KR20100092512A - System for attenuating pulsation in the gas discharge of a refrigeration compressor - Google Patents

Abstract

The damping device is applied to a compressor, which has a cylinder (2) and a cylinder cover (5), one end of which is closed by a valve plate (4) and a valve plate (4). Has a discharge hole 4a and at the same time forms a compression chamber 6 together with the cylinder 2, the cylinder cover 5 is seated on the valve plate 4 to form the discharge chamber 7, The discharge chamber 7 is in communication with the outside of the compressor through the discharge pipe (8). The damping device includes at least one intermediate chamber (10) formed in the discharge chamber (7) to accommodate the entire discharge flow discharged from the compression chamber (6) through the discharge hole (4a); And at least one connecting pipe 20 mounted inside the discharge chamber 7, wherein the discharge chamber 7 has a first end 21 and a discharge chamber 7 communicating with the interior of the intermediate chamber 10. The second end part 22 which communicates with the inside of the (circle) is provided.

Description

System for attenuating pulsation in the gas discharge of a refrigeration compressor}

The present invention relates to, for example, a pulsation damping device adapted to be applied to the gas outlet of a reciprocating hermetic refrigeration compressor, generally driven by a linear motor.

In general, gas dischargers of refrigeration compressors are equipped with pulsation dampers or acoustic filters. The purpose of this damping device is to attenuate the pulsation of the gas pumped from the compressor to the cooling device to which the compressor is connected or to attenuate the pulsation of the gas pumped to the high pressure side of the cooling circuit to which the compressor is attached, as well as the compressor. It is to attenuate the noise emitted by the outside air. The pulsation of the gas causes vibrations in the parts to which the ducts and the exhaust of the compressor are connected, which generate noise.

Attenuation of the pulsation upon gas discharge of the compressor is generally carried out in the following manner: by limiting the flow rate of the pumped cooling fluid by reducing the diameter of the discharge conduit, or by achieving attenuation through load loss, or Providing at least one inflated volume disposed in series in the outlet tube, or reflecting pulsating sound waves present in the outlet tube by acoustic impedance discontinuity, thereby attenuating the transmitted pulsation. In these structures, the pulsation dampener is coupled to the cylinder block and / or the exhaust pipe. The gas flow is forced through the volume and limiting portions installed in the pipes, cylinder blocks and / or exhaust pipes in a predetermined order, and the dimensions, arrangement and characteristics of the volume and restricting portions are applied, the type and dimension of the compressor, the mass flow, It depends on the working fluid, temperature and operating conditions, the noise band of the noise to be attenuated, and so on.

This discharger, having a volumetric configuration in series, achieves significant attenuation but has the drawback of causing high load losses. This solution has the drawback that the cylinder block must be of large dimensions in order to allow for machining of the volume and discharge pipe further. For example, in a compact compressor having no mass block, in a compressor in which a cylinder block constituting a part of the shell is very lightweight, there is no space for coupling the damping device to the cylinder block. The solution does not apply.

It is a general object of the present invention to provide a pulsation damping device of a gas discharge part of a cooling compressor of a particularly small dimension which can attenuate exhaust pulsation and noise without generating load loss of a known structure.

Another object of the present invention is to provide a pulsation and noise damping device as described above, which can be easily constructed and mounted, in particular, a compressor having no linear mass block.

These objects include a cylinder block forming a cylinder of the present invention; A valve plate that closes an end of the cylinder, is provided with a discharge hole, and forms a compression chamber together with the cylinder; A cylinder cover seated on the surface of the valve plate on the opposite side of the compression chamber and forming a discharge chamber; In the pulsation damping device of the gas discharge portion of the cooling compressor of the type including a discharge pipe for communicating the discharge chamber and the outside of the compressor,

At least one intermediate chamber formed inside the discharge chamber for receiving a total discharge flow discharged from the compression chamber through the discharge hole; At least one connecting tube mounted inside the discharge chamber, having a first end communicated with the interior of the intermediate chamber and a second end communicated with the interior of the discharge chamber, the interior of at least one of the intermediate chamber and the discharge chamber; It is achieved by the pulsation damping device of the gas discharge portion of the refrigeration compressor, characterized in that it comprises a connecting tube, protruding by an extension.

Hereinafter, the present invention will be described with reference to the drawings presented as examples of embodiments of the present invention.
1 is a schematic longitudinal sectional view of a part of the discharge device of a particularly compact linear motor reciprocating compressor in which the shell is formed by a cylinder block and a cylinder cover;
2 is a schematic longitudinal cross-sectional view as in FIG. 1 of a linear motor compressor having an exhaust pulsation damping device of the present invention;
3 is a schematic longitudinal cross-sectional view similar to FIG. 2 showing a pulsation damping device having one or more intermediate chambers;
4 is a schematic enlarged longitudinal sectional view of the cylinder cover of the compressor shown in FIG. 2, in which the exhaust pulsation damping device of the present invention of the embodiment shown in FIG. 2 is installed;
Fig. 5 is a graph showing attenuation results obtained by a structure having a pulsation damping device of the present invention having a gas discharge device of the prior art having one discharge volume in the discharge chamber and two gas discharge volumes in the cylinder cover; ; And
6 is a graph showing attenuation results obtained by one discharge volume and two discharge volume in the discharge chamber in the cylinder cover according to one embodiment of the present invention.

Hereinafter, the present invention describes a reciprocating hermetic compressor. The compressor has a motor-compressor assembly having a cylinder block 1 forming a cylinder 2, in which the piston 3 is axially driven by the operation of a motor (not shown). Is displaced. In a special compressor structure of the type driven by a linear motor, the piston 3 is connected to a resonance spring (not shown) and is axially displaced inside the cylinder 2 by an actuating device (not shown). The actuator supports the magnetic component (not shown) and is driven in the axial direction when energizing the linear motor.

The cylinder 2 has an open end into which the piston 3 enters and an opposite end closed by the valve plate. The valve plate 4 has at least one intake valve and a discharge valve, which regulates the inflow and outflow of gas into and out of the cylinder 2. In the drawing, the valve plate 4 is provided with a discharge hole 4a which is closed by the discharge valve 4b and two suction holes 4c which are closed by the valve member 4d. In the structure of this figure, the valve plate 4 has the discharge valve 4b and the suction valve 4d on their opposite surfaces, respectively. The valve plate 4 forms a compression chamber 6 together with the inside of the cylinder 2. The structure shown in FIG. 1 is a known structure in which a cylinder cover 5 is mounted on a cylinder block 1, which has the drawbacks already described above.

The cylinder cover 5 is in close contact with the opposing surface of the surface facing the compression chamber 6 of the valve plate 4 and forms the discharge chamber 7 together with the surface of the adjacent valve plate 4. The discharge chamber 7 maintains the selective fluid communication with the compression chamber 6 through the discharge hole 4a and the discharge valve 4b, and discharge tube 8 which communicates the discharge chamber 7 with the outside of the compressor. ) Maintains a constant fluid communication with the discharge side of the cooling device to which the compressor is coupled.

The gas suction action and the gas compression action in the compressor are respectively determined by the reciprocating motion of the piston 3 with respect to the valve plate 4 inside the cylinder 2.

In the construction of some of the compressors driven by linear motors, the motor-compressor assembly is mounted inside a shell that creates an airtight environment, which mounting is typically a set of suspension springs installed inside the shell. springs). In the compact linear compressor structure, the cylinder block 1 and the cylinder cover 5 form part of the shell.

According to the invention, the refrigeration compressor is provided with an outlet damping device. The damping device has at least one intermediate chamber 10 formed inside the discharge chamber 7, which is discharged from the compression chamber 6 through the discharge hole 4a of the valve plate 4. To accommodate the entire discharge flow, the intermediate chamber 10 is in constant fluid communication with the discharge chamber 7 through at least one connecting pipe 20 mounted inside the discharge chamber 7. The connecting pipe 20 has a first end portion 21 communicating with the interior of the intermediate chamber 10 and a second end portion 22 communicating with the interior of the discharge chamber 7, and the intermediate chamber has a predetermined extension. It protrudes inside at least one of the 10 and the discharge chamber 7.

The solution of the present invention refers to the concept of volume-tube-volume silencer, which is not installed inside the cylinder block 1 or inside the discharge pipe 8, but without the cylinder cover ( 5) an intermediate chamber 10, which is an initial volume portion through which the gas is discharged through the opening of the discharge valve 4b, and a final volume portion formed adjacent to the discharge pipe 8 of the cylinder cover 5; At least one of the two volume parts is in communication with the adjacent volume part through the connecting pipe 20, and one end of the connecting pipe 20 is inside the discharge chamber 7 as shown in FIG. 2. And the other end communicate with an adjacent intermediate chamber.

The volume of the intermediate chamber and the discharge chamber, the dimensions of the tube 20 (extension, shape, cross-sectional area), and the length of protrusion of the tube into each chamber as a function of the damping effect to be achieved and the damping range of the pulsation Is determined.

According to the present invention, as shown in Fig. 3, when a plurality of intermediate chambers are installed in series, these intermediate chambers can be interconnected by the above-described connector structure, and fluid communication between two consecutive intermediate chambers is Carried out by at least one connector having a first end 21 and a second end 22, the length of the extension of which is at least the main pulsation mode of the compressed gas to be attenuated. Calculated as a function of

In a particular structural form in which a plurality of volumes are connected in series, these volumes have overlapping intermediate chambers 10, the first of which is in fluid communication with the discharge hole 4a. In another particular structure, the intermediate chambers are disposed in a plurality of layers that surround either concentric or non-concentric form.

In another embodiment of the invention, the volumes and tubes in series can be obtained by a series of volumes spaced apart from each other and connected by a connecting tube 20.

In any of these structures and variations on the depicted structure, the first intermediate chamber 10 receives compressed gas discharged directly from the compression chamber 6, seated on the valve plate 4. have. In another structural variant within the concept of the invention, a connecting pipe 20 is provided between the discharge hole 4a and the first intermediate chamber 10, the connecting tube 20 being the first intermediate chamber. (10) is kept in a state spaced apart from the seated state on the valve plate (4).

In any of the structures of the volume and tube of the present invention, these structures are provided so as not to interrupt the intermittent gas stream discharged to the discharge chamber during compression, while damping the pulsation of the compressed gas stream.

Each intermediate chamber 10 is formed by a hollow body of a rigid structure, and the intermediate chamber attaches a part of the connection tube 20 by, for example, welding or adhesive or integrally integrates the connection tube. . Each intermediate chamber 10 includes a cylinder cover 5 such that fluid communication with an adjacent volume of the intermediate chamber 10 or fluid communication with the discharge chamber 7 is made through one or more connecting pipes 20. ) Is installed inside.

In order to improve the attenuation of the pulsation, at least a part of the intermediate chamber 10 and the connecting pipe 20 is provided with a soundproof material or coated.

In the structure in which the intermediate chamber 10 is seated on the valve plate 4, each intermediate chamber 10 is simply fitted with suitable fastening means 40 such as adhesives, screws, welding, or the like. Attached to the valve plate 4 by interference, the attachment is effected to prevent leakage of compressed gas between the outer end of the intermediate chamber 10 and the adjacent surface of the valve plate 4.

In the structure form for attaching the intermediate chamber to the valve plate 4, the intermediate chamber is a hollow body having an opening, and the outer shape of the opening is formed by an outer peripheral portion 10a seated on the valve plate 4, the outer peripheral portion The outer circumferential flange 11 protrudes from the outside, for example continuously, which can be fixed to the valve plate 4 via, for example, a screw as shown in FIG. 4. In another embodiment, the outer flange of the intermediate chamber 10 has an extension determined at the outer circumference of the cylinder cover 5. This extension is dimensioned enough to seat the outer periphery of the cylinder cover 5 which is fixed to the cylinder with the intermediate chamber within its outer periphery.

According to an embodiment of the invention, each connecting tube 20 has first and second ends 21, 22 arranged eccentrically in the intermediate chamber 10 and the discharge chamber 7, respectively. The second end 22 of 20 is disposed away from the open end of the discharge tube 8 and towards the interior of the discharge chamber 7.

According to another aspect of the present invention, each of the connecting pipes 20 projects at least one of the first and second ends into the interior of the intermediate chamber 10 and the discharge chamber 7, respectively, and the protruding length is attenuated. It is estimated in advance as a function of the pulsation mode. In the illustrated structural form, the first and second ends of the connecting pipe 20 both project inside the intermediate chamber 10 and the discharge chamber 7 by a length calculated as described above, respectively.

According to another aspect of the present invention, it is possible to form one or a plurality of holes in the parts instead of the respective connecting tubes 20, and the thickness of the parts having the holes is an extension of the pipe having both ends described above. It shall be specified without damaging its function. The attenuation curve in this case is shown in FIG.

Each intermediate chamber 10 is provided with respective connecting tube (s) 20, which are integrated into the intermediate chamber by fixing or integrally with the main body of the intermediate chamber 10 at the time of manufacturing the intermediate chamber. Is formed.

According to the extension provided by the connecting pipe, the connecting pipe 20 spirals into at least one of the intermediate chamber 10 and the discharge chamber 7 from a portion of the extension projecting inside the respective chamber. It should be installed so that the part is provided. In the structure shown in FIG. 4, the connecting pipe 20 is provided with a helical portion from the first end 21 to a portion of the extension projecting outward from the hollow body of the intermediate chamber 10. As the space inside the cylinder cover 5 is reduced, the connecting pipe 20 provides a helical portion that follows at least a portion of the outer circumference of the intermediate chamber. However, in the illustrated structural form, the connecting pipe 20 should not be construed as being limited to this structural form, but should be understood as an example of the structure.

In addition, it is to be understood that the structural modifications described herein may be provided individually to a particular structure, or may be provided in partly combined form or in totally combined form.

As can be seen in Figures 5 and 6, the pulsation attenuation solution of the present invention provides a substantial attenuation effect of broadband, and the attenuation reaches up to 50 decibels in a particular band compared to the conventional structure.

Claims (11)

A cylinder block 1 forming a cylinder 2; A valve plate (4) which closes an end of the cylinder (2), is provided with a discharge hole (4a), and forms a compression chamber (6) together with the cylinder (2); A cylinder cover (5) seated on the surface of the valve plate (4) on the opposite side of the compression chamber (6) and forming a discharge chamber (7); In the pulsation damping device of the gas discharge portion of the cooling compressor of the type comprising a discharge pipe (8) for communicating the discharge chamber (7) and the outside of the compressor,
At least one intermediate chamber 10 formed inside the discharge chamber 7 for receiving the entire discharge flow discharged from the compression chamber 6 through the discharge hole 4a;
At least one connecting tube 20 mounted inside the discharge chamber 7, the first end 21 communicating with the interior of the intermediate chamber 10 and a second communication with the interior of the discharge chamber 7; A gas outlet of the refrigeration compressor, characterized in that it comprises an end pipe 22 and protrudes by an extension into at least one of the intermediate chamber 10 and the discharge chamber 7. Pulsation damping device. The method according to claim 1,
The first and second ends (21, 22) of the connecting pipe (20) are eccentrically arranged in the intermediate chamber (10) and the discharge chamber (7), the pulsation damping device of the gas discharge portion of the cooling compressor. The method according to claim 2,
The connecting pipe 20 has one extension which is calculated as a function of the main pulsation mode of the gas under compression to be attenuated between the first and second ends 21, 22. Pulsation damping device. The method according to claim 3,
The pulsation of the gas outlet of the cold compressor is characterized in that the first end 21 of the connecting tube 20 protrudes into the interior of the intermediate chamber 10 by a predetermined extension, which is determined in advance as a function of the pulsation mode to be attenuated. Damping device. The method according to claim 1,
The connecting tube 20 is provided with a helical portion from the first end 21, which extends at least along an extension of the connecting tube 20 inside the discharge chamber 7. Pulsation damping device of gas outlet. The method according to claim 1,
The connecting pipe 20 is a pulsation damping device of the gas discharge portion of the cooling compressor, characterized in that formed integrally with the intermediate chamber (10). The method according to claim 1,
At least one of the components of the intermediate chamber (10) and the connecting pipe (20) is formed of a soundproof material pulsation damping device of the gas discharge portion of the refrigeration compressor. The method according to claim 1,
The pulsation damping device of the gas discharge part of the cooling compressor, characterized in that the second end (22) of the connecting pipe (20) is spaced apart from the open end of the discharge pipe (8). The method according to claim 1,
The pulsation damping device of the gas discharge part of the cooling compressor, characterized in that the intermediate chamber (10) is attached to the valve plate (4) in an airtight state. The method according to claim 9,
The pulsation damping device of the gas discharge part of the cooling compressor, characterized in that the intermediate chamber 10 is a hollow body having an opening, and the outer shape of the opening is formed by an outer peripheral portion 10a seated and fixed to the valve plate 4. . The method according to claim 10,
The pulsation damping device of the gas discharge portion of the refrigeration compressor, characterized in that the hollow body is a rigid body.

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