KR102520580B1 - Compression Low Vibration Turbo Compressor - Google Patents

Abstract

The present invention relates to a compression-type low-vibration turbo compressor. More particularly, the present invention relates to a compression-type low-vibration turbo compressor that prevent performance degradation of compression-type motors due to heat as the air flowing back to a compression motor and the air used for cooling the compression motor are discharged to the outside of a housing through a sound absorption discharge part, while reducing vibration and noise generated from the housing.

Description

Compression type low vibration turbo compressor {Compression Low Vibration Turbo Compressor}

The present invention relates to a compression-type low-vibration turbo compressor, and more particularly, as the air flowing back to the compression-type motor and the air used for cooling the compression-type motor are discharged to the outside of the housing through a sound-absorbing discharge unit, heat A compression-type low-vibration turbo compressor capable of preventing performance degradation of a compression-type motor and reducing vibration and noise generated from a housing.

A compressor is a mechanical device that receives power from a power generating device such as an electric motor or turbine and compresses air, refrigerant, or other various gases to increase the pressure. It is widely used throughout the industry.

These compressors are used alone or are built into an enclosure having the shape of a housing together with various control devices and inverters for driving and controlling, and are manufactured and used as a single compressor package.

A conventional compressor package includes a housing configured to allow air inflow, a compressor installed inside the housing to transfer discharged compressed air to the next process (operating device), and a cooling device for cooling heat generated from the compressor. and the like, and as one of the technologies for such a conventional compressor package, Patent Registration No. 10-2153696 (hereinafter referred to as 'prior art') is disclosed.

In the prior art, the internal space of the housing is divided into a motor room in which a compressor is installed and a refrigerant inlet room into which outside air flows, and as the air introduced through the refrigerant inlet room passes through the motor room and is discharged to the outside of the housing, heat generated in the compressor is cooling

However, in the prior art, since the compressor is cooled using heat exchange between the compressor case and the motor room, there is a problem in that the cooling efficiency is lowered.

In addition, in the prior art, there is a problem in that a lot of noise and vibration are generated from a blower fan used to supply refrigerant to the refrigerant inlet chamber and discharged to the outside, and a power device used to operate the refrigerant.

Registered Patent Publication No. 10-2153696 (2020.09.02. registration)

The present invention was created to solve the problems of the prior art, and the problem to be solved in the present invention is that the air flowing back to the compression type motor and the air used for cooling the compression type motor are removed from the outside of the housing through the sound absorption discharge unit. As configured to be discharged, it is to provide a compression-type low-vibration turbo compressor that can prevent performance degradation of the compression-type motor due to heat and reduce vibration and noise generated from the housing.

The present invention includes a housing 100 configured to enable installation of various parts and devices therein; A filtering unit 200 provided on the rear side of the housing 100 to filter fluid flowing into the housing 100; a compression type motor 300 provided inside the housing 100 to compress the fluid introduced into the housing 100 through the filtration unit 200 and deliver the fluid to an operating device; and a sound absorbing and discharging unit 400 disposed inside the housing 100 to discharge air flowing back to the compression type motor 300 and air used for cooling the compression type motor 300 to the outside. and a control unit 500 configured to control the operation of the compression motor 300.

At this time, the filtering unit 200 includes a filter frame 210 provided on an open front side of the housing 100 in which a plurality of filter attachment grooves are arranged in rows and columns; and filter members 220 respectively provided in the filter attachment grooves.

On the other hand, the compression type motor 300 is composed of a motor including a rotor 314 and a stator 315, and operation shafts 316 are provided at both ends of the rotor 314 in the front and rear directions, respectively, and the operation shaft ( 316) is provided in parallel with the front and rear directions of the motor unit 310; a first compression unit 320 provided in front of the motor unit 310 to intake air and primarily compress the air; One end is connected to the outlet of the first compressed air flow path 323, and the other end is connected to the second compression inlet 341a of the second compression unit 340 to supply the primarily compressed air to the second compression unit 340. Connecting pipe 330 to deliver; and a second compression unit 340 that secondarily compresses the air delivered from the first compression unit 320 and delivers it to an operating device.

At this time, the motor unit 310, one or more cooling holes 311 through which the outside and the inside communicate; a blowing fan 312 provided inside the compression motor 300 and introducing air into the inside by the operation of the rotor 314; and a heat dissipation hole 313 through which the air introduced by the blowing fan 312 is discharged to the outside.

On the other hand, the sound absorption and discharge unit 400 allows compressed air flowing back to the compressed air pipe 350 connecting the second compression unit 340 of the compression type motor 300 and the operating device to the outside of the housing 100. A discharge device 410 for backflow air to be discharged to; and a cooling air discharge device 420 for receiving the air used for cooling discharged from the heat dissipation hole 313 of the compression type motor 300 and discharging it to the outside of the housing 100 .

At this time, the backflow air discharge device 410 has one end in communication with the compressed air pipe 350 and the other end in communication with the backflow silencer box 413 to supply backflow compressed air to the backflow noise box for backflow air. piping 411 for backflow air passing to 413; It is provided on the backflow air pipe 411 and when the inflow of compressed air is blocked to the operating device connected to the compressor, the air of the compressed air pipe 350 flows into the backflow air pipe 411 while being opened a blow-off valve 412; and a noise box 413 for backflow air that is provided inside the housing 100 and receives the compressed air flowing into the backflow air pipe 411 and discharges it to the outside.

In addition, the backflow air noise box 413 includes a backflow air case 413a having an empty interior; a perforated plate 413b for backflow air provided at a predetermined distance from the inside so as to form a predetermined space between the inner surface of the case 413a for backflow air; and a sound absorbing material 413c for a backflow machine provided between the case 413a for backflow air and the perforated plate 413b for backflow air.

Meanwhile, the control unit 500 compares the measured pressure of compressed air measured by a pressure gauge (not shown) provided in the compressed air pipe 350 with the reference pressure to determine opening and closing of the blow-off valve 412. can

On the other hand, the cooling air exhaust device 420 has one end connected to collect air used for cooling discharged from the heat dissipation hole 313 of the compression type motor 300, and the other end cools the collected used air. A cooling air collection unit 421 passing to the air pipe 422; a cooling air pipe 422 having one end connected to the cooling air collector 421 and the other end connected to the cooling air noise box 423; and a silencer box 423 for cooling air provided inside the housing 100 to receive air introduced through the pipe 422 for cooling air and discharge it to the outside of the housing 100 .

On the other hand, the cooling air silencer box 423 includes a cooling air case 423a having an empty interior; a perforated plate 423b for cooling air provided at a predetermined distance to form a predetermined space between the inner surface of the case 423a for cooling air; and a sound absorbing material 423c for cooling air provided between the case 423a for cooling air and the perforated plate 423b for cooling air.

According to the present invention, since the air flowing back to the compression motor and the air used for cooling the compression motor are discharged to the outside of the housing through the sound absorbing discharge unit, the effect of preventing performance deterioration of the compression motor due to heat is achieved. there is.

Further, according to the present invention, since the sound absorbing material is provided in the sound absorbing discharge unit and the sound absorbing material is provided on the inner surface of the housing, vibration and noise generated in the housing can be reduced.

1 is a perspective view of an embodiment of a compression-type low-vibration turbo compressor according to the present invention, showing a state in which one side is opened.
Figure 2a is an exploded perspective view of the filtration unit applied to the present invention.
3a to 3b are perspective views of one side and the other side of a compression type motor applied to the present invention;
Figure 3c is a plan view of the compression type motor applied to the present invention.
Figure 3d is a cross-sectional view A-A' of Figure 3c.
Figure 4 is a side view of one side of Figure 1, a view showing the installed state of the compression type motor.
Figure 5a is a perspective view showing a compression type motor and a sound absorption discharge unit applied to the present invention.
Figure 5b is a front view of a compression type motor and a sound absorption discharge unit applied to the present invention.
Figure 5c is a plan view of a compression type motor and a sound absorption discharge unit applied to the present invention.
6a and 6b are partially exploded perspective views of the compressor according to the present invention.

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

The present invention relates to a compression-type low-vibration turbo compressor, and more particularly, air flowing back to the compression-type motor 300 and air used for cooling the compression-type motor 300 are sound-absorbing provided inside a housing 100 It is configured to be discharged to the outside of the housing 100 through the discharge unit 400, and as a sound absorbing material is provided on the sidewall of the housing 100, compression type low vibration that can reduce vibration and noise generated in the housing 100 It's about the turbo compressor.

The present invention is characterized in that it includes a housing 100, a filtering unit 200, a compression type motor 300, a sound absorption and discharge unit 400 and a control unit 500.

As shown in FIG. 1, the housing 100 is configured to enable installation of various parts and devices therein.

In detail, the housing 100 is configured in the form of an enclosure so that the compression motor 300 and various devices can be formed as a single package, and the rear side of the housing 100 is formed in an open form, through which the housing Outside air of (100) may be introduced into the inside.

In addition, both sides of the housing 100 facing each other are configured to be openable, and if necessary, the side surfaces can be opened to inspect and repair various parts and devices installed inside the housing 100.

Meanwhile, as shown in FIG. 2 , the filtering unit 200 is provided on the rear side of the housing 100 to filter fluid flowing into the housing 100 .

On the other hand, the filtering part 200 is configured in a replaceable form and is detachably provided. For example, the filtering part 200 is arranged so that a plurality of filter attachment and detachment grooves are arranged in rows and columns, so that the housing 100 It includes a filter frame 210 provided on the open front side and a filter member 220 provided in each of the filter attachment grooves.

At this time, the filter member 220 may be composed of a medium filter.

In addition, a filter cover 230 may be further provided on the outside of the filtering unit 200 to protect the filtering unit 200, and the filter cover 230 allows outside air to pass through the filtering unit 200 so as to protect the housing. It is configured to be able to flow into the interior of (100).

According to the above configuration, the filtering unit 200 allows the outside air of the housing 100 to pass through the filter member 220 and flow into the inside in a filtered state.

On the other hand, the compression motor 300 is provided inside the housing 100 and compresses the fluid introduced into the housing 100 through the filtering unit 200 and delivers it to the operating device.

At this time, as shown in FIGS. 3A to 3D, the compression type motor 300 is configured to double compress air. To this end, the motor unit 310, the first compression unit 320, and the connection pipe ( 330) and a second compression unit 340.

In other words, as shown in FIG. 3D, the motor unit 310 is made of a general motor including a rotor 314 and a stator 315, which has motion shafts 316 at both ends of the rotor 314 in the front and rear directions, respectively. It is provided, but the operation shaft 316 is provided parallel to the front and rear directions.

Meanwhile, as shown in FIGS. 3A to 3C , the first compression unit 320 is provided in front of the motor unit 310 to take in air and primarily compress the air.

To this end, the first compression unit 320 includes a first casing body 321 provided in front of the motor unit 310 with a first compression inlet 321a through which outside air flows into the front center, The first impeller 322 provided in the inner center of the first casing body 321, the rear side of which is connected to the front side operating shaft 316 of the motor unit 310 and the first casing body 321 It extends along the outer circumference and includes a first compressed air passage 323 at one end communicating with the first casing body 321 to receive compressed air.

That is, the first compression unit 320 is configured to compress air while the first impeller 322 rotates according to the operation of the motor unit 310, and the compressed air flows through the first compressed air passage 323. along the flow to the next process.

At this time, the inlet of the first compressed air passage 323 is located on the upper end side of the first casing body 321, and the outlet of the first compressed air passage 323 faces downward.

Meanwhile, the connection pipe 330 has one end connected to the outlet of the first compressed air passage 323 and the other end connected to the second compression inlet 341a of the second compression unit 340 for primary compression. The compressed air is delivered to the second compression unit 340.

At this time, the connection pipe 330 passes through the lower end of the motor unit 310 and extends backward to be connected to the second compression unit 340 .

Meanwhile, the second compression unit 340 secondarily compresses the air received from the first compression unit 320 and delivers it to the operating device.

To this end, the second compression unit 340 has a second compression inlet 341a connected to the other end of the connection pipe 330 at the rear center thereof, and is provided at the rear of the motor unit 310. The casing body 341, the second impeller 342 provided in the inner center of the second casing body 341, the front side being connected to the rear side operating shaft 316 of the motor unit 310, and the second impeller 342 2. A second compressed air passage 343 extending along the outer circumference of the casing body 341, one end communicating with the second casing body 341 and the other end connected to the operating device side to deliver compressed air to the operating device. ).

At this time, the inlet of the second compressed air passage 343 is located at the lower end of the second casing body 341, and the outlet of the second compressed air passage 343 faces upward.

According to the configuration described above, the second compression unit 340 receives primarily compressed air through the connection pipe 330, and the received compressed air is transferred to the second impeller according to the operation of the motor unit 310. Secondarily compressed by the rotation of 342, the compressed air is finally supplied to the operating device along the second compressed air passage 343.

At this time, the final outlet 110 is formed in the upper part of the housing 100, and the other end of the second compressed air passage 343 and the final outlet 110 are airtightly connected by a compressed air pipe 350, Double compressed air can be supplied to the operating device through this.

On the other hand, the motor unit 310 has one or more cooling holes 311 that communicate with the outside and the inside, and is provided inside the compression type motor 300 to introduce air into the inside by the operation of the rotor 314. A blowing fan 312 and a heat dissipation hole 313 through which the air introduced by the blowing fan 312 is discharged to the outside are further included.

At this time, one or more cooling holes 311 are provided, but they are provided to be biased toward the first compression unit 320, and the blowing fan 312 is provided along the operating shaft 316 of the second compression unit 340. As one or more heat dissipation holes 313 are provided to be biased toward the second compression unit 340, the air introduced into the compression type motor 300 is circulated from the front to the rear. can be fluid.

On the other hand, the housing 100 is further provided with a cooling air discharge port 120 communicating with the heat radiation hole 313 and discharging air used for cooling to the outside of the housing 100. The heat radiation hole 313 The cooling air outlet 120 is airtightly connected by a cooling air pipe 422 so that air used for cooling is discharged to the outside of the housing 100 .

On the other hand, the compression type motor 300 configured as described above is installed in a floating state in the air without contacting the bottom surface inside the housing 100 .

In detail, the inside of the housing 100 is configured to have a predetermined area in a horizontal direction, and an installation plate 140 is provided while crossing the inside of the housing 100 in a horizontal direction, and the compression type motor 300 is installed such that the motor unit 310 is located on top of the installation plate 140 to support the load.

At this time, the connection pipe 330 is disposed in the lower space of the installation plate 140, which is provided in a floating state, so that the connection pipe 330 may drop downward due to its own load.

Therefore, the above phenomenon can be prevented in advance by further providing an auxiliary plate 141 supporting the load of the connection pipe 330 at the lower end of the connection pipe 330 .

On the other hand, as shown in FIG. 4 , the sound absorption and discharge unit 400 is provided inside the housing 100 and is used for cooling air flowing back to the compression motor 300 and the compression motor 300. To discharge the air to the outside, for this purpose, a countercurrent air exhaust device 410 and a cooling air exhaust device 420 are included.

At this time, referring to FIGS. 5A to 5C, the backflow air discharge device 410 is configured to discharge the compressed air that flows back to the compressed air pipe 350 to the outside of the housing 100. To this end, the backflow air It is configured to include a pipe 411, a blow-off valve 412, and a silencer box 413 for backflow air.

In other words, the backflow air pipe 411 has one end communicated with the compressed air pipe 350 and the other end communicated with the reverse air silencer box 413 to transfer compressed air flowing backward to the silencer box.

On the other hand, the blow off valve 412 is provided on the backflow air pipe 411, and when the inflow of compressed air to the device connected to the compressor is blocked, the valve opens and the compressed air pipe The air of 350 is introduced into the pipe 411 for backflow air.

At this time, the opening and closing of the blow-off valve 412 is determined by the controller 500, and the controller 500 measures the amount of compressed air measured by a pressure gauge (not shown) provided in the compressed air pipe 350. Opening and closing of the blow-off valve 412 may be determined by comparing the measured pressure with the reference pressure.

In detail, when the measured pressure exceeds the reference pressure, the control unit 500 determines that the operation is normal, closes the blow-off valve 412 so that compressed air flows into the operating device, and when the measured pressure is less than the reference pressure. , the blow-off valve 412 is opened so that the compressed air flows into the backflow air pipe 411 by determining that the operation is abnormal.

In addition, the control unit 500 may determine whether to open or close the blow-off valve 412 according to the operating state of the operating device, and a manager may appropriately set this according to the operating device.

Meanwhile, the noise box 413 for backflow air is provided inside the housing 100, and can receive compressed air flowing into the backflow air pipe 411 and discharge it to the outside.

In detail, the backflow noise box 413 has an inner side so that a predetermined space is formed between the backflow air case 413a having an empty interior and the inner surface of the backflow air case 413a. and a perforated plate 413b for backflow air provided at a predetermined distance apart from each other and a sound absorbing material 413c for backflow air provided between the case 413a for backflow air and the perforated plate 413b for backflow air.

At this time, a backflow air outlet 130 is formed in the housing 100, and the backflow air silencer 413 is airtightly connected to the backflow air silencer 413 by a pipe so that the backflow air can be discharged.

On the other hand, the cooling air discharge device 420 is for discharging the cooling air used for cooling the compression type motor 300 to the outside of the housing 100, and is used for cooling discharged from the heat dissipation hole 313. Used air is received and discharged to the outside of the housing 100, and for this purpose, a cooling air collector 421, a cooling air pipe 422, and a cooling air noise box 423 are included.

The cooling air collector 421 has one end connected to collect air used for cooling discharged from the heat dissipation hole 313, and the other end configured to transfer the collected air to the cooling air pipe 422. .

Meanwhile, the cooling air pipe 422 has one end connected to the cooling air collector 421 and the other end connected to the cooling air noise box 423 .

Meanwhile, the cooling air noise box 423 is provided inside the housing 100 to receive air introduced through the cooling air pipe 422 and discharge it to the outside.

In detail, the cooling air silencer box 423 has an inner side so that a predetermined space is formed between the cooling air case 423a configured in an empty state and the inner surface of the cooling air case 423a. and a perforated plate 423b for cooling air provided at a predetermined distance apart from each other and a sound absorbing material 423c for cooling air provided between the case 423a for cooling air and the perforated plate 423b for cooling air.

At this time, a cooling air outlet 120 is formed in the housing 100, and the silencer box for cooling air is airtightly connected thereto by a pipe so that the air used for cooling can be discharged to the outside.

Meanwhile, the sound absorbing material 413c for backflow air and the sound absorbing material 423c for cooling air are made of a fabric material, which may be firmly fixed by a fixing member such as a bolt or screw.

Meanwhile, the controller 500 is configured to control the operation of the compression motor 300 .

At this time, the controller 500 may include a control room 510 configured in front of the housing 100 and a control device (not shown) provided inside the control room 510 to control the operation of the compressor device. there is.

In addition, the control device may include all of various devices and parts for controlling the operation of the compressor, such as a controller, a circuit breaker, and an inverter.

Meanwhile, a door for repair and inspection of the control device may be opened and closed on a side surface of the control room 510, and a display device may be further provided to display the operating state of the device as visual information.

In addition, an inverter outlet 520 for discharging cooling air of the inverter to the outside may be further provided at the top of the control room 510 .

Meanwhile, as shown in FIGS. 6A and 6B, a first sound absorption material 150 is provided between the controller 500 and the housing 100, and between the housing 100 and the filtering unit 200. A second sound absorbing material 160 is provided to absorb noise generated from the housing 100 .

In detail, the first sound absorbing material 150 is made of a fabric material and is fixed between the control unit 500 and the housing 100, and the second sound absorbing material 160 is between the housing 100 and the filtering unit 200. is fixed to

At this time, as the first sound absorbing material 150 and the second sound absorbing material 160 are fixed in a pressurized state by the fixing net 170 made of a lattice form, the phenomenon of being separated from the installed position is prevented.

Although the preferred embodiments of the present invention have been described above, the scope of the present invention is not limited thereto, and it should be understood that the scope of the present invention extends to those within the scope substantially equivalent to the embodiments of the present invention. Various modifications and implementations are possible by those skilled in the art to which the invention pertains without departing from the spirit of the invention.

100: housing 110: final outlet
120: cooling air outlet 130: countercurrent air outlet
140: installation plate 141: auxiliary plate
150: first sound absorbing material 160: second sound absorbing material
200: filtering unit 210: filter frame
220: filter member
300: compression motor
310: motor unit 311: cooling hole
312: blowing fan 313: heat dissipation hole
314: rotor 315: stator
316: motion axis
320: first compression unit 321: first casing body
322: first impeller 323: first compressed air flow path
330: connection pipe
340: second compression unit 341: second casing body
342: second impeller 343: second compressed air flow path
350: piping for compressed air
400: sound absorption and discharge unit
410: discharge device for countercurrent air 411: piping for countercurrent air
412: blow-off valve 413: noise box for backflow air
413a: Case for countercurrent air 413b: Perforated plate for countercurrent air
413c: Sound absorbing material for backflow air
420: cooling air discharge device 421: cooling air collection unit
422: piping for cooling air 423: noise box for cooling air
423a: case for cooling air 423b: perforated plate for cooling air
423c: sound absorbing material for cooling air
500: control unit 510: control room
520: outlet for inverter

Claims (10)

A housing 100 configured to enable installation of various parts and devices therein;
A filtering unit 200 provided on the rear side of the housing 100 to filter fluid flowing into the housing 100;
a compression type motor 300 provided inside the housing 100 to compress the fluid introduced into the housing 100 through the filtration unit 200 and deliver the fluid to an operating device;
a sound absorbing/discharging unit 400 provided inside the housing 100 to discharge the air flowing back to the compression motor 300 and the air used for cooling the compression motor 300 to the outside; and
a controller 500 configured to control the operation of the compression motor 300;
Including,
The filtering unit 200,
a filter frame 210 provided on an open front side of the housing 100 in which a plurality of filter attachment grooves are arranged in rows and columns; and
Filter members 220 provided in each of the filter attachment grooves;
Including,
The compression motor 300,
It is composed of a motor including a rotor 314 and a stator 315, and operation shafts 316 are provided at both ends of the rotor 314 in the forward and backward directions, respectively, and a motor in which the operation shaft 316 is provided parallel to the front and rear directions section 310;
a first compression unit 320 provided in front of the motor unit 310 to intake air and primarily compress the air;
One end is connected to the outlet of the first compression unit 320 and the other end is connected to the second compression inlet 341a of the second compression unit 340 to supply the primarily compressed air to the second compression unit 340. Connecting pipe 330 for transmission; and
a second compression unit 340 that secondarily compresses the air received from the first compression unit 320 and delivers it to an operating device;
Including,
The motor unit 310,
one or more cooling holes 311 through which the outside and the inside communicate;
a blowing fan 312 provided inside the compression motor 300 and introducing air into the inside by the operation of the rotor 314; and
a heat dissipation hole 313 through which the air introduced by the blowing fan 312 is discharged to the outside;
Including,
The sound absorption and discharge unit 400,
A backflow air discharge device (410) for discharging compressed air flowing backward through the compressed air pipe (350) connecting the second compression unit (340) of the compression type motor (300) and the operating device to the outside of the housing (100). ); and
a cooling air discharge device 420 for receiving the air used for cooling discharged from the heat dissipation hole 313 of the compression type motor 300 and discharging it to the outside of the housing 100;
Including,
The discharge device 410 for countercurrent air,
One end communicates with the compressed air pipe 350 and the other end communicates with the reverse air silencer box 413 to transfer compressed air flowing backward to the reverse air silencer box 413 (411) ;
It is provided on the backflow air pipe 411 and when the inflow of compressed air is blocked to the operating device connected to the compressor, the air of the compressed air pipe 350 flows into the backflow air pipe 411 while being opened a blow-off valve 412; and
a noise box 413 for backflow air provided inside the housing 100 and receiving compressed air flowing into the backflow air pipe 411 and discharging it to the outside;
Including,
The cooling air discharge device 420,
A cooling air collector having one end connected to collect the air used for cooling discharged from the heat dissipation hole 313 of the compression type motor 300 and the other end passing the collected air to the cooling air piping 422. (421);
a cooling air pipe 422 having one end connected to the cooling air collector 421 and the other end connected to the cooling air noise box 423; and
a silencer box 423 for cooling air provided inside the housing 100 to receive air introduced through the cooling air pipe 422 and discharge it to the outside of the housing 100;
Including,
The housing 100 is provided with an installation plate 140 while crossing the inside in a horizontal direction,
In the compression type motor 300, the motor unit 310 is located above the installation plate 140, and the connection pipe 330 is installed in a lower space of the installation plate 140,
An auxiliary plate 141 for supporting the load of the connection pipe 330 is further provided at the lower end of the connection pipe 330,
A first sound absorbing material 150 is provided between the control unit 500 and the housing 100, and a second sound absorbing material 160 is provided between the housing 100 and the filtering unit 200. Compression type low vibration turbo compressor.
delete delete delete delete delete The method of claim 1,
The noise box 413 for backflow air,
a case 413a for backflow air configured to be empty inside;
a perforated plate 413b for backflow air provided at a predetermined distance from the inside so as to form a predetermined space between the inner surface of the case 413a for backflow air; and
a sound absorbing material 413c for backflow air provided between the case 413a for backflow air and the perforated plate 413b for backflow air;
Compression-type low-vibration turbo compressor comprising a.
The method of claim 1,
The controller 500,
Compression-type low-vibration turbo, characterized in that the opening and closing of the blow-off valve 412 is determined by comparing the measured pressure of compressed air and the reference pressure measured by a pressure gauge (not shown) provided in the compressed air pipe 350 compressor.
delete The method of claim 1,
The noise box 423 for cooling air,
a cooling air case 423a having an empty interior;
a perforated plate 423b for cooling air provided at a predetermined distance to form a predetermined space between the inner surface of the case 423a for cooling air; and
a sound absorbing material for cooling air (423c) provided between the case for cooling air (423a) and the perforated plate for cooling air (423b);
Compression-type low-vibration turbo compressor comprising a.

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