ES2298859T3 - COMPRESSOR. - Google Patents

Abstract

This invention relates to a suction muffler (4) used preferably in compressors (1) and whereby the noise generated during the refrigeration cycle by the refrigerant is minimized.

Description

Compressor.

The present invention relates to a compressor in which a suction silencer minimizes the noise generated by the refrigerant during the refrigeration cycle.

In refrigerators, cooling is reaches by circulating a refrigerant in a cycle that It usually consists of a condenser, which transfers heat outside, a pressure reducer used to regulate the pressure, an evaporator that absorbs heat and a compressor. In the compressors used in the aforementioned cycle, it they use suction silencers so the refrigerant used to get the cooling reaches the block of cylinder without being heated and avoiding noise that could be generated by the refrigerant. The suction silencer usually It is manufactured from plastic material and placed both in the cylinder head as between the cylinder head and the valve saucer. The sucked refrigerant reaches a block of the cylinder passing through a silencer in which its part which forms the suction manifold is placed inside the cylinder head Meanwhile it is necessary to minimize noise generated at different frequencies.

In the state of the art, in the US Patent No. 5,101,931, or EP 0 027 311 A, is provides a description of a silencer that minimizes noise in which its two cameras are connected by a tube.

In the state of the art, in the US Patent No. 5,341,654, a description of a silencer that minimizes noise at different frequencies through its two cameras, which have Admissions with different diameters.

The objective of the present invention is to realize a compressor comprising a suction silencer so it minimizes the noise generated by the refrigerant.

The compressor designed to meet the objectives that the present invention is illustrated in the figures attached in the which:

Figure 1 is a cross-sectional view. of a compressor.

Figure 2 is a perspective view of a suction silencer.

Figure 3 is a schematic representation of a suction silencer comprising an attenuation conduit and Three muffler chambers.

Figure 4 is a schematic representation of a suction silencer comprising an attenuation conduit and Two silencer chambers.

Figure 5 is a schematic representation of a suction silencer comprising three dimming ducts and three muffler chambers.

Figure 6 is a schematic representation of a suction silencer with several guides in the holes admission and exit and comprising three dimming ducts and Two silencer chambers.

Figure 7 is a schematic representation of a suction silencer comprising two dimming ducts which connect different cameras to each other and four cameras of the muffler.

The elements represented in the figures are numbered as follows:

one.

Compressor

2.

Cylinder

3.

Cylinder head

Four.

Suction silencer

5.

Valve saucer

6.

Muffler Outlet Hole

7.

Opening

8.

Muffler Head

9.

Suction hole

10.

Flow pipe

eleven.

Guiding element

12.

Silencer chamber

13.

Dimming duct

14.

Inlet hole of the pipe flow

fifteen.

Outlet hole of the flow pipe

16.

Inlet hole of the duct attenuation

17.

Exit hole of the duct attenuation.

In household appliances, preferably in refrigeration devices, refrigerant circulation used to perform cooling is achieved by means of a compressor (1).

The compressor (1) comprises a cylinder (2) the which provides the pumping of the refrigerant in it, a head of the cylinder (3) placed in the cylinder (2) through which circulates the refrigerant that is sucked and discharged, a dish valve (5) on which the cylinder head is arranged (3), a suction silencer (4) preferably made of plastic, which ensures that the refrigerant with reduced energy acoustics that circulate inside it reach the block of cylinder without being heated and avoiding noise that could be generated by the refrigerant.

The suction silencer (4) comprises a silencer head (8) by which the silencer (4) is attached to the cylinder head (3), an outlet hole of the silencer (6) placed above the silencer head (8) and that provides the refrigerant to pass to the cylinder (2), so minus two silencer chambers (12) provided with different volumetric resonance frequencies to achieve attenuation acoustics at different frequencies, where energy is reduced acoustic, a suction hole (9) that allows the refrigerant through it, a flow pipe (10) preferably with a quadrangular cross section, placed across the suction hole (9) and muffler outlet hole (6) and, the ends of which open to different chambers of the silencer (12), an opening (7) in the flow line (10), by at least one attenuation duct (13) preferably with a circular cross section, in which its parts in the chambers of the silencer, in which its intake and exit communicate with them, they have different areas of the section transverse and so the union between the chambers of the silencer (12) and the acoustic energy is derived.

The flow line (10) comprises a hole of inlet of the flow pipe (14) placed through the suction hole (9) and an outlet hole of the pipe flow (15) placed through the muffler outlet hole (6).

The attenuation duct (13), which communicates the silencer chambers (12) connecting them, comprises a intake hole of the attenuation duct (16), which, is extends to one of the muffler chambers (12), which is closer to the suction outlet hole (6) and, which attenuates sound waves at unwanted frequencies through the area of the cross section (A5) thereof and; an exit hole of the attenuation duct (17) with an area of the cross section different (A6) from that of the intake hole of the duct attenuation (16).

The cross-sectional area through the which passes the flow, increases continuously downstream, from the suction hole (9) in the suction silencer (4) to the suction outlet hole (6), in order to minimize the factors that would slow the flow of the refrigerant and that would reduce the thermodynamic performance of the suction silencer (4) causing pressure losses Therefore, it is minimized that the flow uniform is affected due to reductions in the section transversal, up to the conditions of the boundary layer or when it passes by inclined or curved areas. For this reason, the area of the cross section (A1) of the suction hole (9) outside the Silencer chamber (12) is smaller than that (A2) of the inlet hole of the flow pipe (14) and the area of the cross section (A3) of the outlet hole of the pipe flow (15) is less than that (A4) of the outlet opening of the silencer (6) inside the silencer chamber (12).

In another application of the present invention, the suction silencer (4) comprises a silencer chamber (12) which communicates with the suction hole (9), a second chamber of the silencer (12) with a volumetric resonance frequency different that communicates with the muffler outlet hole (6), a third silencer chamber (12) with a frequency of different volumetric resonance placed between the other two Silencer chambers (12) and a dimming duct (13) that communicates with the third and second silencer chambers (12) (figure 3).

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In another application of the present invention, the suction silencer (4) comprises a silencer chamber (12) which communicates with the suction hole (9), a second chamber of the silencer (12) with a volumetric resonance frequency different that communicates with the muffler outlet hole (6) and a dimming duct (13) that communicates with the cameras first and second silencer (12) (figure 4).

In an application of the present invention, the suction silencer (4) comprises a first chamber of the silencer (12) that communicates with the suction hole (9), a second silencer chamber (12) with a frequency of different volumetric resonance that communicates with the orifice of muffler outlet (6), a third muffler chamber (12) with a volumetric resonance frequency different from those of the other two muffler chambers (12) and which is placed between the first and second chambers of the silencer (12) and three dimming ducts (13) which communicate with the third and second silencer chambers (12) and provided with areas of the different cross section thus minimizing the noise at different frequencies (figure 5).

In another application of the present invention, the suction silencer (4) comprises one or more guiding elements (11) extending from the suction hole (9) to the first silencer chamber (12) so the refrigerant Suction is carried to the flow line (10) and the refrigerant in the flow pipe (10) it is led to the outlet orifice of the silencer (6) (figure 6).

In another application of the present invention, the suction silencer (4) comprises a first chamber of the silencer (12) that communicates with the suction hole (9), a second silencer chamber (12) with a frequency of different volumetric resonance that communicates with the orifice of muffler outlet (6), third and fourth chambers of the silencer (12) with volumetric resonance frequencies different and which are placed between the first and second silencer (12), an attenuation duct (13) that communicates with the third and second silencer chambers (12) and another dimming duct (13) that communicates with the cameras second and fourth silencer (12) and provided with an area of the cross section different from that of the other by minimizing in that way the noise at different frequencies (figure 7).

By means of the application according to the present invention, during the circulation of the refrigerant is achieved minimize the noise generated by the increase in the behavior of the compressor (1).

Claims (5)

1. Compressor (1) comprising a suction silencer (4) such that the refrigerant reaches the cylinder block without being heated and avoids the noise that could be generated by the refrigerant, and that includes a silencer head ( 8), whereby the silencer (4) is connected to a cylinder head (3), a silencer outlet hole (6) placed above the silencer head (8) and ensuring that the refrigerant passes to a cylinder (2), at least two muffler chambers (12) provided with different volumetric resonance frequencies to achieve acoustic attenuation at different frequencies, in which the acoustic energy is reduced, and a suction hole (9) to allow the refrigerant enters through it and characterized in that it has a suction silencer (4) comprising a flow pipe (10) placed through the suction hole (9) and the outlet hole of the silencer (6) and the e The ends of which are opened to different muffler chambers (12), an attenuation duct (13) between the muffler chambers (12) used to derive acoustic energy and minimize noise at desired frequencies, in which the holes of Inlet (16) and outlet (17) of said attenuation duct (13) communicating with said muffler chambers have different areas of the cross section. 2. Compressor (1) according to claim 1, characterized in that it has a suction silencer (4), which communicates the chambers of the silencer (12) by connecting them, comprising an attenuation conduit (13) with an inlet opening of the attenuation (16) which, extending to one of the muffler chambers (12), which is closer to the suction outlet hole (6) and, attenuating the sound waves at unwanted frequencies by the area of the cross section (A5) thereof and; an outlet orifice of the attenuation conduit (17) with a different cross-sectional area (A6) than that of the intake orifice of the attenuation conduit (16). 3. Compressor (1) according to any of the preceding claims, characterized in that it has a suction silencer (4) comprising an opening (7) in the flow line (10). 4. Compressor (1) according to any one of the preceding claims, characterized in that it has a suction silencer (4) comprising a flow line (10) with an inlet port of the flow line (14) placed through the hole suction (9) and an outlet orifice of the flow line (15) placed through the outlet orifice of the silencer (6). 5. Compressor (1) according to any of the preceding claims, characterized in that it has a suction silencer (4) comprising one or more guiding elements (11) extending from the suction hole (9) to the first chamber of silencer (12) in such a way that the sucked refrigerant is conducted to the flow line (10) and the refrigerant in the flow line (10) is taken to the outlet port of the silencer (6).