KR100927299B1 - Compressor of high pressure air or gas - Google Patents

Abstract

The present invention relates to a compressor of high pressure air or gas, comprising: a compressor for a high pressure air or gas having a multistage cylinder and a piston moving inside the cylinder, the water for cooling air compressed in the high pressure air or gas compressor A jacket is installed, and the multi-stage cylinder is provided with a cylinder water jacket for cooling the cylinder, respectively, and includes a water cooling radiator for cooling the coolant circulating in the water jacket and the cylinder water jacket, and the cooling fan is fixed to the radiator. It is characterized by.

Accordingly, it is easy to lower the temperature of the air or the gas by means of a separately installed water jacket for cooling the compressed air or the compressed gas, and maintains the temperature of the cylinder water jacket and the cooling water circulating through the water jacket by using a water-cooled radiator. do.

Water jacketed, water cooled, high pressure air or gas compressors

Description

Compressor for high pressure air or gas

The present invention relates to a high-pressure air or gas compressor for compressing air or gas at high pressure, in particular to lower the temperature of the compressed air or gas using water cooling as a cooling method, to operate the piston without oil to prevent the generation of harmful gases It relates to a compressor of high pressure air or gas.

In general, an air compressor compresses and produces air and stores it at a high pneumatic pressure, and supplies it to an air-breathing storage container or a pneumatic tool if necessary. A conventional air compressor includes a compressor main body and a tank storing compressed air. do.

In addition, such an air compressor cools the compressed air produced in the primary and secondary cylinders through a piston and then sends it to the tertiary high pressure cylinder to compress it again.

That is, the connecting rod connected to the crankshaft which transmits the rotational force of the motor vertically reciprocates the piston, whereby the air is sucked and compressed inside the cylinder surrounding the piston.

Such air compressors are classified into low pressure air compressors and high pressure air compressors according to their compression capacity.

In addition, the high pressure compressor has a structure in which each cylinder is configured in series during air compression so that compressed air is supplied through one discharge path through multiple stages.

Here, in the high pressure air compressor, three or more reciprocating pistons are generally installed on the crankshaft in a V-shape or X-shape to compress the air at high pressure while the three or more pistons reciprocate as the crankshaft rotates.

As described above, the high pressure air compressor is formed in multiple stages to compress the air to high pressure, and the air compressed through the high pressure air compressor is used in various aspects.

Among them, compressed air is used as an example to fill the high-pressure pressure vessels worn by firefighters to extinguish the fire, thereby enabling the firefighters to work in the fire place.

As an example of such a high-pressure air or gas compressor, the applicant has applied for a "three-stage high pressure air compressor having a four-stage compression structure" Patent No. 10-0382462.

Compressors of high-pressure air or gas according to the "three-stage high pressure air compressor having a four-stage compression structure" are V-shaped in the crankcase (1), the first and second cylinders (17) at the center upper end, and the third cylinder (on the right) 52) and a compressor of high pressure air or gas of a three-stage compression type composed of a fourth cylinder 5 on the left side is mounted on the air compressor base B.

In addition, the first and second cylinders 17 are equipped with a first and second cylinder heads 19 for heat dissipation and suction and discharge of air, and one side of the first and second cylinder heads 19. The suction filter 50 is equipped with a primary filter for the air sucked.

Further, the tertiary cylinder head 51 and the tertiary cylinder head 51 and the tertiary cylinder head 51 and the tertiary cylinder head 6 are respectively mounted on the upper surfaces.

In addition, an air supply line is connected between each cylinder to circulate compressed air. In order to reduce the temperature of the compressed air by lengthening the supply line, a third cooler (C) is provided in the third and fourth cylinders. ) And a quaternary cooler (C ') are formed.

However, the conventional high pressure air compressor passes through a cooler that extends only a circulation path of a supply line without a separate cooling device, and thus the temperature of the compressed air is about 150 ° C to 160 ° C.

In other words, the compressed air is stored in the bomb and cannot be used in real time.

In addition, when the piston is operated in the integrated cylinder, inhaled air or gas and oil come into contact with the harmful gas is generated.

An object of the present invention is to solve the problems as described above, to provide a high-pressure air or gas compressor to effectively lower the temperature of the compressed air or gas, and to operate the piston without oil to prevent the generation of harmful gases. .

In order to achieve the above object, the high pressure air or gas compressor of the present invention is a high pressure air or gas compressor having a multistage cylinder and a piston moving inside the cylinder, wherein the compressed air is compressed in the high pressure air or gas compressor. A water jacket is installed for the multistage cylinder, and a cylinder water jacket for cooling the cylinder is installed respectively, and includes a water cooling radiator for cooling the coolant circulating in the water jacket and the cylinder water jacket, wherein the radiator has a cooling fan. It is characterized in that it is fixed.

In addition, the water jacket is characterized in that connected to each of the cylinder formed in the multi-stage through the connection path.

In addition, the water jacket is characterized in that connected to the radiator through a radiator connection.

In addition, the cylinder water jacket is characterized in that connected to the radiator through a radiator connection passage.

In addition, a separator for separating a gas and a liquid is inserted into the outer side of the cylinder formed in the multi-stage, respectively.

In addition, the cylinder constituting each stage is formed to surround both sides of the piston consists of two, respectively, characterized in that the side cylinder into which air or gas is introduced operates without oil.

In addition, the radiator is attached to the sensor for detecting the coolant temperature, the sensor is characterized in that connected to the cooling fan through the controller.

In addition, the cooling fan is characterized in that the operation when the temperature of the cooling water flowing into the radiator is above the set temperature.

As described above, according to the compressor of the high pressure air or gas according to the present invention, it is easy to lower the temperature of the air or the gas by means of a separately installed water jacket for cooling the compressed air or the compressed gas, and the cylinder water jacket using a water-cooled radiator. And keep the temperature of the cooling water circulating in the water jacket not to rise.

In addition, since the piston operating without oil does not come into contact with air and oil to prevent the generation of harmful gases, it is easy to use as breathing air.

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

In this embodiment according to the present invention will be described as an example of a high-pressure air or gas compressor consisting of a three-stage cylinder, but is not limited thereto, and may be used in a high-pressure air or gas compressor having four or more cylinders.

In addition, in the present embodiment, the air is described as an example, but the present invention is not limited thereto, and the present invention may be applied to other gases.

As shown in FIG. 2, a three-stage cylinder 10, a piston 20 moving inside the cylinder 10, a water jacket 30 connected to each of the cylinders 10, and not shown, are compressed air. It consists of a bomb that is stored.

Specifically, the cylinder 10 is composed of three stages so that the air is compressed three times. Here, the cylinder 10 is compressed at low pressure in the first stage and high pressure in the second and third stage. If it is equipped with 4 or 5 stages, it is compressed to high pressure in 4 and 5 stages.

At this time, the cylinder 10 and the piston 20 is formed so as to decrease the diameter from one stage to three stages, that is, the lower stage to the higher stage.

The cylinders 10 are each provided with a water-cooled cylinder water jacket 14 surrounding the outer circumferential surface thereof.

On the other hand, a separate water jacket 30 is connected to each of the cylinders 10 and the connection path 40 is installed, the water jacket 30 is long by lowering the temperature of the compressed air through a water cooling method It is formed in a cylindrical shape.

In addition, the water jacket 30 is formed so that the connection passage 40 connected to the respective cylinders 10 passes through the water jacket 30.

That is, as shown in FIG. 3, the air compressed in the first stage cylinder 11 is introduced into the second stage cylinder 12 through the water jacket 30 through the first stage connection path 41 and the second stage. The compressed air in the cylinder 12 is formed to pass through the water jacket 30 through the two-stage connection path 42 to enter the three-stage cylinder 13.

In addition, the air compressed once again in the three-stage cylinder 13 is formed to move to the bomb through the water jacket 30 through the three-stage connection path 43.

Although not shown, separators are installed in the cylinders 10 at each stage to separate the gas and the liquid, that is, remove the water present in the air.

On the other hand, one side of the high-pressure air or gas compressor is provided with a water-cooled radiator 50, a cooling fan 51 for operating toward the radiator 50 is installed.

At this time, although not shown, the radiator 50 is provided with a sensor for detecting the temperature of the cooling water, the cooling fan 51 is operated by a controller connected to the sensor.

That is, the temperature of the coolant is stored in the controller in advance so that the cooling fan 51 is operated when the temperature sensed by the sensor exceeds the set temperature.

In addition, the radiator 50 is connected to the water jacket 30 and each cylinder water jacket 14 to allow the coolant to circulate through the radiator 50, in which case the water jacket 30 and the cylinder water jacket 14 Are respectively connected to the radiator 50 through the radiator connection path 52.

Accordingly, the temperature of the cooling water heated in the water jacket 30 and the cylinder water jacket 14 is lowered by the cooling fan 51 while passing through the radiator 50.

On the other hand, as shown in Figure 4 (a) the cylinder 10 is separated to surround both ends of the piston 20 is composed of two each.

4 (a) shows the interior of the cylinders 10, except for the water jacket 30, the connection path 40, and the radiator connection path 52, for clarity.

In detail, as illustrated in FIG. 4 (b), the two-cylinder cylinder 12 and 12 ′, as shown in FIG. 4B, have a cylinder 12 on the side where air is sucked and compressed. The piston 20 is formed by being separated into the cylinder 12 'on the side where the air is driven, and oil is not used in the cylinder 12 on the side where air is sucked and compressed.

Therefore, it is possible to use a compressor of high pressure air or gas without causing harmful gas to come into contact with air and oil.

Here, one side of the piston 20 is assembled to interlock with the crankshaft 21 through the connecting rod 24, the crankshaft 21 is connected to the drive motor 60 through the belt 70, etc. Works.

The same applies to the cylinders 11 and 13 of the first and third stages, and reference numeral 15 denotes a cylinder head, 22 a discharge valve, and 23 a suction valve.

Since the technique of operating the piston in the cylinder is a known technique, a detailed description of its operation is omitted.

Compression of the air in the compressor of the high pressure air or gas in which the water jacket 30 is installed as described above is as follows.

First, air introduced into the first stage cylinder 11 is compressed to low pressure by the first stage piston 20. The air compressed at low pressure in the first stage cylinder (11) moves to the second stage cylinder (12) through the first stage connecting passage (41), where the first stage connecting passage (41) passes through the water jacket (30). However, since the air is connected to the cylinder 12, the compressed air passes through the water jacket 30 and is first cooled.

Thereafter, in the second stage, the air introduced into the second stage cylinder 12 is once again compressed by the second stage piston 20, and the compressed air in the second stage cylinder 12 passes through the second stage connection path 42. Enter the third stage cylinder (13).

At this time, the second stage connection path 42 is also formed to pass through the water jacket 30, the air compressed in the second stage cylinder 12 is secondarily cooled.

Then, the air introduced into the three-stage cylinder 13 through the two-stage connection path 42 is finally compressed once more through the three-stage piston 20 "to become high pressure air, and the compressed air as described above Again passes through the water jacket 30 through the three-stage connection.

The compressed air finally compressed as described above and passed through the water jacket 30 is moved to the cylinder and stored.

Here, since the three-stage connection path 43 also passes through the water jacket 30, the air compressed in the three-stage cylinder 13 is cooled to the third and stored in the bomb.

In addition, the cooling water circulating in the cylinder water jacket 14 and the water jacket 30 is connected to the radiator 50 through the radiator connecting passage 52 to circulate, respectively, and the cooling fan 51 installed at one side of the radiator 50. Decrease the temperature of the coolant.

Here, the cooling fan 51 is operated when the temperature of the cooling water circulating the radiator 50 is higher than the set temperature to lower the temperature of the cooling water.

Accordingly, it is possible to prevent the temperature rise of the cylinders 10 through the circulation of the coolant and to continuously lower the temperature of the compressed air passing through the water jacket 30.

As described above, the air compressed through the third stage is continuously cooled in the compression process and cooled to a temperature of about 50 ° C., and can be immediately used by storing it in a bomb without a separate cooling time or a separate storage space.

1 shows a compressor of high pressure air or gas according to the prior art;

2 shows a compressor of high pressure air or gas according to the invention.

Figure 3 shows the movement of air in the compressor of the high pressure air or gas of the present invention.

4A and 4B show a piston inside a cylinder in a high pressure air or gas compressor of the present invention.

Explanation of symbols on the main components of the drawings

10: cylinder 11: single stage cylinder

12: 2 stage cylinder 13: 3 stage cylinder

14: cylinder water jacket 15: cylinder head

20: piston 21: crankshaft

22: discharge valve 23: suction valve

24: connecting rod 30: water jacket

40: connection road 41: connection path 1

42: two-stage connection 43: three-stage connection

50: radiator 51: cooling fan

52: With radiator connection

60: drive motor 70: belt

Claims (8)

In a compressor of high pressure air or gas having a multistage cylinder and a piston moving inside the cylinder, A water jacket for cooling the compressed air in the high pressure air or gas compressor is installed, The multi-stage cylinder is provided with a cylinder water jacket for cooling the cylinder, respectively It includes a water-cooled radiator for cooling the cooling water circulating the water jacket and the cylinder water jacket, Cooling fan is fixed to the radiator, The radiator is equipped with a sensor for detecting a coolant temperature, the high-pressure air or gas compressor, characterized in that the cooling fan is operated through a controller in accordance with the temperature detected by the sensor. The method of claim 1, The water jacket is a high-pressure air or gas compressor, characterized in that connected to each of the cylinder formed in the multi-stage through the connecting passage. The method of claim 2, The water jacket is a compressor of high pressure air or gas, characterized in that connected to the radiator through a radiator connection passage. The method of claim 1, The cylinder water jacket is a high pressure air or gas compressor, characterized in that connected to the radiator through a radiator connection. The method according to any one of claims 1 to 4, The compressor of the high-pressure air or gas, characterized in that the separator for separating the gas and the liquid is inserted into the outer side of the cylinder formed in the multi-stage. The method of claim 5, The cylinder of each stage is formed of two to surround each of the two sides of the piston, the high-pressure air or gas compressor, characterized in that the side cylinder into which air or gas is introduced operates without oil. delete The method of claim 1, The cooling fan is a high-pressure air or gas compressor, characterized in that when the temperature of the cooling water flowing into the radiator is operating above a set temperature.

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