KR101514246B1 - Air compressor - Google Patents

Abstract

The present invention relates to a cooling apparatus-connected air compressor which separates and installs each composition for air compression and cooling treatment of compressed air produced by the same on two frames, and connects and separates the two frames mutually. To this end, according to the present invention, the cooling apparatus-connected air compressor comprises: a compressed frame in a square box form having an inner space part; an air compression unit arranged on the space part of the compressed frame; a cooling frame in a square box form having an inner accommodation part; a cooling unit arranged on the inner accommodation part of the cooling frame, and cooling compressed air by the compression unit; and a connecting unit interconnecting the compressed frame and the cooling frame.

Description

[0001] AIR COMPRESSOR [0002]

The present invention relates to a cooling device connecting type air compressor in which an air compressor and a cooling device are incorporated in each frame and each frame is interconnected and detachable.

As a technology relating to an air compressor having a cooling device,

(Hereinafter referred to as "prior art") of the Korean Utility Model Registration No. 20-0303920 (registered on Jan. 29, 2003), a cooling unit fixing structure for a screw air compressor,

In the prior art, the vertical base is fixed on the upper corner of the square bottom plate, the auxiliary base is vertically fixed between the front base and the back base, and the upper base and the auxiliary base are connected to the horizontal / A horizontal support for supporting a cooling unit is provided between the front and rear auxiliary supports, a motor is fixed to a side of the horizontal support, and a motor And a circulation pipe assembly is installed on the upper part of the blowing fan to effectively fix the cooling unit for cooling the compressed air and the compression oil to the proper place of the main frame without a separate frame.

The present invention relates to a refrigerator which comprises a compression part for compressing a sucked outside air, a compression frame in which the compression part is housed, a cooling part for cooling the compressed air produced in the compression part to supply it to the outside, A cooling unit connecting type air compressor having a structure in which compression and cooling structures are connected and connected to separate frames by providing a connecting unit for interconnecting frames has been developed.

It is an object of the present invention to provide a cooling device-connected air compressor capable of mutual coupling and separation between an air compression system and a cooling system.

According to an aspect of the present invention, there is provided a cooling device connecting type air compressor,

A square box type compression frame having an inner space portion;

An air compression part disposed in a space of the compression frame;

A rectangular box-shaped cooling frame having an inner receiving portion;

A cooling part disposed in the receiving part of the cooling frame for cooling the compressed air by the compressed part; And

A connecting unit for interconnecting the compression frame and the cooling frame;

.

At this time,

A duct case protruding from the side wall of the cooling frame,

An insertion space formed in the sidewall of the compression frame to insert the duct case,

A fastening means for fastening the contact surfaces of the compression frame and the cooling frame to each other;

.

The duct case includes an inner passage for circulating outside air into the cooling frame, an outer air inlet passage formed at a lower portion thereof so as to be connected thereto and spaced apart from the installed floor,

Wherein the compression frame is formed with an opening portion penetrating vertically through a bottom surface facing the inflow passage of the duct case.

In the cooling device connecting type air compressor according to the present invention,

There is a great effect that each frame is connected and separated by the connecting unit when the compression system and the cooling system are installed in each frame.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a three-dimensional view showing a compression frame and a compression part in a cooling device connecting type air compressor according to the present invention;
Fig. 2 is a front structural view of Fig. 1,
Fig. 3 is a rear view of Fig. 1,
FIG. 4 is a three-dimensional view showing a cooling frame and a cooling part in a cooling device connecting type air compressor according to the present invention,
Fig. 5 is a front view of Fig. 4,
Fig. 6 is a side view of Fig. 4,
7 is a front view showing the mutual coupling between the compression frame and the cooling frame;

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

Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined. Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and are not intended to represent all of the technical ideas of the present invention. Therefore, various equivalents It should be understood that water and variations may be present.

The top accommodating portion side is specified as an upper or upper side, and the bottom accommodating portion side is defined as a lower or lower side with reference to Fig.

1 to 7, a cooling device connecting type air compressor according to the present invention includes:

A compression part P1, a cooling frame 10, a cooling part P2, and a connecting unit 200. As shown in Fig.

Looking at each configuration,

The compression frame 100

As shown in Figs. 1 to 3

The inner space portion 101,

As shown in Fig.

Four horizontal frames 103 connecting the upper ends of the four vertical frames 102 and four horizontal frames 103 connecting the upper ends of the four vertical frames 102, And a frame 104, and the space 101 is formed inside.

The compressed part part (P1)

As shown in Figs. 1 to 3,

A conventional piston type air compression module is provided on one side of the top frame 104 to be disposed in the space 101 of the compression frame 100 and includes at least one piston driving part P12 for compressing the sucked outside air, A cylinder portion P11 having

A compressed air tank P13 which is provided on the other side of the top frame 104 to be disposed in the space portion 101 of the compression frame 100 and stores the compressed air produced by the cylinder portion P11,

.

The cooling frame 10

As shown in Figs. 4 and 5,

The inner accommodating portion (11)

(A four-sided surface and a top and a bottom cage).

At this time, the receiving portion 11 is divided into upper and lower receiving portions 11A and 11B by the partition wall 12,

As a result, the partition wall 12 has a function of preventing a convection phenomenon between a cooling unit 20 and a refrigeration cycle unit 50 to be described later, and a function of preventing a heat exchange tank 30 and a compressed air relay pipe 23).

The cooling frame 10 further includes top and bottom ventilation openings 13A and 13B respectively formed in the top and bottom accommodating portions 11A and 11B,

The top and bottom ventilation openings 13A and 13B are formed with a plurality of holes, and external air can flow in.

The cooling frame 10 has a top base portion 14A on the housing 21 side of a cooling unit 20 to be described later and a bottom exhaust portion 13B on the wall adjacent to the bottom air outlet 13B in the bottom accommodating portion 13B. (14B) are formed.

At this time, the top and bottom exhaust portions 14A and 14B are formed of a plurality of holes, and the internal air can be discharged.

The cooling frame 10 covers the rear side of the tower and the bottom ventilation openings 13A and 13B so that the internal passages to the top and bottom ventilation openings 13A and 13B, that is, the top and bottom ventilation openings 13A and 13B, And a duct case 15 having an internal passageway 151 for connecting therewith, and an inflow passageway 152 formed so as to be spaced apart from the installation floor so as to be opened downwardly to be connected thereto.

Therefore, the outside air flows into the inflow passage 152 of the duct case 15 and flows into the top and bottom ventilation openings 13A and 13B through the inside passage 151, respectively.

At this time, the inflow passage 152 of the duct case 15 is formed at a position spaced apart from the installation floor adjacent to the installation floor, so that the cold air staying on the floor is introduced into the duct 15, To maximize the cooling efficiency in the blower 24 of the unit 20 and the condenser 52 of the refrigeration cycle unit 50.

The cooling part part (P2)

(11) of the cooling frame (10) for cooling the compressed air by the compressed part (P1)

A refrigerant circulation pipe 40C, a refrigeration cycle unit 50 and a discharge unit 60. The refrigerant circulation pipe 40C, the refrigerant circulation pipe 40C, the refrigerant cycle unit 50,

First, as shown in Fig. 5, the cooling unit 20

For cooling the high-temperature, high-pressure compressed air introduced from the air compressor (AC)

A housing 21 coupled to the upper inner wall of the tower accommodating portion 11A in the accommodating portion 11 of the cooling frame 10 and having a hollow structure,

A compressed air supply pipe 22 interconnecting the air compressor (AC) and the housing 21,

A compressed air relay tube (23) for interconnecting the housing (21) and the heat exchange tank (30), and

A blower 24 mounted on the lower portion of the housing 21 and having an impeller 241 for blowing the air introduced from the tower air vent 13A to the housing 21 side,

.

At this time, the supply pipe 22 has one end connected to one side of the housing 21 and the other end passing through a wall formed with the tower vent 13A in the cooling frame 10, And is connected to the compressed air tank P13 of the compressed part part P1.

One end of the compressed air relay pipe 23 is connected to the other side of the housing 21 and the other end of the compressed air relay pipe 23 is connected to the side of the heat exchange tank 30 after vertically penetrating the partition wall 12.

The air flowing into the tower ventilation hole 13A is blown toward the lower side of the housing 21 by the rotation operation of the impeller 241 of the blower 24 so that the air passes through the housing 21 from the supply pipe 22, The compressed air flowing into the compressed air relay pipe 23 is cooled.

The air blown by the impeller 241 of the blower 24 is exhausted to the outside via the top base portion 14A of the cooling frame 10. [

4 and FIG. 5, the heat exchange tank 30

The compressed air cooled by the cooling unit 20 is stored,

And is vertically fixed to the bottom portion 11B side of the receiving portion 11 of the cooling frame 10 so that the top end of the bottom portion 11B is supported by the partition wall 12 .

On the other hand, as shown in Figs. 4 and 5, the inflow pipe 40A

And a tube connected to a lower portion of the heat exchange tank 30 to receive the refrigerant.

On the other hand, as shown in Figs. 4 and 5, the outlet pipe 40B

And a tube which is connected to the lower part of the heat exchange tank 30 adjacent to the inflow pipe 40A and through which the refrigerant flows.

On the other hand, as shown in FIG. 4, the refrigerant relay pipe 40C

And a pipe connecting the inlet pipe (40A) and the outlet pipe (40B) so as to pass through the inside of the heat exchange tank (30).

In other words, the refrigerant relay pipe 40C has an end connected to the heat exchange tank 30 at the inlet pipe 40A and an end connected to the heat exchange tank 30 at the outlet pipe 40B And a tube having a structure that is interconnected and embedded in the heat exchange tank (30).

Therefore, the refrigerant flowing through the inlet pipe 40A passes through the refrigerant relay pipe 40C to the outlet pipe 40B.

On the other hand, as shown in FIG. 5, the refrigeration cycle unit 50

And is interposed in the inflow pipe (40A) and the outflow pipe (40B) for cooling the refrigerant.

A compressor 51 connected to the inflow pipe 40A and mounted on the bottom of the bottom accommodating portion 11B to compress the refrigerant,

A condenser 52 mounted on the wall of the bottom portion 11B of the cooling frame 10 for condensing and liquefying the high temperature and high pressure refrigerant by the compressor 51,

An expansion valve (53) connected to the outflow pipe (40B) for reducing the pressure of the liquid refrigerant by the condenser (52) to a low pressure, and

An evaporator 54 disposed in the outlet pipe 40B and the expansion valve 53 for evaporating the refrigerant decompressed by the expansion valve 53;

.

At this time, the condenser 52 includes two supports 521 installed on both sides of the bottom vent 13B in the wall where the bottom vent 13B of the cooling frame 10 is positioned, A condensing relay pipe 523 for connecting the compressor 51 and the condensing pipe 522 and a condenser pipe 523 fixedly installed between the two supports 521, And a condensing impeller 524 for sucking air from the bottom vent 13B.

The other end of the outlet pipe 40B, that is, the opposite end of the end connected to the heat exchange tank 30 is connected to the condensing pipe 522.

Accordingly, the air introduced from the bottom ventilation opening 13B is blown into the condensing tube 522 by the rotation operation of the condensing impeller 524, thereby condensing and liquefying the refrigerant passing through the condensing tube 522, Flows into the outflow pipe 40B,

The liquefied refrigerant flowing into the expansion valve (53) connected to the outlet pipe (40B) is depressurized to a low pressure by the expansion valve (53)

The refrigerant decompressed by the expansion valve 53 is vaporized while passing through the evaporator 54. The vaporized refrigerant passes through the refrigerant relay pipe 40C through the outlet pipe 40B and flows into the heat exchange tank 30 The heat of the compressed air in the air is absorbed.

On the other hand, as shown in Figs. 4 and 5, the discharge unit 60

And is for discharging the compressed air stored in the heat exchange tank 30 to the outside by being disposed in the bottom accommodating portion 11B in the accommodating portion 11 of the cooling frame 10,

A discharge pipe 61 whose one end is connected to the intermediate side of the heat exchange tank 30 and whose other end is exposed to the outside through the wall of the cooling frame 10,

Two or more filter members 62 for filtering contaminants contained in the compressed air provided on the discharge pipe 61,

.

Accordingly, the compressed air cooled in the heat exchange tank 30 is filtered by the two or more filter members 62 while being discharged through the discharge pipe 61, and then discharged to the outside.

The connecting unit 200

As shown in Fig. 7,

For connecting the compression frame (100) and the cooling frame (10)

The duct case 15 of the cooling frame 10,

An insertion space 201 formed on a sidewall of the compression frame 100 to insert the duct case 15,

A fastening means (202) for fastening the compression frame (100) and the cooling frame (10)

.

As described above, the duct case 15 includes an inner passage 151 for circulating outside air into the cooling frame 10, an outside air inflow passage (not shown) 152).

At this time, the compression frame 100 is formed with an opening 105 passing through a floor facing the inflow passage 152 of the duct case 15, that is, the bottom frame 104, It is preferable that a bottom passage 106 for introducing outside air into the opening 105 and a bottom passage 106 for supplying the outside air to the opening 105 is formed. For example, the bottom frame 104 may have a cross- 106 may be formed.

The fastening means 202 may be a bolt or the like which is inserted through the contact surface between the compression frame 100 and the cooling frame 10.

While the present invention has been described with reference to the accompanying drawings, it should be understood that various changes and modifications may be made by those skilled in the art without departing from the spirit and scope of the present invention as defined by the appended claims. And should be construed as falling within the scope of protection of the present invention.

100: Compressed frame
101: Space section 102: Vertical frame
103: Horizontal frame 104: Floor frame
105: opening portion 106: bottom passage
P1: Compressed part
P11: Cylinder part P12:
P13: Compressed air tank
P2: cooling part
200: connecting unit
201: insertion space unit 202: fastening means
10: Cooling frame
11: accommodating portion 11A: tower accommodating portion
11B: bottom receptacle 12: partition wall
13A: Top ventilation hole 13B: Bottom ventilation hole
14A: Upper base portion 14B: Bottom exhaust portion
15: Duct case 151:
152: Internal passage
20: cooling unit
21: housing 22: supply pipe
23: Compressed air relay tube 24: Blower
241: Impeller
30: Heat exchange tank
40A: inlet pipe
40B: Outflow tube
40C: Refrigerant relay tube
50: Refrigeration cycle unit
51: compressor 52: condenser
521: Support 522: Condenser tube
523: condensation relay tube 524: condensing impeller
53: expansion valve 54: evaporator
60: exhaust unit
61: exhaust pipe 62: filter member

Claims (3)

A square box type compression frame having an inner space portion;
An air compression part disposed in a space of the compression frame;
A rectangular box-shaped cooling frame having an inner receiving portion;
A cooling part disposed in the receiving part of the cooling frame for cooling the compressed air by the compressed part; And
A connecting unit for interconnecting the compression frame and the cooling frame;
, ≪ / RTI >

The connecting unit
A duct case protruding from the side wall of the cooling frame,
An insertion space formed in the sidewall of the compression frame to insert the duct case,
A fastening means for fastening the contact surfaces of the compression frame and the cooling frame to each other;
And a cooling device connected to the air compressor.
delete The method according to claim 1,
Wherein the duct case has an inner passage for circulating outside air into the cooling frame and an outside air inflow passage formed at a lower portion thereof so as to be connected thereto and spaced apart from the installed floor,
Wherein the compression frame is formed with an opening portion penetrating vertically through the floor facing the inflow passage of the duct case.

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