KR101190164B1 - Green Air-Compression System - Google Patents

Abstract

The present invention relates to an air compressor system using an air compressor. The air compressor is water-cooled to be buried in the ground to secure space and at the same time reduce noise and use cooling water including cooling waste heat as heating and hot water. To a compression system.
Eco-friendly air compression system of the present invention by the configuration as described above has the following effects. First, the space utilization is high, it can be implemented with minimal space in the city center and dense residential area. Second, it provides a pleasant working environment with low noise and vibration. Third, the air compressor cooling efficiency is high, saving energy consumption. Fourth, energy efficiency is improved because the cooling waste heat generated after heat exchange is recycled to heating.

Description

Green Air-Compression System

The present invention relates to an air compressor system using an air compressor. The air compressor is water-cooled to be buried in the ground to secure space and at the same time reduce noise and use cooling water including cooling waste heat as heating and hot water. To a compression system.

In general, compressors for compressing gas such as air or refrigerant are used in various fields such as car repair shops, car washes, factories and buildings, and the components of the refrigeration cycle are composed of a compressor, a condenser, an expansion valve, and an evaporator. In the same refrigeration cycle, the refrigerant is continuously circulated through the compressor, the condenser, the expansion valve, and the evaporator, thereby performing four physical changes of compression, condensation, expansion, and evaporation by repeatedly changing from gas to liquid and liquid to gas.

Among such compressors, as shown in FIG. 1, the air compressor includes a drive motor 10, a V belt 6a and a belt pulley 6 for transmitting power of the drive motor 10, and a belt pulley. A reducer (2) operating under the rotational force of (6), a compressor (1) interlocked with the reducer (2), a storage tank (5) for storing gas compressed through the compressor (1), and the like. do.

In addition, a gas filter 1a for introducing air into the compressor 1, a compressor body conveying pipe 7 for sending the compressed gas to the storage tank 5, and a compressor body discharged from the storage tank 5. The compressor body outlet pipe 4 is provided, and a cooling fin 1b for cooling the heat generated by the driving of the device is formed on the outer surface of the compressor 1. The drive motor 10, the reducer 2, the compressor 1, and the like are provided on the upper surface of the storage tank 5.

In the figure, reference numeral 3 is a pressure gauge, 9 is a cover covering the device, and 11 is a power supply cable.

In the gas compression apparatus having the above configuration, when the driving motor 10 rotates, the belt pulley 6 rotates through the V belt 6a, and the reducer 2 is rotated by the rotation of the belt pulley 6. In operation, the compressor 1 connected thereto is operated to compress the gas introduced through the gas filter 1a, and the compressor body is stored in the storage tank 5 through the compressor body delivery pipe 7.

As such, the compressed air stored in the storage tank 5 is transferred to the work piece through the pressure gauge 3 during the use of the compressor body outlet pipe 4.

However, the conventional gas compression apparatus as described above has a vibration caused by the rotation of the drive motor 10, the V-belt 6a, the belt pulley 6, etc. during operation, the noise and the compressor (1) and Noise caused by friction generated when driving in the reducer 2 was generated, and when the device was operated for a long time, heat was generated in the device, causing the following problems.

First, most of the gas compression system is installed in a room that requires quietness such as measuring room, design room, and hospital for experiment. There was a problem.

Second, because the configuration is complicated, there is a problem in that the installation area is excessively necessary and a separate space or simple building for installing the facility is required.

Third, since the driving motor 10 and the reducer 2 are installed in contact with the storage tank 5, the vibration generated during driving is transmitted to the storage tank 5, and the storage tank 5 is placed on the floor. Vibration generated by the compressor 1 is transmitted to the floor of the room where the device is installed, which causes errors in measuring equipment and measuring devices. In particular, the most frequently used reciprocating compressor has a problem that the vibration accompanied by severe noise occurs.

Fourth, when the gas compressor operates for a long time, the service life of the equipment is reduced due to overheating generated in the drive motor 10 and the compressor 1, and in particular, the compressor 1 is a part that generates a lot of heat. A configuration for cooling the heat was required.

Therefore, there is a configuration for cooling the heat in the conventional gas compressor, there are typically methods for cooling the heat of the compressor (1) are air-cooled and water-cooled, air cooling is, as described above, to increase the heat transfer contact area The cooling fin 1b is installed on the surface of the compressor 1 to dissipate heat into the air due to the convection of air. However, the cooling fin 1b is insufficient to cool the heat of the compressor 1, so the cooling efficiency is low. There was a problem that the continuous operation is impossible and the energy consumption also increases.

Therefore, a technique using a water-cooled compressor that can increase the cooling efficiency has been known, but most of the configuration is applied to a large structure, requiring a cooling tower and a configuration for supplying cooling water continuously, thus requiring excessive installation area. There was a problem.

In consideration of the above problems and requirements, recently, a technology for reducing vibration and noise by introducing a compressor and a motor integrated equipment inside a coolant tank filled with a gas compression device to operate in a liquid has been introduced. There is still a need for a configuration for circulating the coolant, and the heat energy generated after heat exchange is discarded and the energy utilization is still low.

Therefore, there is an urgent need to develop an eco-friendly air compression system that is simple in configuration to increase space utilization, effectively circulates cooling liquids, increases cooling efficiency, and utilizes thermal energy.

The present invention has been made to solve the above problems, the object of the present invention,

First, the heat of the air compressor is cooled with water, and the air compressor is accommodated in the water tank filled with water to reduce vibration and noise. Second, the water tank is buried in the ground to secure space. In order to increase water consumption, the water supply unit for supplying water to the water tank and the heating unit for storing and utilizing the discharged water are configured to circulate the cooling water. To provide an air compression system.

Eco-friendly air compression system of the present invention comprises an air compressor (10) for compressing air; A water tank 20 in which the air compressor 10 is accommodated and filled with water for reducing and cooling the noise of the air compressor 10; Compressed air tank (30) for storing the compressed air from the air compressor (10); A water supply unit 40 supplying water to the water tank 20; A heating unit 50 connected to the water tank 20 and receiving water including cooling waste heat; And a control unit.

In addition, the air compressor 10 is characterized in that the compressor, the motor and the reducer are integrally formed.

In addition, the water tank 20 is characterized in that it is buried underground.

In addition, the eco-friendly air compression system, the water tank 20 is accommodated in the water-proof cover 60 is filled; includes, the air compressor 10 is characterized in that it is accommodated in the water-proof cover (60). It is done.

In addition, the water tank 20 is characterized in that the overflow pipe 70 for adjusting the water level is further provided.

In addition, the heating unit 50 is a hot water tank 51 for storing the water supplied, a hot water pump 52 for supplying water to the hot water tank 51, and stored in the hot water tank 51 It characterized in that it comprises a radiator 53 for receiving hot water and heating and a hot water valve 54 for supplying the hot water.

In addition, the eco-friendly air compression system, one end is connected to the rear end of the radiator 53, the other end is connected to the water supply unit 40; characterized in that it comprises a.

In addition, the radiator 53 is characterized in that it comprises a moving means (53a) at the bottom to be movable.

In addition, the compressed air tank 30 is installed spaced apart upwards from the ground, the air compressor 10 and the compressed air tank 30 is characterized in that connected through the compressed air supply pipe (10b).

Eco-friendly air compression system of the present invention by the configuration as described above has the following effects. First, the space utilization is high, it can be implemented with minimal space in the city center and dense residential area. Second, it provides a pleasant working environment with low noise and vibration. Third, the air compressor cooling efficiency is high, saving energy consumption. Fourth, energy efficiency is increased because the cooling waste heat generated after heat exchange is recycled to heating.

1 is a front view of a conventional air-cooled air compressor
Figure 2 is an internal perspective view of the water tank of the present invention
3 is a schematic view of an air compression system of the present invention
Figure 4 is an internal perspective view of the water tank of the second embodiment of the present invention
5 is a schematic diagram of an air compression system according to a second embodiment of the present invention.
6 is a schematic diagram of an air compression system according to a third embodiment of the present invention.

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

2 and 3, the eco-friendly air compression system according to the present invention the device is an air compressor 10, water tank 20, compressed air tank 30, water supply unit 40, heating unit 50 And an overflow pipe 70 and a recycle pipe 80.

The air compressor 10 uses what is known as a device for compressing air. The air compressor 10 may be integrally formed with a compressor, a motor, and a reducer. When the compressor, the motor and the reducer of the air compressor 10 are integrally formed, the external surface area of the air compressor 10 can be reduced, so that the waterproof structure is easy. The air compressor 10 may be finished with an outer surface of the waterproof material. This is to allow the air compressor 10 to be directly cooled by water. The air compressor 10 sucks air from the suction unit 15, and the compressor is operated by driving the motor so that the compressed air is stored in the compressed air tank 30. The air compressor 10 and the suction unit 15 may be connected through the suction pipe 10a, and the air compressor 10 and the compressed air tank 30 may be connected through the compressed air supply pipe 10b.

The water tank 20 may be formed to accommodate the air compressor 10 therein. Water may be filled in the water tank 20. The water filled in the water tank 20 serves as a coolant to directly cool the air compressor 10 and at the same time attenuates noise and vibration emitted to the outside of the air compressor 10. The outer wall of the water tank 20 may be formed to protrude in a zigzag outer surface 20a to increase the surface area. This increases the heat exchange efficiency between the water filled in the water tank 20 and the outside, and serves to attenuate the noise and vibration secondarily.

The water tank 20 may be connected to the water supply unit 40 to receive water, and may be connected to the heating unit 50 to discharge the water. The water supply unit 40 and the water tank 20 may be connected through a water supply pipe 42, and the water tank 20 and the heating unit 50 may be connected through hot water pipes 52a and 52b. Due to the configuration as described above it is possible to increase the cooling efficiency of the air compressor 10 by allowing the water to flow without a separate cooling water circulation device. In addition, the water containing the cooling waste heat exchanged from the air compressor 10, that is, hot water is supplied to the heating unit 50, thereby increasing the energy efficiency.

The present invention can be said to be the most ideal system when the amount of water supplied to the water tank 20 and the hot water discharged to the heating unit 50 is the same, but when the amount of hot water discharged is less than the water supplied When the amount of hot water consumed by the heating unit 50 is small, an overflow pipe 70 is provided at the top of the water tank 20 to control the water level by forcibly discharging the water supplied to the water tank 20. Can be. The water including the cooling waste heat forcedly discharged through the overflow pipe 70 may be used as a means for preventing the freezing of the winter surface by allowing it to flow along the surface. Although the overflow pipe 70 is shown to be installed in close proximity to the water supply pipe 42, the overflow pipe 70 is maximized in the water supply pipe 42 so that the supplied water can be discharged after the heat exchange as possible It is preferable to be spaced apart.

The compressed air tank 30 may be installed at a spaced distance above the ground. This is to increase the space utilization of the air compression system of the present invention. The compressed air tank 30 stores the compressed air introduced through the compressed air supply pipe 10b and is used through a nozzle (not shown) where necessary.

The water supply unit 40 may be used for conventional water supply and groundwater. The water supply unit 40 is connected to the water tank 20 through the water supply pipe 42 serves to supply water to the water tank 20. The water supply unit 40 may be installed so that a predetermined amount of water is supplied to the water tank 20 when the air compressor 10 operates in conjunction with the air compressor 10.

The heating unit 50 includes a hot water tank 51, a pump 52, a radiator 53, and a hot water valve 54.

The hot water tank 51 receives and stores the water containing the cooling waste heat discharged from the water tank 20, that is, the hot water. The hot water tank 51 and the water tank 20 may be connected through hot water pipes 52a and 52b. The pump 52 may be installed on the hot water pipes 52a and 52b. The pump 52 is operated in conjunction with the water level sensor of the hot water tank 51 until the water level of the hot water tank 51 reaches a predetermined height.

The radiator 53 receives the hot water from the hot water tank 51 to heat and heat the surroundings, and the hot water valve 54 receives the hot water from the hot water tank 51 to provide hot water. The radiator 53 and the hot water valve 54 may be connected to the hot water tank 51 through a hot water supply pipe 51a.

The heating unit 50 is the core configuration of the eco-friendly system of the present invention in that it uses recycled energy without requiring separate energy consumption because it uses water containing cooling waste heat discharged from the water tank 20. can do.

At this time, the water cooled through the radiator 53 is recycled to the water tank 20 through the recycle pipe (80). The recycling pipe 80 may be installed such that one side is connected to the radiator 53 and the other end is connected to the water supply pipe 42. By recirculating the water cooled through the recycle pipe 80 to increase the cooling efficiency of the water tank 20 and to minimize the amount of water discharged to maximize the resource recycling effect.

In addition, the radiator 53 may include a moving means 53a to be movable. In winter, it is located in an indoor or outdoor work space where heating is required, and when heating is not needed, such as in summer, it does not stop operation. In order to exchange heat with the water filled in the water tank 20 through the recycle pipe (80).

Hereinafter, a second embodiment of the present invention as described above will be described in detail with reference to the accompanying drawings.

4 and 5, the second embodiment of the present invention is applied to the configuration of the first embodiment as described above, the waterproof cover 60 is further included.

The waterproof cover 60 may be formed surrounding the main body to accommodate the air compressor 10. The waterproof cover 60 is filled with air. The waterproof cover 60 is characterized in that it is provided as an additional waterproof means for strengthening the durability of the air compressor 10 because the air compressor 10 is accommodated in the water to operate. In addition, as the heat exchange, noise attenuation, and vibration attenuation functions are primarily performed through the air filled in the waterproof cover 60, an additional effect of doubling the heat exchange efficiency, noise, and vibration damping effect may be expected. The outer surface of the waterproof cover 60 may be provided with a fin (60a) or integrally formed in the waterproof cover 60 in order to increase the heat exchange efficiency, noise and vibration damping effect.

Environment-friendly air compression system of the second embodiment of the present invention configured as described above to improve the durability of the air compressor (10) through the waterproof cover 60, primarily performing heat exchange, noise attenuation and vibration attenuation functions Since the second water tank 20 performs heat exchange, noise attenuation, and vibration attenuation functions secondly, it can be said that the heat exchange efficiency, noise attenuation effect, and vibration damping effect are superior to those of the first embodiment.

Hereinafter, a third embodiment of the present invention as described above will be described in detail with reference to the accompanying drawings.

6, in the third embodiment of the present invention, the configuration of the first embodiment described above is applied as it is, and the water tank 20 may be embedded in the ground. This increases the space utilization of the air compression system of the present invention, it can also be expected a side effect of the additional attenuation of noise and vibration generated outside the water tank (20).

The outer wall of the water tank 20 may be formed to protrude in a zigzag outer surface 20a to increase the surface area. This serves to increase heat exchange efficiency between the water filled in the water tank 20 and the outside and to attenuate the noise and vibration secondarily, and when the water tank 20 is buried in the ground, the outer surface ( 20a) The shape gives the effect of being firmly fixed in the ground.

In addition, it is possible to increase the space utilization by having the water supply pipe 42 located in the ground directly connected through the water supply pipe 42 without having to lift the ground.

Environment-friendly air compression system of the third embodiment of the present invention having the above configuration is superior to the first and second embodiments in terms of securing space because the configuration of the water tank 20 and the water supply unit 40 is buried in the ground It's a system.

The technical idea should not be construed as being limited to the above-described embodiment of the present invention. Various modifications may be made at the level of those skilled in the art without departing from the spirit of the invention as claimed in the claims. Therefore, such improvements and modifications fall within the protection scope of the present invention, as will be apparent to those skilled in the art.

10: air compressor 10a: suction pipe
10b: compressed air supply pipe 15: suction
20: water tank
30: compressed air tank
40: water supply
50: heating unit 51: hot water tank
52: hot water pump 53: radiator
54: hot water valve
60: waterproof cover
70: overflow pipe
80: recycling tube

Claims (9)

An air compressor 10 for compressing air;
A water tank 20 in which the air compressor 10 is accommodated and filled with water for reducing and cooling the noise of the air compressor 10;
Compressed air tank (30) for storing the compressed air from the air compressor (10);
A water supply unit 40 supplying water to the water tank 20;
A heating unit 50 connected to the water tank 20 and receiving water including cooling waste heat; And
A waterproof cover 60 accommodated in the water tank 20 and filled with air; Including;
The air compressor (10) is eco-friendly air compression system, characterized in that accommodated in the waterproof cover (60).
The method of claim 1,
The air compressor (10) is an eco-friendly air compression system, characterized in that the compressor, motor and reducer are integrally formed.
The method of claim 1,
The water tank 20 is an eco-friendly air compression system, characterized in that buried underground.
delete The method of claim 1,
The water tank 20 is an eco-friendly air compression system, characterized in that it is further provided with an overflow pipe (70) for adjusting the water level.
The method of claim 1,
The heating unit 50 is a hot water tank 51 for storing the water supplied, a hot water pump 52 for supplying water to the hot water tank 51, and hot water stored in the hot water tank 51 Eco-friendly air compression system comprising a radiator (53) for receiving and heating the supply and a hot water valve (54) for supplying the hot water.
The method according to claim 6,
The eco-friendly air compression system,
Eco-friendly air compression system comprising a; one end is connected to the rear end of the radiator (53) and the other end is connected to the water supply unit (40).
The method according to claim 6,
The radiator (53) is an eco-friendly air compression system, characterized in that it comprises a moving means (53a) at the bottom to be movable.
The method of claim 1,
The compressed air tank 30 is spaced upwardly above the ground, the air compressor (10) and the compressed air tank (30) is an eco-friendly air compression system, characterized in that connected through the compressed air supply pipe (10b).

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