KR200447369Y1 - Moisture separating device for air compressors - Google Patents

Abstract

The present invention relates to a water separator that is mounted on an air compressor for compressing air to discharge a high pressure gas, and in particular, gradually forms a guide tube having an enlarged size gradually between the upper and lower fixed plates, The gas is moved in the upper and lower zigzag form along the flow path formed between the tubes, and by forming the vortex conductor in the upper and lower ends of the guide tube in a zigzag form, the gas is rotated and moved in a spiral form.

The high pressure gas flowing through the compressor circulates in the form of zigzag up and down and repetitive spiral vortices to effectively remove water droplets and moisture in the gas, and the water moves along the inner wall of the guide tube by a catchment formed on the inner wall of the guide tube. It is a water separator for an air compressor having an excellent characteristic of removing water droplets and water contained in the high pressure gas because it collects and discharges it quickly and effectively.

Compressor, Moisture, Separation, Mounting Plate, Vortex, Helix, Passage, Circulation, Sump

Description

Moisture separating device for air compressors

The present invention relates to a water separator that is mounted on an air compressor for compressing air to discharge high-pressure gas, and particularly, separates concentric guide tubes having a size gradually expanding between upper and lower fixing plates. By forming the air vents and the vortex conductors in the upper and lower zigzag shapes at the tip and the bottom of these guide tubes, the gas moving with the spiral flow from the inside of the center guide tube is gradually moved in the zigzag form through the expansion flow path. Moisture contained in the gas on the path flows along the inner wall of the guide tube by centrifugal force to be collected, thereby having an excellent water removal effect even with a relatively simple structure.

In general, the air compressor serves to inhale air in the air and convert it into a high pressure gas by using a compression force such as a piston, and the air compressor is provided with a compression tank capable of storing the high pressure air. Through the air pipes drawn out from the compression tank, various air tools and the like can be used.

In other words, it is possible to use a variety of devices and devices such as an air gun, air impact and air spray or air power mechanism using high pressure air, the above-mentioned tools and devices using high pressure air to obtain a relatively strong rotational torque It can be able to perform a variety of tasks impossible by the electric motor.

In this case, a separate water separation device is installed in the air pipe drawn out from the compression tank of the air compressor. Inside the compression tank of the air compressor, water droplets and a large amount of water generated by compressing the air at high pressure are stored. Since it is generated will combine the device for separating and removing such water droplets from the high pressure air.

That is, the storage device of the air compressor acts as a condenser. When the air of high pressure is compressed and the air is cooled, water vapor in the air condenses in the form of water droplets. Likewise, the process of getting rid of foreign substances will be a failure.

Therefore, the water separator is for separating and removing the water droplets discharged together with the high pressure air from the compression tank, the separator using a rotary centrifugal force, the removal device using a heating heater and the removal device using a filter, and the like. As it is, the configuration of the most widely used universal water separator is shown in FIG.

That is, a general water compressor for air compressor, as shown in the illustration, when the high pressure air is provided from the inlet 101 formed on one side of the upper connector 100, the gas inside the outer cylinder 102 below the upper connector 100 It is to be introduced into, the front end of the outer cylinder 102 is coupled to the vortex oil tool 104 is formed with a spiral groove 103 on the outer surface so that the gas is vortex moving in the downward spiral inside the outer cylinder (102) Done.

The gas in such a moving state is introduced into the lower portion of the inner cylinder 105 with the lower portion reaching the lower end of the outer cylinder 102, and the discharge guide tube 106 vertically mounted inside the inner cylinder 105. Accordingly, it is to be discharged to the outlet 107 on one side of the upper connector (100).

At this time, the vortex oil tool 104 is formed at the lower end of the discharge guide tube 106 to allow the gas to vortex in an upward spiral between the inner cylinder 105 and the discharge guide tube 106. The lower end of the outer cylinder 102 is coupled to the collecting container 108 and the drain valve 109 for collecting water.

Accordingly, the gas provided to the inlet 101 is vortically circulated in the spiral of the inside of the outer cylinder 102 and the inside of the inner cylinder 105 at a high speed while the moisture in the gas is transferred to the outer cylinder 102 and the inner cylinder (by the centrifugal force). It is configured to flow along the inner wall of 105, and when a certain amount of water is collected inside the container 108, the drain valve 109 is operated to discharge the water.

However, the conventional water separator for air compressors, as described above, can effectively separate large-sized droplets, but small droplets are light, and thus have a disadvantage of being swept away with the gas rotating at high speed. In reality, there are still difficulties in the work where no water or water droplets are discharged, such as spray painting.

In other words, the conventional water separator has a structure that separates water from the moving centrifugal force by rotating centrifugal force with a high-speed kinetic force and rotates in a spiral, but heavy water droplets flow down the inner wall and are collected while being light and Small droplets of water are rotated and discharged together by the kinetic force of the gas, so the effect of water separation and removal is not satisfactory.

The present invention is devised to improve the problems as described above, gradually forming a guide tube having an enlarged size gradually between the upper, lower fixed plate, the gas is formed along the flow path formed between these guide tubes, Lower zigzag movement, and the upper and lower ends of the guide tube to form a vortex conductor in a zigzag form, the gas is rotated in a spiral to move, the inner wall of the guide tube is divided radially in the catchment It is an object of the present invention to provide a water separation device for an air compressor to form and thereby to achieve a reasonable separation and removal of water.

The water separator for an air compressor of the present invention as described above is circulated in the upper and lower zigzag and repetitive vortices by flowing the high pressure gas, and the water guide device formed on the inner wall of the guide tube while effectively removing water droplets and moisture in the gas. As the water moving along the inner wall of the pipe is quickly and effectively collected and discharged, it is excellent in removing water droplets and water contained in the high pressure gas.

Hereinafter, preferred embodiments of the present invention will be described.

2 is an exploded perspective view of a water separator for an air compressor according to the present invention, FIG. 3 is an exploded cross-sectional view of a water separator for an air compressor according to the present invention, and FIG. 4 is a water separator for an air compressor according to the present invention. It is a combined section.

The water separator for the air compressor according to the present invention is to be completed by fastening the upper fixing plate 10 and the outer cylinder 30 and the lower fixing plate 20 to each other, the inside of the outer cylinder 30 in each other, At least two or more guide tubes 40 and 40 ′ having different outer diameters are inserted with the same center line while being spaced apart from each other, such that the flow paths 41 are spaced between the guide tubes 40 and 40 ′. 41 'is formed.

At this time, the upper fixing plate 10 is formed in the transverse direction with the discharge passage 11 connected to the flow passage 41, 41 'and the end of the discharge passage 11 is the innermost guide pipe 40 It penetrates inward.

In addition, an inlet 12 is formed at one side of the upper fixing plate 10 to be connected to the compression tank of the compressor, and the inlet 13 formed in the transverse direction from the inlet 12 is the innermost guide tube 40. It is penetrating towards.

In addition, the lower fixing plate 20 is also formed with another discharge channel 21 in the transverse direction, such a discharge channel 21 also flow paths 41 and 41 between the guide pipes 40 and 40 '. ') And the end of the discharge passage 21 is in communication with the collecting passage 22 formed in the center of the lower fixing plate (20).

Particularly, the vortex conductors 50 and 50 ′ which are sequentially inserted in a zigzag form are fixed to the inner ends and the lower ends of the flow paths 41 and 41 ′, respectively. ), The vortex holes 51 and 51 'having a planar curved shape are radially formed, and the inner ends of the vortex holes 51 and 51' are formed in the guide tubes 40 and 40 '. It is connected to the ventilation holes 42 and 42 'formed at the front end or the lower end, and the other end of the vortex holes 51 and 51' is open toward the flow paths 41 and 41 '.

Here, the high-pressure gas provided through the inflow path 13 is not directly introduced into the innermost guide tube 40, but is a separate spiral conductor 60 mounted at the tip of the guide tube 40. As flowing through, the outer surface of the spiral conductor 60 is formed with a spiral groove 61 and the tip of the spiral groove 61 is open to be connected to the inflow path 13, The high-pressure gas provided through the inflow path 13 of the gas is discharged into the innermost guide tube 40 while rotating downward along the spiral groove 61 of the spiral conductor 60.

Accordingly, as shown in FIG. 5A, the gas discharged into the innermost guide tube 40 rapidly rotates and moves downward in a downward spiral, so that water droplets or moisture in the gas are moved to the inner wall of the guide tube 40 by the rotating centrifugal force. And gas flows downward, and the gas in the state in which water is first removed is flowed through the vent holes 42 and 42 'at the bottom of the guide tube 40 on the flow paths 41 and 41' on the outside thereof. It moves to the vortex holes 51 and 51 'of the vortex vortex conductors 50 and 50' which are fastened, and the vortex holes 51 and 51 'of the curved shape are shown in FIGS. 5B and 5C. As it is gradually discharged in a spiral form toward the inside of the flow passage 41 (41 ') having an extended inner diameter, the spiral rotational movement of the gas is also repeatedly made in the corresponding flow passage 41 (41'). .

In particular, the water and water droplets in the gas flow along the inner wall of each of the guide pipes 40 and 40 'while the flow paths 41 and 41' are moved in the zigzag form as described above. It moves along the direction of movement and is introduced into the discharge channel 11 in the upper fixing plate 10 or the discharge channel 21 in the lower fixing plate 20.

Here, the water flowing into the discharge channel 11 of the upper fixing plate 10 is discharged downward into the guide tube 40 because the discharge channel 11 penetrates toward the innermost guide tube 40. While the water is lowered and exits to the water collecting passage 22 in the center of the lower fixing plate 20, the water flowing into the discharge channel 21 of the lower fixing plate 20 is the water collecting channel 22 described above. ) Is directly connected, so it will exit.

At this time, since the separate collecting container is fastened to the water collecting passage 22 as in the prior art, water collected in the collecting container can be stored, and the lower end of the collecting container can be used by installing a drain valve as in the prior art. .

As described above, the gas which has repeatedly rotated in a zigzag shape in the up-and-down zigzag form moves along the outermost flow paths 41 and 41 ', so that the moisture is sufficiently removed. It is discharged to the outside through the discharge port 31 formed in the outer cylinder 30 to form the flow path 41 (41 ').

At this time, the discharge port 31 can be used to install a variety of air tools using an air pipe, etc., because it is not discharged at all even during the process such as spray coating can maintain a stable quality.

Particularly, the collecting parts 43 and 43 'formed on the inner wall of the guide pipe 40 and 40' can remove and collect the water droplets more effectively, and the collecting part 43 ( 43 ') is manufactured in the form of a spiral groove from the inner wall of the guide tubes 40 and 40', or in the form of a protrusion as shown in FIG. 6, and as the gas is circulated in a spiral form, water droplets in the gas are caused by centrifugal force. The water droplets that hit the inner wall of the guide pipes 40 and 40 'and are pushed out by the centrifugal force interfere with the water collecting portions 43 and 43', and have a groove shape or a protrusion water collecting portion ( 43) (43 ') more effectively along the surface.

At this time, the air, that is, the gas has relatively less interference with the water collecting parts 43 and 43 'than the water droplets, and thus does not interfere with the circulation of the gas, while the water droplets under the centrifugal force to be bounced outward are collected as described above. 43) (43 ') is directly interfering with the water, so the effect of collecting water droplets is further increased.

Accordingly, the inventive water separation device moves up and down in a zigzag form and repeatedly has a spiral vortex flow, thereby quickly and quickly removing water or water droplets in the gas and effectively removing even small particulate water droplets. It is possible to minimize various wastes and problems caused by the moisture.

In particular, the inventive water separation device is to be able to have a more excellent feature by varying the number of the guide tubes 40, 40 'in the interior according to the capacity of the compressor, when the capacity is small and low pressure the guide tube While reducing the number of (40) (40 '), while the capacity is large and relatively high pressure, the outer cylinder 30 is designed to be large and the number of guide tubes (40) and (40') therein can be increased to more effectively separate the water. It can be done.

1 is a cross-sectional view of a conventional water separator for a conventional air compressor.

2 is an exploded perspective view of a water separator for an air compressor according to the present invention

3 is an exploded cross-sectional view of the water separator for an air compressor according to the present invention.

4 is a cross-sectional view of the water separator for air compressor according to the present invention

5a to 5d is a step-by-step operation of the water separator for air compressor according to the present invention,

Figure 5a is a cross-sectional view of the initial flow state from the inlet

FIG. 5B is a sectional view of a state where the process proceeds to the next step from the state of FIG. 5A

FIG. 5C is a sectional view of a state where the process proceeds to the next step from the state of FIG. 5B

5D is a cross-sectional view of the state in which water is discharged and removed

6 is another embodiment of a water separator for an air compressor according to the present invention

Explanation of symbols on the main parts of the drawings

10: upper fixing plate 11: drainage

12 inlet 13 inlet

20: lower fixing plate 21: discharge passage

22: catchment

30: outer cylinder 31: outlet

40,40 ': Director 41,41': Euro

42,42 ': Aerator 43,43': Water catcher

50,50 ': Vortex derivative 51,51': Vortex ball

60: spiral conductor 61: spiral groove

Claims (7)

An outer cylinder 30 is formed to be coupled between the upper fixing plate 10 and the lower fixing plate 20, and the guide tubes 40 and 40 ′ having different diameters are formed at the same center inside the outer cylinder 30. Inserted so that the flow paths 41 and 41 'are formed between guide tubes 40 and 40' inside and outside, respectively. The gas flowing from the side of the upper fixing plate 10 is moved along the plurality of flow paths 41 and 41 'in an up and down zigzag form, and moves on the flow paths 41 and 41' which are the movement paths of the gas. Vortex inductors 50 and 50 'are formed to circulate in a spiral direction, and discharge channels 11 and 21 are formed at upper and lower ends of the flow paths 41 and 41', The moisture-depleted gas is provided to the outside through the discharge port 31, and the water collected into the discharge channels 11 and 21 along the inner wall of the guide pipes 40 and 40 'is fixed to the lower fixing plate 20. Water separator for the air compressor, characterized in that configured to be discharged to the central collecting channel (22). The method of claim 1, The upper fixing plate 10 is formed in the transverse inlet 12 and the inlet passage 13, and the end of the inlet passage 13 is in communication with the tip of the innermost guide pipe 40, At the tip of the innermost guide tube 40, a spiral conductor 60 having a spiral groove 61 is formed on the outer surface so that the high-pressure gas discharged from the inflow path 13 is along the spiral groove 61. Water guide device for an air compressor, characterized in that configured to be rotated in a spiral form toward the inner guide tube 40 inside the lower side. The method of claim 1, The upper fixing plate 10 and the lower fixing plate 20 are formed with discharge channels 11 and 21 in the transverse direction, respectively, and the inflow side ends of these discharge channels 11 and 21 are flow paths 41 and 41 '. Communicate with, The discharge channel 11 of the upper fixing plate 10 is in communication with the interior of the innermost guide tube 40, the discharge channel 21 of the lower fixing plate 20 is characterized in that it is configured to communicate with the collecting channel 22 Water separator for air compressor. The method of claim 1, The vortex inductors 50 and 50 'are provided with radially forming vortex holes 51 and 51' in a planar curved shape, and the inner ends of the vortex holes 51 and 51 'are guide tubes 40 ( And the other end of the vortex holes 51 and 51 'to face the flow paths 41 and 41' so as to be connected to the vent holes 42 and 42 'formed in the 40'. The gas provided from the vent holes 42 and 42 'of the 40' is rotated and discharged into the flow passages 41 and 41 'in a spiral form through the vortex holes 51 and 51'. Water separator for air compressor. The method of claim 1, The inner wall of the guide tube (40) (40 ') is a water separation device for an air compressor, characterized in that formed by forming a spiral collecting portion (43) (43') radially. The method of claim 5, Water collecting unit (43) (43 ') is a water separation device for an air compressor, characterized in that configured to protrude from the inner wall of the guide tube 40, 40' in the up and down direction. The method of claim 5, The water collecting parts 43 and 43 'are recessed around the upper and lower parts of the inner wall surfaces of the guide pipes 40 and 40' so as to be guided upward and downward from the inner walls of the guide pipes 40 and 40 '. Water separator for an air compressor, characterized in that formed by forming.

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