JPH07280372A - Compressor - Google Patents

Abstract

PURPOSE:To eliminate uneven wear due to one side contact of a piston and to prolong a service life of a compressor by always disposing a center of gravity of a movable unit in a cylinder. CONSTITUTION:Part of a piston 21 of a movable unit 57 is engaged within an inner cylinder 17 of a cylinder 13. The piston 21 is energized to a neutral position by a piston spring 41. Mass of an inner part 59 of the unit 57 is increased larger than that of an outer part 61. Thus, the center of gravity of the unit 57 is disposed in the cylinder 13 at an expansion side dead point. The mass of the unit 57 is set to the same as that of the unit 57 when materials of both the parts 59, 61 are the same.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a compressor for generating a pressure wave in a working fluid in a cylinder by reciprocating movement of a piston fitted in the cylinder.

[0002]

2. Description of the Related Art Conventionally, as a compressor of this type, as shown in FIG. 7, for example, a cylinder (a) arranged with its axis oriented in the horizontal direction, and a part thereof reciprocally moves into the cylinder (a). A piston (b) that is inserted so that it is possible, and the piston (b)
And a linear motor (c) of a voice coil type for driving a cylinder, and the piston (b) compresses a refrigerant gas as a working fluid in the cylinder (a) to generate a pressure wave. ing. The linear motor (c) has an annular coil (d) and an annular permanent magnet (not shown) arranged around the coil (d), and the coil (d) is the piston (b). ) Cylinder (a)
It is installed on a bobbin (e) connected to the portion extending to the outside. (F) is a flange portion formed on a portion of the piston (b) extending outside the cylinder (a), (g) is a bolt for attaching the bobbin (e) to the flange portion (f),
(H) is a coil spring for urging the piston (b) to be positioned at a neutral position in the cylinder (a), and (i) is a holder for connecting the coil spring (h) to the piston (b). is there. Then, an alternating magnetic field having a predetermined frequency is applied to the coil (d) to generate an alternating magnetic field, and the coil (d)
The piston (b) is reciprocated by the interaction between the permanent magnet and the permanent magnet. Further, a movable part including the piston (b), the bobbin (e) and the coil (d), a coil spring (h), and a cylinder (a) acting as a gas spring.
The refrigerant gas therein constitutes one vibration system. A coil (d) of the linear motor (c) is energized with an alternating current of a predetermined frequency to resonate the vibration system, and a piston (b) is used to generate a pressure wave in the refrigerant gas in the cylinder (a). There is.

[0003]

In the conventional compressor described above, since the load of the movable portion is supported by the cylinder (a), the center of gravity (j) of the movable portion is inside the cylinder (a). When it is located, the movable part is held horizontally, but when the center of gravity (j) goes out from the cylinder (a), as shown in FIG. 7, gravity acting on the center of gravity (j) (in the figure, The piston (b) tilts downward to the right due to (see arrow). Then, a part (k) of the piston (b) that passes through the cylinder opening and a piston tip peripheral part (l) come into contact with the cylinder (a), so-called one-sided contact occurs, and both parts (k) and (l) are contacted. Uneven wear occurs. When such uneven wear occurs, the clearance between the piston (b) and the cylinder (a) increases,
There is a problem that gas leakage occurs and compression becomes impossible, which shortens the life of the compressor. The problem of the position of the center of gravity during the operation of the piston is remarkable especially when the cylinder (a) is shortened due to the demand for downsizing of the compressor.

The present invention has been made in view of the above points, and an object thereof is to adjust the mass distribution of the movable portion so that the center of gravity of the movable portion is always positioned in the cylinder during piston operation. In this way, uneven wear due to partial contact of the piston is eliminated, and the life of the compressor is extended.

[0005]

In order to achieve the first object, the means for solving the problems according to the invention of claim 1 is a cylinder (13) in which an axis is arranged horizontally as a compressor. ), And a piston (21) partially inserted into the cylinder (13) so as to be capable of reciprocating, and for compressing the working fluid in the cylinder (13) to generate a pressure wave.
The magnet (4) has a spring member (41) for urging the piston (21) so as to position the piston (21) in a neutral position in the cylinder (13), a magnet (47) and a coil (55).
7) or the coil (55) is provided in a portion of the piston (21) extending outside the cylinder (13), and
A linear motor (43) for exciting the piston (21) by the interaction of the two (47) and (55), and a magnet (47) or coil (55) provided on the piston (21); The piston (21) and the movable part (5
7) is assumed. In such a compressor, the movable part (57) is connected to the piston (21).
Is located at the dead center most moved to the outside of the cylinder (13), the mass of the inner portion (59) existing inside the cylinder (13) from the position of the opening (17a) of the cylinder (13) is the same as that of the opening (17a). Cylinder (13) from position (17a)
It is assumed that the mass is set to be larger than the mass of the outer portion (61) existing on the outer side.

[0006] Specifically, the solution means taken by the invention according to claim 2 is the compressor according to claim 1, in which the inner part (59) and the outer part (61) of the movable part (57) are different. And the specific gravity of the material of the inner part (59) is made larger than the specific gravity of the material of the outer part (61).

The means for solving the problem of the invention according to claim 3 is as follows.
A compressor according to claim 1, wherein a weight (75) is provided in the inner portion (59) of the movable portion (57) such that the mass of the inner portion (59) is greater than the mass of the outer portion (61).
Is added.

[0008] The solving means taken by the invention according to claim 4 is,
Compressor according to claim 1, wherein the volume of the outer part (61) of the movable part (57) is such that the mass of the outer part (61) is smaller than the mass of the inner part (59).
It is smaller than the volume of the inner portion (59).

The solving means taken by the invention according to claim 5 is:
A compressor according to claim 2, wherein the mass of the movable part (57) is the mass of the movable part (57) when the material of the inner part (59) and the material of the outer part (61) are the same. The settings are the same.

[0010]

With the above construction, in the invention according to claim 1,
Since the mass of the inner part (59) of the movable part (57) is set to be larger than the mass of the outer part (61), the center of gravity of the movable part (57) is set to the cylinder (13) during the operation of the piston (21). Will always be located inside the piston (2
1) is held horizontally, and the uneven contact is eliminated.

Further, in the invention according to claim 2, since the specific gravity of the material of the inner portion (59) is larger than the specific gravity of the material of the outer portion (61), the volume of the movable portion (57) is changed. The center of gravity is adjusted without.

On the other hand, in the invention according to claim 3, by adding a weight to the inner part (59), in the invention according to claim 4, the volume of the outer part (61) is set to the inner part (59).
By adjusting the volume to be smaller than the volume, the center of gravity of the movable portion (57) can be easily adjusted.

Further, in the invention according to claim 5, the mass of the movable part (57) is set to be the same as the mass of the movable part (57) when the materials of the both parts (59) and (61) are the same. Therefore, the mass of the movable part (57) does not change. Therefore, for example, when a vibration system having the movable part (57) as a mass element is provided in the compressor, the natural frequency of the vibration system is specified, and the change of the spring constant of the vibration system is limited. Even if the mass of the movable part (57) cannot be freely changed because of the above, the center of gravity of the movable part (57) can be adjusted.

[0014]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows a compressor (1) according to a first embodiment of the present invention. The compressor (1) is combined with the expander (3) (see FIG. 2) to form a Stirling refrigeration system. The compressor (1) is a piston-opposed vibratory compressor, and as shown in FIG. 1, a closed cylindrical casing (5) arranged in a horizontal direction and a casing (5) housed in the casing (5). And the actuated part (7). The working part (7) has a cylindrical closed working part casing (7a), and the working part casing (7a) has a plurality of holding members (9), (9),
Are held in the casing (5) at predetermined intervals by means of a pair of left and right cylindrical casing assemblies (11), (11) and are sandwiched by the casing assemblies (11), (11). Cylinder (1
3) and are provided. The cylinder (13) includes an outer cylinder portion (15) and an inner cylinder portion (17) which are concentrically provided,
A connecting part (19) for connecting the two tubular parts (15) and (17)
It has and. (S) is an axis of the cylinder (13) extending in the horizontal direction. The inner cylinder part (17) of the cylinder (13) has a pair of left and right pistons (21) from the left and right openings (17a) and (17a) of the inner cylinder part (17) which is the opening of the cylinder (13). A part of each is fitted so as to be reciprocally movable. Further, a sliding member (23) is fitted on the outer peripheral surface of the piston (21), and the sliding member (23) is provided inside the inner tubular portion (17) during operation of the piston (21).
It is designed to be in sliding contact with the inner peripheral surface (see FIG. 3). The space sandwiched by the pair of pistons (21) in the cylinder (13) is a compression chamber (A), and the compression chamber (A) is filled with a refrigerant gas as a working fluid. A gas passage (25) extending from the inner peripheral surface of the inner cylindrical portion (17) to the outer peripheral surface of the outer cylindrical portion (15) is provided at the connecting portion (19) forming portion of the cylinder (13). Is connected to the coupling pipe (31) through a connecting passage (29) provided in the pipe member (27).
The connecting pipe (31) extends to the outside of the casing (5) and is connected to the expander (3).

An assembly side holder (35) is attached to the central portion of the inner surface of each casing assembly (11) by a bolt (33). Each piston (21) has a center hole (37), and a piston side holder (39) is attached to the bottom surface of the center hole (37) with a bolt (33). Both holders (3
Both ends of a piston spring (41) as a spring member are fixed to 5) and (39), respectively. The piston spring (41) is composed of a coil spring and biases the piston (21) so as to position the piston (21) at a neutral position in the cylinder (13). The piston spring (41) is held in a free length state in which it is neither compressed nor stretched.

A linear motor (43) is provided in the operating portion (7), and the linear motor (43) is provided.
Has a cylindrical member (45) fitted and fixed around the inner cylindrical portion (17) of the cylinder (13). The cylindrical member (4
Permanent magnet (47) as an annular magnet on the outer peripheral surface of 5)
Is provided, and a gap is formed between the permanent magnet (47) and the outer cylinder part (15). The permanent magnet (47)
Is a cylindrical member (45) and a cylinder (1
3) as a yoke, a permanent magnet (47) and an outer cylinder part (15)
A magnetic field having a predetermined strength is generated in a gap (magnetic gap) between the magnetic field and the magnetic field.

The cylinder (1) of each piston (21)
3) A brim portion (49) protruding outward in the radial direction is provided at a portion extending outward, and a cylindrical bobbin (53) having a bottom is connected to the brim portion (49) by a bolt (51). As a result, the piston (21) and the bobbin (53) are integrated. The bobbin (53) is made of stainless steel which is a non-magnetic material, and is arranged concentrically with the axis (S) of the cylinder (13). A coil (55) serving as an annular driving unit is arranged at the tip of the bobbin (53), and the bobbin (53) and the coil (55) include a permanent magnet (47) and an outer cylinder (15). It reciprocates in the direction of the cylinder axis in the space between them. The piston (21), bobbin (53) and coil (55)
Constitutes a movable part (57). The piston (21), the bobbin (53) and the coil (55) are provided concentrically with the axis (S) of the cylinder (13), and the mass of the movable part (57) is line-symmetric with respect to the axis (S). Balanced as the center, the center of gravity of the movable part (57) is located on the axis (S).

The pair of linear motors (43), (4
AC of a predetermined operating frequency is synchronously supplied to each of the coils (55) of (3).
An alternating magnetic field is generated in 5), and the pair of pistons (21) and (21) are reciprocally moved in opposite directions and in the same phase by the interaction between the alternating magnetic field of the coil (55) and the magnetic field of the permanent magnet (47). It is like this. In addition, the movable part (5
7), the piston spring (41), and the refrigerant gas in the compression chamber (A) that acts as a spring form a single vibration system. The natural frequency of the vibration system is determined by the movable part (5
7) and the spring constant of the piston spring (41) and the gas spring constant of the refrigerant gas in the compression chamber (A). Then, by setting the operating frequency of the alternating current supplied to the coil (55) to be the same as the natural frequency of the vibration system, the vibration frequency for vibrating the movable part (57) matches the natural frequency. The vibration system is caused to resonate. The pair of pistons (2
1) and 21 are the compression side dead center that most penetrates into the cylinder 13 and the cylinder 1 when the neutral position of the piston spring 41 is an equilibrium point of vibration (reciprocating movement).
3) It reciprocates between the expansion side dead center that has moved to the outermost side to generate a compression wave in the refrigerant gas in the compression chamber (A).

If the frequency of the commercial AC power source (power source frequency) is used as it is as the operating frequency of the linear motor (43), there is no need for frequency conversion, so the operating frequency may be set to the power source frequency. In this case, in order to cause the vibration system to resonate at the power supply frequency, it is necessary to set the value of its natural frequency to be the power supply frequency value. For that purpose, the movable part (57) mass and the two Adjust appropriately using the spring constant as a parameter. In addition,
Since it is practically difficult to change the refrigerant gas, only the spring constant of the piston spring (41) is often used as a parameter.

As shown in FIG. 3, the piston (21) is
When the movable portion (5
7) Inside portion (59) existing inside the cylinder (13) from the position of the opening (17a) of the cylinder (13) in
Mass of the cylinder (1) from the position of the opening (17a).
3) The mass is set to be larger than the mass of the outer portion (61) existing on the outer side, and the center of gravity (F) of the movable portion (57) is positioned inside the cylinder (13). In particular,
Inner part (59) and outer part (61) of the movable part (57)
And are made of different materials, the inner part (59)
The specific gravity of the material is made larger than the specific gravity of the material of the outer portion (61). For example, brass or copper is used for the entire inner portion (59), and stainless steel or aluminum having a smaller specific gravity than these metals is used for the entire outer portion (61). The portions having different specific gravities of the materials may be a part of both the portions (59) and (61).

When adjusting the center of gravity of the movable part (57), the mass of the movable part (57) may be changed. However, when the natural frequency of the vibration system is set to the power supply frequency, the piston spring ( It is necessary to change the spring constant of 41) to absorb the mass change of the movable part (57). However, since the selection range of the piston spring (41) is limited, there is a limit to the absorption of the above-mentioned mass change, and if the condition of setting the natural frequency to the power supply frequency is to be observed, the movable part (57) will not be affected. In some cases, the center of gravity (F) cannot be located in the cylinder (13). For this reason, the mass of the movable part (57) is set to be the same as the mass of the movable part (57) when the specific gravity of the materials of both parts (59) and (61) is the same, and the mass of the movable part (57) is Keep it unchanged.

As shown in FIG. 2, the expander (3) has a cylindrical cylinder (63) and a free displacer (65) fitted in the cylindrical cylinder (63) so as to be capable of reciprocating. And the free displacer (6
5) shows the space inside the cylindrical cylinder (63) in the expansion chamber (B)
And the working chamber (C). A displacer spring (67), which is a coil spring that elastically supports the free displacer (65) on the cylindrical cylinder (63), is arranged in the working chamber (C), and inside the free displacer (65). The regenerator material (69) made of metal is filled. The free displacer (65) is provided with a first communication hole (71) at the end of the free displacer (65) on the side of the expansion chamber (B) that allows the refrigerant gas to flow between the free displacer (65) and the expansion chamber (B). Refrigerant gas is supplied to the working chamber (C) at the end on the C side.
A second communication hole (73) is provided for communication between Further, the working chamber (C) communicates with the compression chamber (A) of the compressor (1) via a connecting pipe (31).

Next, the operation of the Stirling refrigerator will be described. The two linear motors (43) and (43) in the compressor (1) resonate the vibration system to generate a pair of pistons (21) and (21). Are reciprocally moved in opposite directions in the same phase to increase / decrease the volume of the compression chamber (A) to generate a pressure wave of a predetermined cycle in the refrigerant gas in the compression chamber (A). The pressure wave in the compression chamber (A) is generated by the gas passage (2
9), propagates to the working chamber (C) of the expander (3) through the connecting passage (31) and the coupling pipe (31). Due to the pressure wave, the displacer of the expander (3) reciprocates in the same cycle as the pressure wave, expands the refrigerant gas in the expansion chamber (B) to generate cold, and the cold at the tip of the cylindrical cylinder (63). Cool the head to cryogenic levels.

Next, the function and effect of the movable part (57) will be described. The mass of the inner part (59) of the movable part (57) at the expansion side dead center of the reciprocating movement is set to the outer part (61).
3, the center of gravity (F) of the movable part (57) is always located in the cylinder (13) during the operation of the piston (21), as shown in FIG. Therefore, the piston (21) can be held horizontally and uneven wear due to one-sided contact can be eliminated, and the life of the compressor (1) can be extended, and thus the life of the Stirling refrigerator can be extended.

Further, since the specific gravity of the material of the inner part (59) is made larger than the specific gravity of the material of the outer part (61), the center of gravity (F) of the movable part (57) is not changed. Can be adjusted and there is no need to change the shape inside the compressor (1).

Further, since the mass of the movable part (57) is set to be the same as the mass of the movable part (57) when the specific gravity of the material of the both parts (59) and (61) is the same, the movable part is set. The mass of (57) can be kept unchanged. Therefore, since the natural frequency of the vibration system is set to the power supply frequency and the change of the two spring constants is limited, the mass of the movable portion (57) cannot be changed freely. Even in the case of the first embodiment, the movable part (5
The center of gravity of 7) can be adjusted.

FIG. 4 shows a second embodiment of the present invention. In the second embodiment, a weight (75) for making the mass of the inner part (59) larger than that of the outer part (61) is added to the inner part (59) of the movable part (57). . In this case, the operating frequency of the linear motor (43) is set to a predetermined value corresponding to the natural frequency changed with the addition of the weight (75). The other structure is the same as that of the first embodiment. According to the second embodiment, the weight (7
Since only 5) is added, the center of gravity can be easily adjusted.

FIG. 5 shows a third embodiment of the present invention. In the third embodiment, the outer portion (61) of the movable portion (57) is provided with a thin portion (77) for making the volume of the outer portion (61) smaller than the volume of the inner portion (59). is there. The thin portion (77) is provided on the bobbin (53), and the thin portion (77) has the mass of the outer portion (61) equal to that of the inner portion (5).
It is formed in a shape smaller than the mass of 9). Further, the operating frequency of the linear motor (43) is set to a predetermined value corresponding to the natural frequency that has changed due to the formation of the thin portion (77). The other structure is the same as that of the first embodiment. Also in the third embodiment, the center of gravity can be easily adjusted.

FIG. 6 shows a modification of the third embodiment. In this modified example, the bobbin (53) and the brim portion (49) are manufactured as one member, and the thin portion (77) is formed on the member to adjust the center of gravity, so that the number of parts can be reduced. it can. The other structure is the same as that of the first embodiment.

The present invention is not limited to the above embodiment, but includes various modifications. For example, the adjustment of the center of gravity in each of the above-described embodiments is not limited to being performed individually, and two or more may be used in combination. For example, the second embodiment and the third embodiment described above are used in combination, and the weight (75) is attached to the inner portion (59) of the movable portion (57) and the outer portion (61).
The center of gravity may be adjusted by providing thin portions (77) respectively.

[0031]

As described above, according to the compressor of the first aspect of the present invention, the mass of the inner part (59) of the movable part (57) is set larger than the mass of the outer part (61). Since the center of gravity (F) of the movable part (57) can be always positioned in the cylinder (13) during the operation of the piston (21), the piston (21) is always held horizontally and the partial contact is caused. Uneven wear can be eliminated and the life of the compressor can be extended.

According to the second aspect of the invention, the specific gravity of the material of the inner portion (59) is made larger than the specific gravity of the material of the outer portion (61). The center of gravity of (57) can be adjusted, and it is not necessary to change the shape inside the compressor.

On the other hand, according to the invention of claim 3, by adding the weight (75) to the inner part (59), the volume of the outer part (61) is increased according to the invention of claim 4. By making it smaller than the volume of the inner part (59),
The center of gravity of the movable part (57) can be easily adjusted.

Further, in the invention according to claim 5, the mass of the movable part (57) is set to be the same as the mass of the movable part (57) when the materials of the both parts (59) and (61) are the same. Since the center of gravity of the movable part (57) is adjusted, the mass of the movable part (57) does not change, and for example, when a vibration system having the movable part (57) as a mass element is provided in the compressor, Even if the mass of the movable part (57) cannot be freely changed because the natural frequency of the vibration system is specified and the change of the spring constant of the vibration system is limited, the movable part (57) is not changed. The center of gravity of the compressor can be adjusted without being restricted by other design items of the compressor.

[Brief description of drawings]

FIG. 1 is a vertical sectional view of a compressor according to a first embodiment of the present invention.

FIG. 2 is a vertical sectional view of an expander.

FIG. 3 is an enlarged sectional view of a main part of a cylinder and a movable part of a compressor.

FIG. 4 is an enlarged sectional view of essential parts of a cylinder and a movable portion of a compressor according to a second embodiment of the present invention.

FIG. 5 is an enlarged sectional view of essential parts of a cylinder and a movable part of a compressor according to a third embodiment of the present invention.

FIG. 6 is an enlarged cross-sectional view of a cylinder and a movable portion of a compressor according to a modified example of the third embodiment.

FIG. 7 is an enlarged cross-sectional view of a main part of a cylinder and a movable part of a conventional compressor.

[Explanation of symbols]

 13 Cylinder 17a Opening of Inner Tube (Cylinder Opening) 21 Piston 41 Piston Spring (Spring Member) 43 Linear Motor 47 Magnet 55 Coil 57 Movable Part 59 Inner Part of Movable Part 61 Outer Part of Movable Part 75 Weight

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Naoshi Kamisaka 1304 Kanaoka-machi, Sakai City, Osaka Daikin Industries, Ltd.Kanaoka Plant, Sakai Manufacturing Co., Ltd. (72) Ryuzo Sotojima 1304, Kanaoka-machi, Sakai, Osaka Prefecture Sakai Factory Kanaoka Factory

Claims (5)

[Claims] 1. A cylinder (13) arranged with its axis lined in a horizontal direction, and a part of the cylinder (13) is reciprocatingly fitted in the cylinder (13) to compress the working fluid in the cylinder (13). (21) for generating a pressure wave by means of a spring, a spring member (41) for urging the piston (21) so as to position the piston (21) in a neutral position in the cylinder (13), a magnet (47) and a coil. (55) and the magnet (4
7) or the coil (55) is provided in a portion of the piston (21) extending outside the cylinder (13), and
A linear motor (43) for exciting the piston (21) by the interaction of the two (47) and (55), and a magnet (47) or coil (55) provided on the piston (21); In the compressor in which the piston (21) constitutes a movable part (57), the movable part (57) is located at a dead point where the piston (21) is most moved outside the cylinder (13). ,
The mass of the inner portion (59) existing inside the cylinder (13) from the position of the opening (17a) of the cylinder (13) is
The compressor is characterized in that the mass is set to be larger than the mass of the outer portion (61) existing outside the cylinder (13) from the position of the opening (17a). 2. The inner part (59) of the movable part (57).
And the outer part (61) are made of different materials,
The specific gravity of the material of the inner part (59) is greater than the specific gravity of the material of the outer part (61).
The described compressor. 3. The inner part (59) of the movable part (57).
The mass of the inner part (59) to the outer part (6).
The compressor according to claim 1, further comprising a weight (75) for making the mass larger than that of (1). 4. The outer part (61) of the movable part (57).
A compressor according to claim 1, wherein the volume of the inner part (59) is smaller than the volume of the inner part (59) so that the mass of the outer part (61) is smaller than the mass of the inner part (59). 5. The mass of the movable part (57) is set to be the same as the mass of the movable part (57) when the material of the inner part (59) and the material of the outer part (61) are the same. The compressor according to claim 2, wherein