JP4670529B2 - Compressor - Google Patents

Description

  The present invention relates to a compressor in which a compression mechanism is housed in a hermetic casing, and more particularly to the structure of a silencer mechanism provided in a high-pressure dome-shaped compressor in which the inside of the casing becomes the discharge pressure of the compressor.

  Conventionally, as this type of compressor, a compression mechanism and an electric motor are provided in a hermetic casing, and a suction pipe fixed to the casing communicates with a suction port of the compression mechanism, and a high pressure discharged from the compression mechanism. Some gas is discharged to the outside from a discharge pipe provided in the casing after the gas is filled in the casing (see, for example, Patent Document 1).

  In the compressor of Patent Document 1, the casing is formed of a sealed container including a vertically long cylindrical barrel, an upper end plate fixed to the upper end of the barrel portion, and a lower end plate fixed to the lower end of the barrel portion. It is configured. The electric motor includes a stator and a rotor, and the stator is fixed to the casing at an intermediate position in the vertical direction of the casing. The compression mechanism is fixed to the casing on the space side below the motor, and is connected to the rotor of the motor via a drive shaft. The casing body is provided with a suction pipe connected to the compression mechanism, while the upper end plate is provided with a discharge pipe that opens in a space above the motor.

  The compression mechanism includes a cylindrical cylinder, an upper bearing member (front head) fixed to the upper end surface of the cylinder, a lower bearing member (rear head) fixed to the lower end surface of the cylinder, these cylinders, and the front head , And a rotating piston disposed in a cylinder chamber defined by the rear head so as to be able to rotate eccentrically, and the rotating piston is coupled to the drive shaft.

  The front head is formed with a discharge port for discharging high-pressure gas upward from the compression mechanism. The compression mechanism is provided with a discharge cover (muffler) that covers the discharge port and forms an expansion space for the discharge gas.

In the compressor of Patent Document 1, an arc-shaped space is formed in the outer peripheral edge portion of the cylinder so as to communicate with the space in the discharge cover in order to expand the volume of the expansion space. Then, the discharge gas discharged from the compression mechanism into the space in the discharge cover is introduced into the arcuate space of the cylinder from one end, and after the discharge gas flows through the arcuate space, the other end of the arcuate space is inserted into the casing. To be leaked. By doing so, the volume of the expansion space is expanded to improve the silencing effect.
JP-A-8-334095

  However, in the above conventional compressor, the discharge gas blown upward from the discharge port of the compression mechanism is reflected by the discharge cover and introduced into the arcuate space of the cylinder. It bends and does not function sufficiently as an inflatable silencer.

  In addition, the arc-shaped space can be formed only to a length of about 2/3 of a half circumference of the cylinder, and a sufficient path length cannot be obtained. Therefore, the effect of reducing low-frequency pulsation noise is particularly low. There was also a problem.

  The present invention has been made in view of the above points, and an object of the present invention is to prevent bending of the discharge gas in the discharge gas outflow path in an expansion-type silencing mechanism used in a high-pressure dome-type compressor. Accordingly, it is possible to prevent the function of the expansion type silencing mechanism from being lowered and to reduce the low-frequency pulsation noise by making the discharge gas outflow path sufficiently long.

  The first invention is a compression mechanism (20) that compresses and discharges gas, a casing (10) that houses the compression mechanism (20), and a suction pipe (14) that communicates with the suction side of the compression mechanism (20). ), A discharge pipe (15) provided in the casing (10) so as to open into a space in the casing (10), and a discharge port (29) provided in the compression mechanism (20) And a silencing mechanism (47) having a discharge cover (43) in which a discharge gas outlet (46) from the expansion space (42) into the casing (10) is formed. A compressor is assumed.

In this compressor, the expansion space (42) is formed along one or more spiral paths passing through the discharge port (29) and the discharge gas outlet (46) .

  In the first invention, the discharge gas discharged from the discharge port (29) of the compression mechanism (20) into the discharge cover (43) is a spiral expansion space (42) formed in the discharge cover (43). ) And is discharged into the casing (10) from the discharge gas outlet (46) of the discharge cover (43). Since the expansion space (42) is formed along one or more spiral paths, the path length of the expansion space (42) is longer than the path length of the expansion space (42) in the conventional silencing mechanism (47). can do.

  Here, the peak frequency of the sound attenuation amount in the silencer mechanism (47) has a characteristic that is inversely proportional to four times the path length of the expansion space (42). Therefore, if the path length is increased, the peak frequency of the acoustic attenuation can be lowered. That is, the low frequency component of the pressure wave of the discharge gas can be absorbed by the silencer mechanism (47).

The first invention further includes a path length variable mechanism (50) for changing the path length of the expansion space (42) formed in a spiral shape.

In the first invention, the path length of the expansion space (42) can be changed by the path length variable mechanism (50). When the path length of the expansion space (42) is changed, the peak frequency of the acoustic attenuation amount can be changed.

According to a second aspect, in the first aspect, the variable path length mechanism (50) is configured to change the path length of the expansion space (42) according to the rotational speed of the compression mechanism (20). It is a feature.

In the second aspect of the invention, when the compressor is of a variable rotational speed type (variable capacity type), the path length can be changed according to the rotational speed of the compression mechanism (20). Here, most of the pulsating noise of the discharge gas of the compressor occupies a frequency component that is almost an integral multiple of the rotational frequency of the compressor. Therefore, if the path length of the expansion space (42) is changed using the path length variable mechanism (50), the peak frequency of the sound attenuation amount is a value that is approximately an integer multiple of the rotational frequency of the compressor (with the compressor). The frequency of pulsating noise, which is the most problematic, can be adjusted.

According to a third invention, in any one of the first and second inventions, the compression mechanism (20) includes a drive shaft (33), a cylindrical cylinder (21), and one of the cylinders (21). A front head (22) through which the drive shaft (33) passes, fixed to the end surface of the cylinder, a rear head (23) fixed to the other end surface of the cylinder (21) and through which the drive shaft (33) passes, 21), a piston (24) which is located in a cylinder chamber (25) defined by a front head (22) and a rear head (23) and which is connected to a drive shaft (33) and rotates eccentrically in the cylinder chamber (25). Between the discharge cover (43) and one of the front head (22) and the rear head (23) and the discharge gas outlet of the discharge cover (43). A spiral groove (42) communicating with (46) is formed to form an expansion space (42) It is characterized.

In the third invention, the expansion space (42) is formed by the spiral groove (42) between one of the front head (22) and the rear head (23) and the discharge cover (43), and the compression mechanism (20 ) Discharge gas discharged from the discharge port (29) into the expansion space (42) passes through the expansion space (42) from the discharge gas outlet (46) of the discharge cover (43) into the compressor casing (10). Discharged.

According to a fourth aspect of the present invention, there is provided a compression mechanism (20) for compressing and discharging a gas, a casing (10) for housing the compression mechanism (20), and a suction pipe (14) communicating with the suction side of the compression mechanism (20). ), A discharge pipe (15) provided in the casing (10) so as to open into a space in the casing (10), and a discharge port (29) provided in the compression mechanism (20) And a silencing mechanism (47) having a discharge cover (43) in which a discharge gas outlet (46) from the expansion space (42) into the casing (10) is formed. A compressor is assumed.

  In the compressor, the expansion space (42) is formed along one or more spiral paths passing through the discharge port (29) and the discharge gas outlet (46), and the compression mechanism (20) A drive shaft (33), a cylindrical cylinder (21), a front head (22) fixed to one end face of the cylinder (21) and through which the drive shaft (33) passes, and the cylinder (21) Located in the cylinder chamber (25) defined by the rear head (23) fixed to the other end face and through which the drive shaft (33) passes, and the cylinder (21), the front head (22), and the rear head (23) The piston (24) is connected to the drive shaft (33) and rotates eccentrically in the cylinder chamber (25). Between the front head (22) and the rear head (23) and the discharge cover (43) A first spiral groove (42a) communicating with the discharge port (29) of the compression mechanism (20) is formed, A second spiral groove (42b) communicating with the discharge gas outlet (46) of the discharge cover (43) is formed between one of the front head (22) and the rear head (23) and the cylinder (21), The first spiral groove (42a) and the second spiral groove (42b) communicate with each other to form an expansion space (42).

In the fourth aspect of the invention, the first spiral groove (42a) between one of the front head (22) and the rear head (23) and the discharge cover (43), the front head (22) and the rear head (23 ) And the second spiral groove (42b) between the cylinder (21) and an expansion space (42) are formed from the discharge port (29) of the compression mechanism (20) to the expansion space (42). The discharge gas discharged in the flow passes through the expansion space (42) and is discharged from the discharge gas outlet (46) of the discharge cover (43) into the casing (10) of the compressor.

According to a fifth invention, in any one of the first to fourth inventions, the discharge port (29) of the compression mechanism (20) is formed at a position in the middle of the spiral path in the expansion space (42). It is characterized by that.

In addition, according to a sixth aspect, in any one of the first to fifth aspects, the discharge gas outlet (46) of the discharge cover (43) is formed at a position in the middle of the spiral path in the expansion space (42). It is characterized by being.

In these second and third inventions, the discharge port (29) of the compression mechanism (20) and the discharge gas outlet (46) of the discharge cover (43) are positioned in the middle of the spiral path in the expansion space (42). Since it is formed, reflection of the pressure wave at the end face of the expansion space (42) occurs, and a standing wave is generated.

According to a seventh invention, in any one of the first to sixth inventions, the discharge gas outlet (46) of the discharge gas cover is located at a position corresponding to the node of the standing wave of pressure in the expansion space (42). It is characterized by being formed.

In the seventh aspect of the invention, since the discharge gas outlet (46) is arranged at the position of the standing wave node, the discharge gas is discharged from the discharge gas outlet (46) with the smallest amplitude. Become.

In an eighth invention according to any one of the first to seventh inventions, a throttle passage (48) is provided at a position in the middle of the spiral path in the expansion space (42), and the expansion space (42) It is characterized by being formed in a plurality of stages through the throttle passage (48).

In the eighth aspect of the invention, a multistage silencing effect can be obtained by the expansion action at the front stage of the throttle passage (48) and the expansion action at the rear stage of the throttle passage (48).

  According to the present invention, since the expansion space (42) is formed along one or more spiral paths passing through the discharge port (29) and the discharge gas outlet (46), the expansion space (42) The path length can be made longer than the path length of the expansion space (42) in the conventional silencing mechanism (47). Therefore, since the peak frequency of the acoustic attenuation amount can be lowered, the low frequency component of the pressure wave of the discharge gas can be absorbed by the silencer mechanism (47).

    In addition, since the expansion space (42) is formed in a spiral shape, the discharge gas flows in a plane along the path of the expansion space (42) and is smooth to the discharge gas outlet (46) without bending three-dimensionally. Flowing into. Therefore, it is possible to prevent the function of the expansion-type silencing mechanism (47) from being deteriorated due to bending of the pressure wave of the discharge gas.

In addition, by providing a variable path length mechanism (50) that changes the path length of the expansion space (42) formed in a spiral shape, the path length of the expansion space (42) can be changed and the peak of the sound attenuation amount can be obtained. It becomes possible to change the frequency. Therefore, it is possible to match the peak of the sound attenuation amount to the frequency of the pressure wave that causes a problem in each compressor.

According to the second aspect of the present invention, by changing the path length of the expansion space (42) using the path length variable mechanism (50), the peak frequency of the sound attenuation amount is substantially equal to the rotational frequency of the compressor. Since it can be adjusted to an integer multiple (the frequency of the pulsating noise that is most problematic in the compressor), the noise reduction effect can be enhanced.

According to the third aspect, the expansion space (42) is formed by the spiral groove (42) between one of the front head (22) and the rear head (23) and the discharge cover (43), and the compression mechanism The discharge gas discharged from the discharge port (29) of (20) into the expansion space (42) passes through this expansion space (42) and is discharged from the discharge gas outlet (46) of the discharge cover (43) to the casing (10 ), The structure of the silencer mechanism (47) can be simplified.

According to the fourth invention, the first spiral groove (42a) between one of the front head (22) and the rear head (23) and the discharge cover (43), the front head (22) and the rear head. An expansion space (42) is formed by the second spiral groove (42b) between one of (23) and the cylinder (21), and the expansion space (42) is formed from the discharge port (29) of the compression mechanism (20). The discharge gas discharged to 42) passes through the expansion space (42) and is discharged from the discharge gas outlet (46) of the discharge cover (43) into the compressor casing (10). The structure of the mechanism (47) can be simplified and the path length can be made longer.

According to the fifth and sixth inventions, the discharge port (29) of the compression mechanism (20) and the discharge gas outlet (46) of the discharge cover (43) are positioned in the middle of the spiral path in the expansion space (42). Therefore, the reflection of the pressure wave at the end face of the expansion space (42) occurs reliably, and the standing wave is generated reliably.

According to the seventh aspect, the discharge gas outlet (46) of the discharge gas cover is formed at a position corresponding to the node of the standing wave of pressure in the expansion space (42). In this state, the gas is discharged from the discharge gas outlet (46). For this reason, pulsation noise can be reduced.

According to the eighth aspect of the present invention, the throttle passage (48) is provided in the middle of the spiral path in the expansion space (42), and the expansion space (42) is formed in a plurality of stages. Since the effect can be obtained, the peak value of the sound attenuation amount can be improved over a wide area, and the sound deadening function can be enhanced.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

<< Reference Technology 1 of Invention >>
As shown in FIGS. 1 and 2, the compressor of the reference technique 1 includes a so-called rotary piston type compressor (1). The compressor (1) includes a casing (10) in which a compression mechanism (20) that compresses and discharges a gas and an electric motor (30) that drives the compression mechanism (20) are housed. It is configured. The compressor (1) is configured as a variable capacity compressor in which the electric motor (30) is inverter-controlled so that the capacity is variable stepwise or continuously. And this compressor (1) drives a compression mechanism (20) with an electric motor (30), for example, sucks and compresses a refrigerant, and then discharges it and circulates it in a refrigerant circuit.

  The casing (10) is joined to the cylindrical body (11), the upper end plate (12) joined to the upper end opening of the body (11), and the lower end opening of the body (11). The lower end plate (13) is formed into a vertically long cylindrical sealed container.

The space in the casing (10) is partitioned into a first space (S1) and a second space (S2) positioned above and below the electric motor (30). In this reference technique 1 , the first space (S1) is disposed below the electric motor (30), and the second space (S2) is disposed above the electric motor (30). A compression mechanism (20) is disposed in the first space (S1).

  In the casing (10), a suction pipe (14) is provided at the lower part of the body part (11), and a discharge pipe (15) is provided in the upper end plate (12). The suction pipe (14) communicates with the suction side of the compression mechanism (20) through the casing (10), and the discharge pipe (15) is opened to open into a space in the casing (10). It is fixed to the end plate (12). That is, the suction pipe (14) is provided at a position on the first space (S1) side in the casing (10), and the discharge pipe (15) is provided at a position on the second space (S2) side in the casing (10). It has been. An accumulator (16) is connected to the suction pipe (14).

  The compression mechanism (20) includes a cylinder (21), a front head (22), a rear head (23), and a rotary piston (24), and the front head (22) is located at the upper end of the cylinder (21). The rear head (23) is fixed to the lower end.

  The cylinder (21) is formed in a thick cylindrical shape. A cylindrical cylinder chamber (25) is defined between the inner peripheral surface of the cylinder (21), the lower end surface of the front head (22), and the upper end surface of the rear head (23). The cylinder chamber (25) is configured such that the rotating piston (24) performs an eccentric rotation operation in the cylinder chamber (25).

  The electric motor (30) includes a stator (31) and a rotor (32). A drive shaft (33) for driving the compression mechanism (20) is connected to the rotor (32). The drive shaft (33) passes through the center of the casing (10) and penetrates the cylinder chamber (25) in the vertical direction. Bearing parts (22a, 23a) for supporting the drive shaft (33) are formed in the front head (22) and the rear head (23), respectively.

  The drive shaft (33) is composed of a main body (33b) and an eccentric part (33a) located in the cylinder chamber (25). The eccentric portion (33a) is formed to have a larger diameter than the main body portion (33b), and is eccentric by a predetermined amount from the rotation center of the drive shaft (33). A rotating piston (24) of the compression mechanism (20) is attached to the eccentric part (33a). As shown in FIG. 2, the rotary piston (24) is formed in an annular shape and its outer peripheral surface is formed so as to be substantially in contact with the inner peripheral surface of the cylinder (21) at one point.

  A blade groove (21a) is formed in the cylinder (21) along the radial direction of the cylinder (21). A blade (26) formed in a rectangular plate shape is mounted in the blade groove (21a) so as to be slidable in the radial direction of the cylinder (21). The blade (26) is urged radially inward by a spring (27) provided in the blade groove (21a), and the tip always contacts the outer peripheral surface of the rotary piston (24).

  The blade (26) divides a cylinder chamber (25) between an inner peripheral surface of the cylinder (21) and an outer peripheral surface of the rotary piston (24) into a suction chamber (25a) and a compression chamber (25b). Yes. The cylinder (21) has a suction port (28) penetrating in a radial direction from the outer peripheral surface to the inner peripheral surface of the cylinder (21) and communicating the suction pipe (14) and the suction chamber (25a). Is formed. The front head (22) is formed with a discharge port (29) that penetrates in the axial direction of the drive shaft (33) and communicates the compression chamber (25b) and the space in the casing (10). .

  The front head (22) is provided with a discharge valve mechanism (40) for opening and closing the discharge port (29). The discharge valve mechanism (40) includes a reed valve (41) and a valve presser (not shown) that regulates the amount of deflection of the reed valve (41). In the reed valve (41), the valve presser is stacked from above, and is sandwiched between the front head (22) and the valve presser. The reed valve (41) and the valve retainer are fixed to the front head (22) by fastening bolts on the base end side (not shown).

The front head (22) is equipped with a discharge cover (43) that covers a discharge port (29) provided in the compression mechanism (20) and forms an expansion space (42) for discharge gas. The discharge cover (43) is formed integrally with an end plate (44) and a side wall (45). The end plate (44) is connected to the inside of the casing (10) from the expansion space (42). A discharge gas outlet (46) through which the discharge gas flows is formed. And the silencer mechanism (47) of this reference technique 1 is comprised by the discharge cover (43) which has this expansion space (42).

  FIG. 3A shows a cross-sectional shape (a cross-sectional shape taken along line III-III in FIG. 1) of the discharge cover (43). As shown in the drawing, the expansion space (42) is formed along a spiral path of one or more rounds passing through the discharge port (29) and the discharge gas outlet (46). This spiral path is defined by a spiral wall (43a). Considering a coordinate system based on the center of the drive shaft, the discharge port (29) is arranged in the passage inside the fourth quadrant of FIG. 3A in this spiral path, and the passage outside the first quadrant A discharge gas outlet (46) is arranged. However, the arrangement of the discharge port (29) and the discharge gas outlet (46) is not limited to the arrangement shown in the figure.

  As shown in FIG. 3A, the discharge port (29) of the compression mechanism (20) is formed not at the position of the end of the spiral path in the expansion space (42) but at the midway position thereof. The discharge gas outlet (46) of the discharge cover (43) is also formed at a position in the middle of the expansion space (42), not at the end of the spiral path.

  The discharge gas blown out from the discharge port (29) of the compression mechanism (20) into the spiral expansion space (42) flows in the clockwise direction in FIG. 3 (A), and the discharge gas outlet ( 46) is blown into the casing (10). On the other hand, in the expansion space (42), reflected waves generated at both end faces (42a, 42b) of the expansion space (42) act on the pressure wave (traveling wave) of the discharge gas, so that standing waves are generated. appear. The discharge gas outlet (46) is formed at a position corresponding to a node of a standing wave of pressure in the expansion space (42).

FIG. 3B is a diagram schematically showing the positional relationship between the expansion space (42), the discharge port (29), and the discharge gas outlet (46). If the path length of the expansion space is l and the distance from the end surface (42b) of the expansion space to the discharge gas outlet (46) is l ₀ ,
l ₀ = l / 4 or l ₀ = l / 2
It is better to satisfy the relational expression.

-Driving action-
Next, the operation of the compressor (1) described above will be described.

  First, when the electric motor (30) is energized, the rotor (32) rotates, and the rotation of the rotor (32) is applied to the rotary piston (24) of the compression mechanism (20) (20) via the drive shaft (33). Communicated. As a result, the compression mechanisms (20) and (20) perform a predetermined compression operation.

  Specifically, the compression operation of the compression mechanisms (20) and (20) will be described with reference to FIG. When the rotary piston (24) is rotated clockwise (clockwise) in the figure by driving the electric motor (30), the volume of the suction chamber (25a) is increased according to the rotation, and a low-pressure refrigerant is supplied to the suction chamber (25a). Is inhaled through the inlet (28). The refrigerant is sucked into the suction chamber (25a) when the rotary piston (24) rotates eccentrically in the cylinder chamber (25), and the cylinder (21) and the rotary piston (24) are located immediately to the right of the suction port (28). Continue until is in contact.

  As described above, when the rotation of the rotary piston (24) completes the suction of the refrigerant, the compression chamber (25b) in which the refrigerant is compressed is formed. A new suction chamber (25a) is formed next to the compression chamber (25b), and the suction of the refrigerant into the suction chamber (25a) is repeated. The refrigerant in the compression chamber (25b) is compressed as the volume of the compression chamber (25b) decreases as the rotary piston (24) rotates.

  When the compression chamber (25b) reaches a predetermined high pressure, the pressure acts on the reed valve (41), thereby opening the discharge port (29). The refrigerant in the compression chamber (25b) is discharged from the discharge port (29) into the discharge cover (43). When the high-pressure refrigerant is discharged and the compression chamber (25b) becomes low pressure, the reed valve (41) closes the discharge port (29) by its own spring force. In this manner, refrigerant suction, compression, and discharge are repeated.

  The high-pressure refrigerant discharged from the compression mechanism (20) passes from the expansion space (42) in the discharge cover (43) through the discharge gas outlet (46) into the first space (S1) in the casing (10). Blown out. At that time, the pulsation noise of the discharge gas is reduced by the expansion action in the expansion space (42).

Here, the frequency at which the sound attenuation amount reaches a peak will be described with reference to FIG. 4 which is a conceptual diagram of the expansion type silencing mechanism. In FIG. 4, when the path length of the expansion space is l (m) and the sound velocity is c (m / s), the frequency f (Hz) at which the acoustic attenuation reaches a peak is
f = nc / 4l
Is satisfied. In this relational expression, n is an odd number. From this, it can be seen that the frequency at which the sound attenuation amount reaches a peak shifts to the lower frequency side as the length of the expansion space (42) increases, and the peak of the sound attenuation amount rises at every odd multiple of the frequency.

The acoustic attenuation TL is
TL = 10 · log ₁₀ {1+ (1/4) (m−1 / m) ² sin ² kl}
Is satisfied. Here, m = (D ₂ / D ₁ ) ² and k = 2πf / c.

  From the above relational expression, when c = 170 (m / s), l = 60 (mm), and m = 5, the peak of the sound attenuation amount is an odd number of about 700 (Hz) as shown in FIG. When c = 170 (mm), l = 400 (mm), and m = 5, the sound attenuation peak appears at an odd multiple of about 100 (Hz) as shown in FIG. In this way, compared with the conventional expansion type silencing mechanism that can only make the path length only about 60 mm, the path is spiraled to about 400 mm so that low frequency pulsation noise is obtained. Can be greatly attenuated. Moreover, since the peak frequency of the acoustic attenuation amount is shifted to the low frequency side and the peak frequency rises every odd number of times, the noise reduction effect is enhanced over the entire range from the low frequency to the high frequency.

-Effects of Reference Technology 1-
Thus, according to the present reference technique 1 , the expansion space (42) is formed along a spiral path of one or more rounds passing through the discharge port (29) and the discharge gas outlet (46). The path length of the expansion space (42) can be made longer than before, and the effect of reducing low frequency pulsation noise can be enhanced. Further, as a result of the peak frequency of the sound attenuation amount being shifted to the low frequency side and rising at an odd number, the effect of increasing the noise reduction effect from the low frequency to the high frequency can be obtained.

Further, in this reference technique 1 , when the discharge gas discharged from the compression mechanism (20) discharge port (29) is discharged from the expansion space (42) through the discharge gas outlet (46) into the casing (10). In addition, since the pressure wave is not refracted in the middle and flows smoothly on the plane along the spiral path, it is possible to obtain a sufficient effect as an expansion type silencing mechanism.

  Further, the discharge port (29) of the compression mechanism (20) and the discharge gas outlet (46) of the discharge cover (43) are formed in the middle of the spiral path in the expansion space (42). Since the discharge gas outlet (46) is disposed at the position of the standing wave node, the discharge gas is discharged from the discharge gas outlet (46) with the smallest amplitude. Become.

<< Reference Technology 2 of Invention >>
In Reference Technology 2 , as shown in FIG. 6, a throttle passage (48) is provided in the middle of the spiral path in the expansion space (42), and the expansion space (42) passes through the throttle passage (48). Are formed in multiple stages. The throttle passage (48) is constituted by the pores of the partition wall (49) provided in the spiral path of the expansion space (42).

Other configurations are the same as those of the reference technique 1 .

FIG. 7 is a graph showing the acoustic attenuation characteristics when c = 170 (mm), the first stage path length l ₁ = 400 (mm), and the second stage path length l ₂ = 200 (mm). . As shown in the figure, the peak value of the acoustic attenuation can be increased as compared with the reference technique 1 by making the spiral path into two stages and changing the path length of each stage. Therefore, the silencing effect can be enhanced over a wide range.

In this reference technique 2 , the expansion space (42) is formed in a two-stage spiral shape, but may be three or more stages.

Embodiment 1 of the Invention
Embodiment 1 of the present invention is an example in which a path length variable mechanism (50) capable of changing the path length of the spiral expansion space (42) is provided in the structure of the silencer mechanism (47) of Reference Technique 1. is there.

  In FIG. 8, the variable path length mechanism (50) includes a slide block (51) whose position can be changed along the side spiral path near the end face (42b) of the expansion space (42), and the slide block (51) It is comprised from the spring (52) provided between the end surfaces (42b), and the low voltage | pressure introduction port (53) provided in the vicinity of the end surface (42b) in expansion space (42). Although not shown in the figure, the low-pressure inlet (53) is provided with an open / close valve such as an electromagnetic valve or an electric valve with variable opening.

  In this example, the low pressure gas is introduced from the low pressure inlet (53) into the end surface (42b) side of the expansion space (42), whereby the first surface (51a) side and the second surface (51b) of the slide block (51). ) Side and pressure difference occurs. Therefore, a force for moving the slide block (51) along the spiral path is generated, and the slide block (51) is moved by the force to change the path length of the expansion space (42). When the path length is changed in this way, the peak frequency of the acoustic attenuation can be adjusted.

  The path length variable mechanism (50) is configured to change the path length according to the rotation speed of the compression mechanism (20) when the compressor (1) is of a variable rotation speed type (variable capacity type). be able to. Specifically, the pulsating noise of the discharge gas of the compressor (1) is mainly composed of frequency components that are almost an integral multiple of the rotational frequency of the compressor (1). Therefore, if the path length of the expansion space (42) is changed using the path length variable mechanism (50), the peak frequency of the sound attenuation amount is a value that is approximately an integer multiple of the rotational frequency of the compressor (1) The frequency of pulsating noise, which is the most problematic in the compressor, can be adjusted. As a result, the noise reduction effect can be enhanced.

(First modification)
As shown in FIG. 9, the variable path length mechanism (50) can also be composed of a slide block (51) and an adjustment screw (55) for adjusting the position of the slide block (51). The adjustment screw (55) is screwed into the screw hole (55a) of the discharge cover (43), and by adjusting the amount of protrusion from the end surface (42b) of the expansion space (42), the slide block (51) Can be adjusted. Specifically, when the protrusion amount is increased, the slide block (51) can be pushed away from the end face (42b) of the expansion space (42), while when the protrusion amount is decreased, the expansion space (42) The slide block (51) moves in a direction approaching the end surface (42b) with the pressure of.

  Also in this first modified example, the peak frequency of the acoustic attenuation can be adjusted by adjusting the path length of the expansion space (42). In addition, when the compressor (1) is a variable rotational speed type (variable capacity type), the path length can be changed according to the rotational speed of the compression mechanism (20). The noise reduction effect can be enhanced in accordance with a value that is almost an integral multiple of the rotational frequency of the compressor (1) (the frequency of the pulsating noise that causes the most problems with the compressor).

(Second modification)
As shown in FIG. 10, the variable path length mechanism (50) can also be constituted by a rotary valve (56) in which a discharge gas passage (57) is formed. This rotary valve (56) can shorten the path length of the expansion space (42) when in the “closed” state, and can increase the path length of the expansion space (42) when in the “open” state. It is configured to be able to. In the figure, the gap between the outer peripheral surface of the valve (56) and the discharge cover (43) is exaggerated, but this gap is actually a fine gap.

  Also in the second modification, the path length of the expansion space can be adjusted, so that the peak frequency of the acoustic attenuation amount can be adjusted. In addition, when the compressor (1) is a variable rotational speed type (variable capacity type), the path length can be changed according to the rotational speed of the compression mechanism (20). The noise reduction effect can be enhanced in accordance with a value that is almost an integral multiple of the rotational frequency of the compressor (1) (the frequency of the pulsating noise that causes the most problems with the compressor).

<< Reference Technology 3 of Invention >>
In Reference Technology 3 of the present invention, the expansion space (42) is formed in the front head (22), and the discharge cover (43) is formed in a flat plate shape.

11A is a cross-sectional view of the silencer mechanism 47, FIG. 11B is a plan view of the discharge cover 43, and FIG. 11C is a plan view of the front head 22. As shown in the drawing, a groove (42) formed along a spiral path is formed on the upper surface of the front head (22). An expansion space is formed by the groove (42) between the front head (22) and the discharge cover (43) by fixing the flat discharge cover (43) to the upper surface of the front head (22). It has come to be. The expansion space (42) communicates with the discharge port (29) of the compression mechanism (20) and the discharge gas outlet (46) of the discharge cover (43), as in the above-described reference techniques and embodiments .

  Even if comprised in this way, since the path | route length of expansion space (42) can be made into sufficient length, the effect of reducing especially low frequency pulsation noise can be heightened. Moreover, since the peak frequency of the acoustic attenuation amount is shifted to the low frequency side, an effect of enhancing the noise reduction effect from the low frequency to the high frequency can be obtained.

Also in this reference technique 3 , the discharge gas discharged from the compression mechanism (20) discharge port (29) is discharged from the expansion space (42) through the discharge gas outlet (46) into the casing (10). At this time, since the pressure wave is not refracted in the middle and flows smoothly on the plane along the spiral path, it is possible to obtain a sufficient effect as an expansion type silencing mechanism.

  Further, the discharge port (29) of the compression mechanism (20) and the discharge gas outlet (46) of the discharge cover (43) are formed in the middle of the spiral path in the expansion space (42). Surely occurs. Further, if the discharge gas outlet (46) is arranged at the position of the standing wave node, the discharge gas can be discharged from the discharge gas outlet (46) with the smallest amplitude.

<< Embodiment 2 of the Invention >>
In Embodiment 2 of the present invention, the expansion space (42) is formed so as to straddle the cylinder (21) and the front head (22), and the discharge cover (43) is formed in a flat plate shape.

12A is a cross-sectional view of the muffler mechanism 47, FIG. 12B is a plan view of the discharge cover 43, and FIG. 12C is a plan view of the front head 22. As shown in the figure, a first spiral groove (42a) communicating with the discharge port (29) of the compression mechanism (20) is formed on the upper surface of the front head (22). Further, a second spiral groove (42) communicating with the first spiral groove (42a) through a first communication hole (42c) formed in the front head (22) is formed on the upper surface of the cylinder (21). 42b) is formed. The second spiral groove (42b) is formed to communicate with the discharge gas outlet (46) of the discharge cover (43) through the second communication hole (42d). A first expansion space (42a) including a first spiral groove (42a) is formed between the front head (22) and the discharge cover (43), and the front head (22) and the cylinder (21 ), A second expansion space (42b) composed of the second spiral groove (42b) is formed. As described above, the first expansion space (42a) and the second expansion space (42b) communicate with each other to form the expansion space (42) of the second embodiment .

In the second embodiment , since the path length of the expansion space can be further increased as compared with the reference technique 3 , the effect of reducing low-frequency pulsation noise can be further enhanced. Further, it is the same as the reference technique 3 in that the effect of enhancing the noise reduction effect from the low frequency to the high frequency can be obtained by shifting the peak frequency of the acoustic attenuation amount to the low frequency side.

<< Other Embodiments >>
About the said embodiment, it is good also as the following structures.

  In the above-described embodiment, the rotary piston type compressor in which the piston (24) and the blade (26) are separated has been described. However, in the present invention, the piston (24) and the blade (26) are integrated. The present invention can also be applied to a swinging piston type compressor that swings with respect to the cylinder (21).

  Moreover, although the said embodiment demonstrated the compressor with which the electric motor (30) was incorporated in the casing (10), you may provide an electric motor in the exterior of a casing (10).

  Further, in each of the embodiments described above, the example in which the silencer mechanism (47) is provided on the front head (22) side has been described. However, the silencer mechanism (47) may be provided on the rear head (23) side in some cases.

  In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

  As described above, the present invention is useful for a high-pressure dome-shaped compressor in which the inside of the casing is the discharge pressure of the compressor and provided with an expansion-type silencing mechanism.

It is a longitudinal cross-sectional view of the compressor which concerns on the reference technique 1 . It is a cross-sectional view which shows the compression mechanism of the compressor of FIG. 3A is a cross-sectional view taken along the line III-III in FIG. 1, and FIG. 3B is a diagram schematically showing the positional relationship between the expansion space, the discharge port, and the discharge gas outlet. FIG. 4A is a conceptual diagram of the expansion type silencing mechanism, and FIG. 4B is a graph showing the relationship between the amount of acoustic attenuation and the frequency. FIG. 5A is a graph showing the relationship between the sound attenuation amount and the frequency of the conventional silencing mechanism, and FIG. 5B is a graph showing the relationship between the sound attenuation amount and the frequency of the silencing mechanism of Reference Technique 1 . It is sectional drawing which shows the discharge cover of the silencer mechanism which concerns on the reference technique 2 . It is a graph which shows the relationship between the amount of sound attenuation of the silencer mechanism of the reference technique 2 , and a frequency. It is sectional drawing which shows the discharge cover of the silencer mechanism which concerns on Embodiment 1. FIG. It is sectional drawing which shows the discharge cover of the silencer mechanism which concerns on the 1st modification of Embodiment 1 . It is sectional drawing which shows the discharge cover of the silencer mechanism which concerns on the 2nd modification of Embodiment 1 . Is a diagram showing a silencer mechanism according to the reference technique 3, Fig. 11 (A) is a sectional view, FIG. 11 (B) a plan view of the discharge cover, FIG. 11 (C) is a plan view of the front head of the silencing mechanism . Is a diagram showing a silencer mechanism according to the second embodiment, FIG. 12 (A) is a sectional view, and FIG. 12 (B) is a plan view of the discharge cover, FIG. 12 (C) is a plan view of the front head of the silencing mechanism .

10 Casing
14 Suction pipe
15 Discharge pipe
20 Compression mechanism
21 cylinders
22 Front head
23 Rear head
24 piston
25 Cylinder chamber
29 Discharge port
33 Drive shaft
42 Spiral groove (expansion space)
42a First spiral groove (expansion space)
42b Second spiral groove (expansion space)
43 Discharge cover
46 Discharge gas outlet
47 Silencer
48 Restricted passage
50 Path length variable mechanism

Claims (8)

A compression mechanism (20) for compressing and discharging gas; a casing (10) for housing the compression mechanism (20); a suction pipe (14) communicating with the suction side of the compression mechanism (20); 10) The discharge gas expansion space (42) covering the discharge pipe (15) provided in the casing (10) so as to open into the internal space and the discharge port (29) provided in the compression mechanism (20) And a silencer mechanism (47) having a discharge cover (43) in which a discharge gas outlet (46) from the expansion space (42) into the casing (10) is formed,
The expansion space (42) is formed along one or more spiral paths passing through the discharge port (29) and the discharge gas outlet (46) ,
A compressor comprising a variable path length mechanism (50) for changing a path length of a spirally formed expansion space (42) . In claim 1,
The compressor characterized in that the path length variable mechanism (50) is configured to change the path length of the expansion space (42) in accordance with the rotational speed of the compression mechanism (20) . In claim 1 or 2,
The compression mechanism (20) includes a drive shaft (33), a cylindrical cylinder (21), a front head (22) fixed to one end face of the cylinder (21) and through which the drive shaft (33) passes. A cylinder chamber defined by a rear head (23) fixed to the other end surface of the cylinder (21) and through which the drive shaft (33) passes, and a cylinder (21), a front head (22), and a rear head (23) (25) is connected to the drive shaft (33) and has a piston (24) that rotates eccentrically in the cylinder chamber (25),
The discharge port (29) of the compression mechanism (20) and the discharge gas outlet (46) of the discharge cover (43) communicate between one of the front head (22) and the rear head (23) and the discharge cover (43). A compressor characterized in that a spiral groove (42) is formed to form an expansion space (42) . A compression mechanism (20) for compressing and discharging gas; a casing (10) for housing the compression mechanism (20); a suction pipe (14) communicating with the suction side of the compression mechanism (20); 10) The discharge gas expansion space (42) covering the discharge pipe (15) provided in the casing (10) so as to open into the internal space and the discharge port (29) provided in the compression mechanism (20) And a silencer mechanism (47) having a discharge cover (43) in which a discharge gas outlet (46) from the expansion space (42) into the casing (10) is formed,
The expansion space (42) is formed along one or more spiral paths passing through the discharge port (29) and the discharge gas outlet (46),
The compression mechanism (20) includes a drive shaft (33), a cylindrical cylinder (21), a front head (22) fixed to one end face of the cylinder (21) and through which the drive shaft (33) passes. A cylinder chamber defined by a rear head (23) fixed to the other end surface of the cylinder (21) and through which the drive shaft (33) passes, and a cylinder (21), a front head (22), and a rear head (23) (25) is connected to the drive shaft (33) and has a piston (24) that rotates eccentrically in the cylinder chamber (25),
A first spiral groove (42a) communicating with the discharge port (29) of the compression mechanism (20) is formed between one of the front head (22) and the rear head (23) and the discharge cover (43). A second spiral groove (42b) communicating with the discharge gas outlet (46) of the discharge cover (43) is provided between one of the front head (22) and the rear head (23) and the cylinder (21). The compressor is characterized in that the first spiral groove (42a) and the second spiral groove (42b) are formed to form an expansion space (42) . In any one of Claims 1-4,
The compressor characterized in that the discharge port (29) of the compression mechanism (20) is formed at a position in the middle of the spiral path in the expansion space (42) . In any one of Claims 1 to 5,
The compressor characterized in that the discharge gas outlet (46) of the discharge cover (43) is formed at a position in the middle of the spiral path in the expansion space (42) . In any one of Claims 1-6 ,
A compressor characterized in that a discharge gas outlet (46) of the discharge gas cover is formed at a position corresponding to a node of a standing wave of pressure in the expansion space (42) . In any one of Claims 1-7,
A throttle passage (48) is provided in the middle of the spiral path in the expansion space (42), and the expansion space (42) is formed in a plurality of stages through the throttle passage (48). Compressor.

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