This application claims the benefit of Korean Application No. P2003-56833, filed on Aug. 18, 2003, which is hereby incorporated by reference as if fully set forth herein.
1. Field of the Invention
The present invention relates to compressors for compressing a working fluid, such as refrigerant to a predetermined pressure, and more particularly, to a suction silencer for reducing noise of refrigerant drawn for compression, having a structure, of which configuration is made simple, and assembly of which is convenient; and a compressor therewith.
2. Description of the Related Art
In the compressor, for compressing a working fluid, such as gas, or refrigerant, to a pressure, there are, in general, turbo compressors, such as axial compressors, and centrifugal compressor, and displacement type compressors, such as rotary compressors and reciprocating compressors.
The reciprocating compressor has a piston reciprocating in a cylinder for drawing and compressing gas or refrigerant.
A related art reciprocating compressor (hereafter compressor) is provided with a shell having an upper shell and a lower shell, a compression part in the shell for compressing refrigerant, and a driving part for driving the compression part.
The compression part is provided with a compression chamber for compressing and discharging refrigerant drawn thereto, a suction silencer for reducing noise from refrigerant being drawn to the compression chamber, a inlet pipe for guiding the refrigerant to the suction silencer, and the like.
However, the suction silencer having many components increases production cost, and reduces productivity due to a complicate fabrication process.
Moreover, the more the number of components of the suction silencer, the more the assembly defects caused by assembly tolerance, to cause refrigerant leakage or failure of assembly.
Accordingly, the present invention is directed to a suction silencer and a compressor therewith that substantially obviates one or more problems due to limitations and disadvantages of the related art.
An object of the present invention is to provide a suction silencer of which structure is made simple to enable an easy assembly, and a compressor therewith.
Additional advantages, objects, and features of the invention will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the invention. The objectives and other advantages of the invention may be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings.
To achieve these objects and other advantages and in accordance with the purpose of the invention, as embodied and broadly described herein, a suction silencer in a compressor includes a lower shell having an opened top, for drawing refrigerant, and an upper shell fixed to the top of the lower shell to form an inside space for reducing noise of drawn refrigerant, for discharging refrigerant in a direction different from a flow direction of the refrigerant introduced into the lower shell.
The lower shell includes an inlet passage having one end fixed to the lower shell, and the other end projected outward, for guiding refrigerant into the inside space.
The lower shell further includes a first extension pipe having one end connected to one end of the inlet passage, and the other end extended toward an inside wall of the inside space.
The inlet passage has the other end expanded like the trumpet.
The upper shell includes an outlet pipe having one end fixed to an outside wall of the upper shell, and the other end projected outwardly, for discharging refrigerant having noise reduced in the inside space.
The upper shell further includes a second extension pipe having one end connected to one end of the outlet pipe, and the other end extended toward the inside space.
The flow direction of the refrigerant introduced into the inside space is perpendicular to a flow direction of the refrigerant discharged from the inside space.
The upper shell and the lower shell are fastened with hooks on one of the upper shell and the lower shell, and hook slots on the other one of the upper shell and the lower shell.
It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide further explanation of the invention as claimed.
The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the principle of the invention. In the drawings;
Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like parts.
Referring to
The frame 2 has a boss 2a with a vertical hollow at a central portion thereof, and a crankshaft 5 is rotatably mounted on the vertical hollow.
The crankshaft 5 has oil passages (not shown), for guiding oil 13 from a bottom of the shell 1 to an upper portion of the shell through the oil passage, and spraying onto the frame 2. To do this, the crankshaft 5 has a pumping mechanism (not shown) at a lower end thereof for pumping up the oil 13 to the oil passage.
The crankshaft 5 is rotated by the motor part, and the motor part includes a stator 3 fixed to a lower portion of the frame, and a rotor 4 coupled to the crankshaft 5 for rotating in an electro-magnetic interaction with the stator 3.
At a top of the crankshaft 5, there is a crankpin 5a eccentric from a rotation axis of the crankshaft 5. Opposite to the crank pin 5b, there is a balance weight (not shown), for making a rotation speed of the crankshaft 5 constant.
At one side of an upper portion of the shell 1, there is a cylinder 6 having a compression chamber 6a therein as one unit with the frame 1. The cylinder is provided with a piston 7 for compression of refrigerant or gas, and the piston 7 is connected to the crank pin 5a at top of the crankshaft 5 with a connecting rod 8 for converting a rotation of the crankshaft to a linear motion.
There is a valve assembly 9 mounted on the cylinder 6 for regulating refrigerant flow in/out of the compression chamber 6a. The valve assembly 9 includes a suction valve for drawing the refrigerant, and a discharge valve for discharging the compressed refrigerant.
A head cover (not shown) is mounted to the valve assembly for separating refrigerant drawn in/discharged from the compression chamber.
In the meantime, at one side of the head cover, there is a suction silencer 11 having one end connected to the inlet pipe 12 for receiving refrigerant from an outside of the compressor, for reducing noise of the refrigerant being introduced into the compression chamber.
Referring to
The lower shell 111 has an inlet 111a for guiding refrigerant from the inlet pipe to the inside space, and the inlet 111a has a connection cap 111b inserted therein, and fastened thereto, for connection between the inlet pipe and the suction silencer.
The upper shell 112 has an outlet 112a at a top thereof for discharging refrigerant to the compression chamber 6a in a state noise is reduced within the suction silencer 110.
The partition 113 has a communication pipe 113a penetrating the partition 113 in a vertical direction, as a passage of the refrigerant moving from the lower space to the upper space.
A noise damping process of the suction silencer in accordance with a first preferred embodiment of the present invention will be described.
The refrigerant introduced into an inside space through the inlet 111a is involved in a first time noise reduction by an impact occurred as the refrigerant hits an under side of the partition 113.
The refrigerant is also involved in a second time noise reduction as a pressure and pulsation of the refrigerant is reduced in a process the refrigerant expands from the inlet to the lower space of the partition 113 which has a larger volume than the inlet.
Then, the refrigerant is also involved in a third time noise reduction as the refrigerant is introduced from the lower space into the upper space of the partition through the communication pipe 113a in the partition, and discharged to the compression chamber 6a through the outlet in the upper shell.
Referring to
The lower shell 121 has a space formed therein, and an opened top, and the upper shell 122 has an opened bottom, to form an inside space together with the lower shell, for reducing noise of the refrigerant.
The lower shell 121 has an inlet passage 121a at a side of a lower portion, having one end fixed to an outside wall of the lower shell 121, and the other end projected outwardly from the wall, for guiding refrigerant introduced into the inside space formed by the upper shell 122 and the lower shell 121.
The other end of the inlet passage 121a projected outwardly from the lower shell 121 is connected to the inlet pipe 12 for drawing refrigerant from an outside of the suction silencer, and guiding the refrigerant to the suction silencer 120. For this, it is preferable that the other end of the inlet passage 121a has an inlet guide 121c expanded like the trumpet formed as one unit with the inlet passage for connection to the inlet pipe 12.
Of course, the inlet guide may be provided by attaching a separate member fabricated as above form to the other end of the inlet passage 121a with adhesive.
It is preferable that there is a first extension pipe 121b extended from the inlet passage 121 a toward an inner side of, and along a bottom of the lower shell as one unit with the inlet passage 121a.
It is preferable that the inlet passage 121a and the first extension pipe 121b which guide the refrigerant to an inside of the suction silencer are fixed so as to form a unit with the lower shell 121a.
The lower shell 121a has an oil drain hole 121d in a bottom surface, and a fastening groove 121e at a top circumference. The fastening groove 121e has a fastening end 122e at the upper shell 122 inserted therein, which will be described, later.
In the meantime, the upper shell 122 includes a cap 122a, and an outlet pipe 122c projected upward from the cap 122a, having a bottom end fixed to a top of the cap 122a, and a top end with an outlet 122b.
The outlet pipe 122c guides noise dampened refrigerant toward the compression chamber 6a of the cylinder.
There is a second extension pipe 122d extended downward from a bottom end formed as a unit with the outlet pipe 122c, and the cap 122a has a fastening end 122e at a bottom end of the cap 122a, for inserting in the fastening groove 121e of the lower shell 121a.
The outlet pipe 122c and the second extension pipe 122d are passages for guiding the refrigerant from the inside space of the suction silencer to the compression chamber 6a.
In the embodiment, it is preferable that the outlet pipe 122c and the second extension pipe 122d are formed as one unit with the cap 122a for simplicity of structure and assembly.
The lower shell 121 and the upper shell 122 may be bonded with adhesive in assembling the lower shell 121 and the upper shell 122.
For bonding with adhesive, the fastening end 122e of the upper shell 122 is inserted in the fastening groove 121e of the lower shell 121.
Then, the adhesive is filled between the fastening end 122e and the fastening groove 121e, to bond the lower shell 121 and the upper shell 122 rigidly, for preventing leakage of the refrigerant from the inside space.
Of course, after applying adhesive to either side of the fastening end 122e or fastening groove 121e, or both sides thereof, the fastening end may be inserted in the fastening groove, and bonded together.
Different from above, hooks (not shown) may be formed on one of the lower shell 121 and the upper shell 122, and hook slots (not shown) are formed on the other one of the lower shell 121 and the upper shell 122, for inserting the hooks in the hook slots to fasten the lower shell 121 and the upper shell 122, or after putting the lower shell 121 and the upper shell 122 together, a separate fastening member, such as clamp (not shown), may be provided to one side of the lower shell 121 and the upper shell 122, to form the suction silencer 120.
Fabrication processes of the lower shell and the upper shell of the suction silencer will be described.
The lower shell 121 may be formed by injecting plastic, or the like, into a predetermined form of a mold, and the inlet passage 121a and the first extension pipe 121b may be formed by adding forms of the inlet passage 121a and the first extension pipe 121b to the mold.
Different from this, the inlet passage 121a and the first extension pipe 121b may be formed with punching means, such as drill, or the like, or by passing a separate pipe through a wall of, and fixing to the lower shell 121a.
Next, the upper shell having the cap 121a with the outlet pipe 122c and the second extension pipe 122d formed as one unit may be formed by injecting plastic into a predetermined form of mold, and the outlet pipe 122c and the second extension pipe 122d may be formed as one unit with the cap 122a by adding forms of the outlet pipe 122c and the second extension pipe 122d to the mold.
Different from this, the outlet pipe 122c and the second extension pipe 122d may be formed as one unit with the cap 122a by passing the outlet pipe 122c and the second extension pipe 122d, which are formed as one unit separately, through a top of, and fixing to the cap 122a. In other words, after forming a pass through hole (not shown) at the top of the cap 122a, by inserting the second extension pipe 122d formed as one unit with the outlet pipe 122c through the pass through hole, and fixing thereto with adhesive, the cap 122a having the outlet pipe 122c and the second extension pipe 122d formed as one unit is formed.
Methods for fabricating the lower shell 121 and the upper shell 122 are not limited to above, but may vary depending on designer's selection.
Refrigerant flow through the suction silencer of the lower shell 121 and the upper shell 122 will be described with reference to
Referring to
That is, the refrigerant drawn through the inlet passage 121a having the inlet guide 121c is introduced into an inside of the lower shell 121 through the first extension pipe 121b extended to an inside of the lower shell 121, and expanded to an inside space of the suction silencer 120.
The refrigerant introduced into, and expanded in the lower shell 121 hits an inside wall of the lower shell 121, when oil in the refrigerant falls down by gravity. The oil fallen down to a bottom of the lower shell thus is drained to an outside of the suction silencer 120 through the oil drain hole 121d.
In the meantime, the refrigerant expanded to an inside space of the suction silencer 120 is introduced into the second extension pipe 122d mounted vertically through the upper shell, and introduced into the compression chamber 6a through the outlet pipe 122c having an outlet 122b.
In above refrigerant flow process, noise damping by the suction silencer will be described.
The refrigerant introduced into an inside through the inlet passage 121a and the first extension pipe 121b is involved in noise damping for the first time by an impact occurred as the refrigerant hits an inside wall of the suction silencer 120, i.e., an inside wall of the lower shell 121a.
The refrigerant introduced into an inside through the inlet passage 121a and the first extension pipe 121b is also involved in noise damping for the second time by reduction of a pressure and pulsation in a process the refrigerant expands to the inside space of the suction silencer 120 having a volume larger than the inlet passage 121a.
The reduction of noise of the refrigerant by the suction silencer 120 permits a quiet compressor operation.
The suction silencer and a compressor therewith have the following advantages.
First, the simple components of the suction silencer permit reduction of a fabrication cost, and to simplify an assembly process, thereby improving productivity.
Second, in the second embodiment, the formation of the outlet pipe to the upper shell for guiding the refrigerant to the outlet, and the formation of the inlet guide as one unit with the inlet passage of the lower shell for serving as the connection cap permits a structure of the suction silencer more simple than the first embodiment.
It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventions. Thus, it is intended that the present invention covers the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.
Number | Date | Country | Kind |
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P2003-0056833 | Aug 2003 | KR | national |