the form of a single element with an adjacent part of the surface of the corresponding wall (11), (12) of the evaporation tray (10). 5. The device according to claim 4, characterized in that at least part of the length of each resonator channel (20) is formed in the thickness of the corresponding wall (11), (12) of the evaporation tray (10). 6. The device according to claim 5, characterized in that the evaporation tray (10) carries a tubular sleeve (30), and the cross section of the resonator channels (20) is partially determined in each part of the evaporation tray (10) and the tubular sleeve (30) ) 7. The device according to claim 6, characterized in that the tubular sleeve (30) is a surface opposing the adjacent surface of the wall (11), (12) of the evaporation tray (10), and each resonator channel (20) is formed by a recess (13) , (33) made in at least one opposing surface of the tubular sleeve (30) and in the adjacent wall (11), (12) of the evaporation tray (10). 8. The device according to claim 7, characterized in that the tubular sleeve (30) occupies an internal and external position with respect to the peripheral wall (11), (12) of the evaporation tray (10). 9. The device according to claim 8, characterized in that at least one of the parts of the peripheral wall (12) and the bottom wall (11) of the evaporation tray (10), tubular sleeve (30) and at least one resonant channel (20) made of porous or fibrous material. 10. The device according to claim 8, characterized in that at least one of the parts of the peripheral wall (12) and the bottom wall (11) of the evaporation tray (10), tubular sleeve (30) and at least one resonant channel (20) covered with porous or fibrous material. 11. The device according to any one of paragraphs.9 and 10, characterized in that the porous material is formed by a material selected from a polymer of polystyrene, polypropylene and from a metal material. 12. The device according to claim 11, characterized in that the porous material is a lot of closed pores (50). 13. A device according to any one of claims 9 and 10, characterized in that the porous material is formed by a material selected from a polystyrene and polypropylene polymer, wherein said porous material is a plurality of pores (50), at least a portion of the pores (50) is open. 14. The device according to claim 3, characterized in that the evaporation tray (10) carries on itself a peripheral ring (40) provided with a plurality of resonator channels (20). 15. The device according to 14, characterized in that the peripheral ring (40) has a certain thickness and at least part of the resonator channels (20) is made in the thickness of the wall of the peripheral ring (40). 16. The device according to 14, characterized in that the peripheral ring (40) occupies an internal and external position with respect to the peripheral wall (11), (12) of the evaporation tray (10). 17. The device according to clause 16, characterized in that at least one of the parts of the peripheral wall (12) and the bottom wall (11) of the evaporation tray (10), the peripheral ring (40) and at least one resonator channel (20) made of porous or fibrous material. 18. The device according to clause 16, characterized in that at least one of the parts of the peripheral wall (12) and the bottom wall (11) of the evaporation tray (10), the peripheral ring (40) and at least one resonator channel (20) covered with porous or fibrous material. 19. The device according to any one of paragraphs.17 and 18, characterized in that the porous material is formed by a material selected from a polymer of polystyrene, polypropylene and from a metal material. 20. The device according to claim 19, characterized in that the porous material is a lot of closed pores (50). 21. The device according to any one of paragraphs.17 and 18, characterized in that the porous material is formed by a material selected from a polymer of polystyrene and polypropylene, having at least part of the pores that are open. 22. The device according to claim 3, characterized in that the resonator channels (20) are straight at least for part of them. 23. The device according to p. 22, characterized in that at least two resonator channels (20) are parallel to each other. 24. The device according to item 22, wherein the at least one resonator channel (20) is vertical. 25. The device according to item 22, wherein the at least one resonator channel (20) is horizontal. 26. The device according to item 22, wherein the resonator channels (20) are located obliquely relative to the axis of the wall in which they are made. 27. The device according to claim 3, characterized in that the second end (22) of each resonator channel (20) is closed. 28. The device according to claim 3, characterized in that at least part of the resonator channels (20) has a constant cross-section along their length. 29. The device according to claim 3, characterized in that at least part of the resonator channels (20) has a variable cross section along their length. 30. The device according to clause 29, wherein at least a portion of the resonator channels (20) has a stepped cross section. 31. The device according to clause 29, wherein at least a portion of the resonator channels (20) has a conical cross section. 32. The device according to clause 29, wherein at least a portion of the resonator channels (20) has an exponential cross section. 33. Device according to any one of paragraphs 28-32, characterized in that at least a portion of the resonator channels (20) has a circular cross section or a cross section in the form of a polygon. 34. The device according to claim 1, characterized in that the sound-absorbing agent is a plurality of pores (50). 35. The device according to clause 34, wherein each pore (50) has a first end part (51) open and rotated in the direction of the noise generation zone in said compartment (1), and a second end part (52), which is located opposite the first end part (51) at a distance from it, and each pore (50) is made with dimensions representing a given internal section, calculated to obtain a specific reactive impedance and a specific absorption impedance in the compartment medium (1) for a given frequency range. 36. The device according to clause 34, wherein at least one of the peripheral wall (12) and the bottom wall (11) of the evaporation tray (10) is made of a porous or fibrous material. 37. The device according to clause 34, wherein at least one of the peripheral wall (12) and the bottom wall (11) of the evaporation tray (10) is covered with a porous or fibrous material. 38. The device according to any one of p and 37, characterized in that the porous material is formed by a material selected from a polymer of polystyrene, polypropylene and from a metal material. 39. The device according to § 38, wherein the pores (50) are closed. 40. Device according to any one of claims 36 and 37, characterized in that the porous material is formed by a material selected from a polystyrene and polypropylene polymer having at least a part of the pores (50) that are open. 41. The device according to claim 1, characterized in that the sound-absorbing means comprises at least one resonator channel (20) extending along the length of the corresponding wall (11), (12) of the evaporation tray (10) and consisting of many pores (50) . 42. The device according to paragraph 41, wherein each resonator channel (20) has a first end (21) that is open and rotated in the direction of the noise generation zone in said compartment (1), and a second end located opposite the first end ( 21) and remote from it, and each resonator channel (20) is made with such dimensions that it has a given length and a given diameter, which are designed to create a specific reactive impedance and a certain absorption impedance in the compartment medium (1) for a given frequency range. 43. The device according to paragraph 41, wherein at least one of the parts of the peripheral wall (12) and the bottom wall (11) of the evaporation tray (10), as well as at least one resonator channel (20) are formed of porous or fibrous material. 44. The device according to paragraph 41, wherein at least one of the parts of the peripheral wall (12) and the bottom wall (11) of the evaporation tray (10), as well as at least one resonator channel (20) are coated with porous or fibrous material. 45. The device according to any one of paragraphs 42 and 43, characterized in that the porous material is formed by a material selected from a polymer of polystyrene, polypropylene and from a metal material. 46. The device according to item 44, wherein the porous material contains many closed pores (50). 47. Device according to any one of paragraphs 42 and 43, characterized in that the porous material is formed by a material selected from a polymer of polystyrene and polypropylene, having at least part of the pores (50) that are open.

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