KR101964226B1 - A compressing system - Google Patents

Abstract

According to an aspect of the present invention, there is provided an air conditioner, comprising: a casing having an inlet on one side and an outlet on the other side; and at least one axial compressor or an intermittent compressor disposed in the casing and adapted to receive and compress fluid from the inlet A first pressure chamber disposed in the casing and communicating with an outlet of the first compression section; at least one first pressure chamber disposed in the first pressure chamber and cooling the fluid in the first pressure chamber; A second compression section disposed in the casing and communicating with the outlet of the first pressure chamber to receive and compress the fluid from the first pressure chamber; and a second compression section disposed in the casing, At least one second intercooler portion disposed in the second pressure chamber and cooling the fluid in the second pressure chamber, And a third compression section communicating with the outlet of the second pressure chamber for receiving the fluid from the second pressure chamber and for conveying the compressed fluid to the discharge port.

Description

A compressing system

The present invention relates to a compression system.

BACKGROUND ART Compressors for compressing fluids such as air, gas and steam are used in various fields, and there are various kinds of compressors.

Generally, compressors can be classified into a volume type and a turbo type. Specifically, the compressor can be classified into a reciprocating compressor, a rotary screw compressor, a turbo compressor, a diaphragm compressor, and a rotary sliding vane compressor.

Such a compressor can be used alone, but a plurality of compressors may be arranged according to the needs of a designer to form a multi-stage system, and a larger compression ratio can be realized when a multi-stage system is configured.

On the other hand, when using a plurality of compressors, there is a case where a cooler is disposed between compressors in order to improve the overall system efficiency. However, in Japanese Patent Laid-Open Publication No. 2010-0107875, a cooler is installed between compressors, A multi-stage compressor device is disclosed in which a cooling system is not required.

According to one aspect of the present invention, it is a principal object of the present invention to provide a compression system capable of compressing a large amount of fluid and having a high compression efficiency.

According to an aspect of the present invention, there is provided a compressor comprising: a casing having an inlet on one side and a discharge port on the other side; at least one axial compressor or a twin compressor disposed in the casing for compressing and receiving fluid from the inlet; A first pressure chamber disposed in the casing and communicating with an outlet of the first compression section; a second pressure chamber disposed in the first pressure chamber and cooling at least the fluid in the first pressure chamber; A second compression unit disposed in the casing and communicating with the outlet of the first pressure chamber to receive and compress fluid from the first pressure chamber, A second pressure chamber communicating with an outlet of the second compression unit; at least one second intercooler unit disposed in the second pressure chamber and cooling the fluid in the second pressure chamber; And a third compression section communicating with the outlet of the second pressure chamber for receiving the fluid from the second pressure chamber and for conveying the compressed fluid to the discharge port.

Here, the casing may include an upper casing unit and a lower casing unit assembled at a lower portion of the upper casing unit.

Here, when the first compression unit includes an axial compressor, the axial compressor may have a variable vane.

Here, the second compression unit may include at least one twin type compressor or a centrifugal type compressor.

Here, the third compression unit may include at least one centrifugal compressor.

Here, the first compression unit, the second compression unit, and the third compression unit may be driven by a single rotary shaft.

Here, an additional intercooler may be installed outside the casing.

The compression system according to one aspect of the present invention has the effect of compressing a large amount of fluid with high efficiency.

1 is a schematic outline perspective view of a compression system according to an embodiment of the present invention.
FIG. 2 is a perspective view schematically illustrating an internal structure of a compression system according to an embodiment of the present invention, with an upper casing portion and a front intercooler portion removed. FIG.
FIG. 3 is a schematic view showing a cut line III-III of the compression system shown in FIG. 1. FIG.
Fig. 4 is a schematic view showing a cut line IV-IV of the compression system shown in Fig. 1. Fig.
5 is a schematic view showing a configuration of a compression system according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. In the present specification and drawings, the same reference numerals are used for constituent elements having substantially the same configuration, and redundant description is omitted.

FIG. 1 is a schematic outline perspective view of a compression system according to an embodiment of the present invention. FIG. 2 is a cross-sectional view of a compression system according to an embodiment of the present invention. And FIG. FIG. 3 is a schematic view showing a section III-III of the compression system shown in FIG. 1, and FIG. 4 is a schematic view showing a section IV-IV of the compression system shown in FIG. 5 is a schematic view showing a configuration of a compression system according to an embodiment of the present invention.

1 to 5, the compression system 100 includes a casing 110, a first compression unit 120, a first pressure chamber 130, a first intercooler unit 140, a second compression unit 140, A second compression chamber 160, a second intercooler unit 170, a third compression unit 180, a rotary shaft 190, a drive motor 195, and a control unit 197.

The casing 110 includes an upper casing part 111 and a lower casing part 112. The upper casing part 111 and the lower casing part 112 are assembled and installed at the time of installation.

The outer shape of the casing 110 is generally a hexahedron shape and includes a first compression unit 120, a first pressure chamber 130, a first intercooler unit 140, a second compression unit 150, A second pressure chamber 160, a second intercooler unit 170, a third compression unit 180, and the like are disposed.

The casing 110 according to the present embodiment has a hexahedral shape as a whole, but the present invention is not limited thereto. That is, the shape of the casing according to the present invention is not particularly limited.

One side of the casing 110 has an inlet 113 through which a fluid flows and a discharge port 114 through which fluid is discharged from the other side.

Oil is disposed in the lower casing portion 112 as shown in FIG. 4 to assist lubricating operation of the compression system 100.

The first compression unit 120 performs a function of receiving and compressing the fluid from the inlet 113. To this end, the first compression unit 120 includes two-stage axial-flow type compressors 121.

The axial-flow type compressor 121 includes a first rotating body 121a, a second rotating body 121b, and a stator 121c.

The first rotating body 121a includes a first hub 121a_1 and a first blade 121a_2 mounted on the first hub 121a_1 and a second rotating body 121b includes a second hub 121b_1 and a second hub 121b_1, And a second blade 121b_2 mounted on the second hub 121b_1.

The first hub 121a_1 and the second hub 121b_1 are fixed to the rotary shaft 190. When the rotary shaft 190 rotates, the first rotary body 121a and the second rotary body 121b rotate together.

The stator 121c has a cylindrical tube shape, and a variable vane 121c_1 and a fixed vane 121c_2 are provided on the inner surface thereof to guide the fluid. In particular, the variable vane 121c_1 also controls the flow rate by controlling the motion by the controller 197. [

The inlet 120a of the first compression unit 120 is configured to communicate with the inlet 113 and is configured to receive the fluid from the inlet 113. [ Meanwhile, the outlet 120b of the first compression unit 120 is configured to communicate with the first pressure chamber 130.

According to the present embodiment, the first compression section 120 includes the two-stage axial-flow type compressor 121, but the present invention is not limited thereto. That is, the first compression unit according to the present invention may use an axial compressor, a axial compressor, an intermittent compressor, or the like having three or more stages.

According to the present embodiment, the first compression unit 120 includes one axial-flow compressor 121, but the present invention is not limited thereto. That is, the first compression unit 120 according to the present invention may include a plurality of compressors.

In the meantime, according to the present embodiment, an axial compressor or a twin compressor is used as the first compressor 120 because the compressor of the axial flow type and the compressor of the twin type can smoothly compress the high- This is because the efficiency is higher than that of the centrifugal type when compressing a large amount of fluid.

The first pressure chamber 130 communicating with the outlet 120b of the first compression unit 120 is disposed in the casing 110. [

The first pressure chamber 130 is formed as a hollow space of a rectangular parallelepiped, and is a place where the fluid of the first pressure passes. Here, the first pressure is a pressure of the fluid compressed by the first compression unit 120, and is determined according to the performance of the first compression unit 120.

The first pressure chamber 130 has an inlet 130a and an outlet 130b.

The inlet 130a of the first pressure chamber 130 communicates with the outlet 120b of the first compression unit 120 and the outlet 130b of the first pressure chamber 130 communicates with the outlet 120b of the second compression unit 150. [ And is configured to communicate with the inlet 150a.

The first intercooler 140 is disposed to face the first pressure chamber 130 in a pair, and functions to cool the fluid in the first pressure chamber 130.

The first intercooler units 140 of this embodiment are arranged in pairs, but the present invention is not limited thereto. That is, the first intercooler unit according to the present invention may be arranged in a single number, or may be arranged in three or more numbers.

The first intercooler portion 140 has a rectangular parallelepiped shape, and the internal structure of the first intercooler portion 140 may have a known intercooler configuration. In other words, it has a heat exchanger and functions to lower the temperature of the fluid.

Meanwhile, the second compression unit 150 performs a function of receiving and compressing the fluid from the first pressure chamber 130. To this end, the second compression unit 150 includes an intermittent compressor 151. In other words, the inlet 150a of the second compression unit 150 is configured to communicate with the outlet 130b of the first pressure chamber 130 to receive the fluid from the outlet 130b of the first pressure chamber 130 . The outlet (150b) of the second compression unit (150) is configured to communicate with the second pressure chamber (160).

On the other hand, the twin-stage compressor 151 includes the impeller 151a and the case 151b, and the configuration of a known twin-stage compressor can be applied as it is.

The impeller 151a includes a hub 151a_1 and a blade 151a_2 disposed on the hub 151a_1. The hub 151a_1 is fixed to the rotary shaft 190. When the rotary shaft 190 rotates, the impeller 151a_1, .

According to the present embodiment, the second compression unit 150 includes the twin-stage compressor 151, but the present invention is not limited thereto. That is, a centrifugal compressor may be used as the second compressor according to the present invention.

Also, according to the present embodiment, the second compression unit 150 includes one twin-stage compressor 151, but the present invention is not limited thereto. That is, the second compression unit 150 according to the present invention may include a plurality of compressors.

A second pressure chamber 160 communicating with the outlet 150b of the second compression unit 150 is disposed in the casing 110. [

The second pressure chamber 160 is formed as a hollow space of a rectangular parallelepiped, and is a passage through which the fluid of the second pressure passes. Here, the second pressure is a pressure of the fluid compressed by the second compression unit 150, which is determined according to the magnitude of the first pressure and the performance of the second compression unit 150.

The second pressure chamber 160 has an inlet 160a and an outlet 160b.

The inlet 160a of the second pressure chamber 160 communicates with the outlet 150b of the second compression unit 150 and the outlet 160b of the second pressure chamber 160 communicates with the outlet 150b of the third compression unit 180 And is configured to communicate with the inlet 180a.

 The second intercooler unit 170 is arranged to face the second pressure chamber 160 in a pair and functions to cool the fluid in the second pressure chamber 160.

The second intercooler units 170 of this embodiment are arranged in pairs, but the present invention is not limited thereto. That is, the second intercooler unit according to the present invention may be arranged in a single number, or may be arranged in three or more numbers.

The shape of the second intercooler portion 170 has a rectangular parallelepiped shape, and the internal structure of the second intercooler portion 170 can have a known intercooler configuration. In other words, it has a heat exchanger and functions to lower the temperature of the fluid.

Meanwhile, the third compression unit 180 functions to compress the fluid from the second pressure chamber 160 to the third pressure. Here, the third pressure is a pressure of the fluid compressed by the third compression unit 180, which is determined according to the magnitude of the second pressure and the performance of the third compression unit 180.

The third compression unit 180 includes a centrifugal compressor 181. In other words, the inlet 180a of the third compression unit 180 is configured to communicate with the outlet 160b of the second pressure chamber 160 to receive the fluid from the outlet 160b of the second pressure chamber 160 . On the other hand, the outlet 180b of the third compression unit 180 is configured to communicate with the discharge port 114. [

The centrifugal compressor 181 includes an impeller 181a, a diffuser 181b, and a scroll case 181c. The configuration of a well-known centrifugal compressor can be applied as it is.

The impeller 181a includes a hub 181a_1 and a blade 181a_2 disposed on the hub 181a_1. The hub 181a_1 is fixed to the rotary shaft 190 so that the impeller 181a is rotated when the rotary shaft 190 rotates. Rotate together.

According to the present embodiment, the third compression unit 180 includes one centrifugal compressor 181, but the present invention is not limited thereto. That is, the third compression unit 180 according to the present invention may include a plurality of compressors.

Meanwhile, the rotary shaft 190 is installed to cross the compression system 100, and the rotary shaft 190 is configured to be connected to the shaft of the drive motor 195.

Although the rotary shaft 190 is directly connected to the shaft of the driving motor 195 in the present embodiment, the present invention is not limited thereto. That is, a separate power transmission device such as a gear device or a belt device may be interposed between the rotary shaft 190 and the drive motor 195 according to the present invention. In addition, the rotary shaft 190 may be installed to rotate by receiving power from another drive shaft (not shown) connected to a turbine shaft (not shown) or the like.

The rotary shaft 190 is supported by a bearing 191 on the casing 110. As the bearing 191, a general rolling bearing, a journal bearing, an air foil bearing, and the like can be used.

The drive motor 195 produces power for rotating the rotary shaft 190 and the control device 197 performs a function of controlling the drive motor 195 and the variable vane 121c_1 according to a user's instruction or a drive program .

The first pressure chamber 130, the first intercooler unit 140, the second compression unit 150, the second pressure chamber 130, The first compression unit 160, the second intercooler unit 170 and the third compression unit 180 are disposed in the casing 110. Therefore, the three compression units 120, 150 and 180 and the two pressure chambers 130 ) 160, and two intercooler units 140 and 170, but the present invention is not limited thereto. That is, the compression system according to the present invention can be configured by further adding a compression unit, a pressure chamber, and an intercooler unit in the casing 110 in addition to the above-described configurations. For example, the compression system may include four compression units, three pressure chambers, and three intercooler units.

According to the present embodiment, the first intercooler unit 140 and the second intercooler unit 170 are disposed in the casing 110, but the present invention is not limited thereto. That is, the compression system according to the present invention may further include an additional intercooler, and the additional intercooler may be installed not only inside the casing 110 but also outside the casing 110. When the additional intercooler portion is additionally installed outside the casing 110, the intercooler portion and the pressure chamber are connected to each other by using the piping.

Next, operation of the compression system 100 according to an embodiment of the present invention will be described.

When the user activates the compression system 100, the control device 197 activates the drive motor 195. Then, the rotation shaft 190 rotates. When the rotation shaft 190 rotates, the first compression unit 120, the second compression unit 150, and the third compression unit 180 are driven. More specifically, the first rotating body 121a and the second rotating body 121b of the axial-flow type compressor 121 of the first compressing section 120 are rotated and the impeller 151a of the second compressing section 150 The impeller 181a of the third compression section 180 rotates.

When the first compression unit 120, the second compression unit 150 and the third compression unit 180 are driven, the fluid introduced from the inlet 113 of the casing 110 flows into the first compression unit 120 And enters the entrance 120a. At this time, the fluid is not compressed, so it has a relatively large nature.

Next, the fluid is compressed to a first pressure in the first compression unit 120. The first compression unit 120 is composed of an axial compressor 121 suitable for compressing large non-body fluid, The high performance is exhibited when the enemy compresses the low pressure of the large flow fluid. In addition, the controller 197 at the time of driving controls the variation of the flow rate by using the variable vane 121c_1 to maintain the optimum efficiency.

The compressed fluid then moves to the first pressure chamber 130, which is in communication with the outlet 120b of the first compression section 120.

The first pressure chamber 130 is provided with a first intercooler portion 140 to cool the fluid in the first pressure chamber 130 to reduce the overall compressor work of the compression system 100.

The fluid cooled by the first intercooler 140 is then drawn into the inlet 150a of the second compression unit 150 which is in communication with the outlet 130b of the first pressure chamber 130. [

Next, the second compression unit 150 compresses the introduced fluid to a second pressure. Here, the second compression unit 150 is composed of an intermittent compressor 151, because the intermittent compressor 151 is advantageous for compressing a fluid having a smaller specific volume than the axial compressor 121.

The compressed air is then transferred to the second pressure chamber 160, which is communicated with the outlet 150b of the second compression unit 150.

A second intercooler portion 170 is disposed in the second pressure chamber 160 to cool the fluid in the second pressure chamber 160 to reduce the overall compressor work of the compression system 100.

The fluid cooled by the second intercooler unit 170 is then drawn into the inlet 180a of the third compression unit 180 which is in communication with the outlet 160b of the second pressure chamber 160. [

Next, the third compression unit 180 compresses the introduced fluid to the third pressure. Here, the third compression unit 180 is constituted by the centrifugal compressor 181, because the centrifugal compressor 181 is advantageous for compressing the fluid having a smaller specific volume than the filament compressor (151).

Then, the compressed fluid is moved to the discharge port 114 communicating with the outlet 180b of the third compression unit 180.

As described above, according to the present embodiment, by configuring the first compression section 120 to include the axial-flow type compressor, it is possible to smoothly perform the compression action of the fluid having a relatively large mass flow rate and to increase the compression efficiency .

According to the present embodiment, the first pressure chamber 130 and the second pressure chamber 160 are disposed in the casing 110, and the first pressure chamber 130 and the second pressure chamber 160, respectively, The first intercooler unit 140 and the second intercooler unit 170 can reduce the compression work as a whole and reduce the number of the first compression unit 120, the second compression unit 150, and the third compression unit 180) of the vehicle.

According to the present embodiment, the variable vane 121c_1 is provided in the axial-flow type compressor 121, and the efficiency of the compression system 100 can be increased by controlling the flow rate change as necessary.

The first pressure chamber 130, the first intercooler section 140, the second compression section 150, the second pressure chamber 130, The second compression unit 160, the second intercooler unit 170, and the third compression unit 180 are disposed together, so that the volume of the compression system 100 can be reduced and the convenience of the operation during assembling and maintenance can be enhanced There are advantages.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, You will understand the point. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

According to an aspect of the present invention, the present invention can be applied to an industry that manufactures or uses a compression system.

100: compression system 110: casing
120: first compression section 130: first pressure chamber
140: first intercooler part 150: second compression part
160: second pressure chamber 170: second intercooler section
180: Third compression section 190:

Claims (7)

A casing having an inlet at one side and an outlet at the other side;
A first compression section disposed in the casing and including at least one axial compressor, for receiving and compressing fluid from the inlet;
A first pressure chamber disposed in the casing and communicating with an outlet of the first compression section;
At least one first intercooler disposed in the first pressure chamber and cooling the fluid in the first pressure chamber;
A second compression unit disposed in the casing and including at least one quadrature compressor, the second compression unit communicating with the outlet of the first pressure chamber to receive and compress the fluid from the first pressure chamber;
A second pressure chamber disposed in the casing and communicating with the outlet of the second compression section;
At least one second intercooler disposed in the second pressure chamber and cooling the fluid in the second pressure chamber;
A third compression section disposed in the casing and including at least one centrifugal compressor, communicating with the outlet of the second pressure chamber to receive the fluid from the second pressure chamber and to transfer the compressed fluid to the outlet; And
And a single rotary shaft for driving the first compression unit, the second compression unit, and the third compression unit,
Wherein the first pressure chamber is disposed between the first compression section and the second compression section and the second pressure chamber is disposed between the second compression section and the third compression section,
Wherein the first compression portion, the first pressure chamber, the second compression portion, the second pressure chamber, and the third compression portion are sequentially disposed from the inlet to the outlet along the single rotation axis. The method according to claim 1,
Wherein the casing includes an upper casing portion and a lower casing portion assembled at a lower portion of the upper casing portion. The method according to claim 1,
Wherein the axial compressor of the first compression section has a variable vane. delete delete delete The method according to claim 1,
Wherein an additional intercooler portion is provided outside the casing.

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