KR102104128B1 - Compressed air separator to remove condensate water within - Google Patents

Abstract

The present invention relates to a device for removing condensed water for compressed air, an inlet provided on one side of the body portion 100 so that compressed air is introduced into the body portion 100 provided with an internal space and the body portion 100 ( 200), the separation plate 300 provided in the inner space of the body portion 100 so that the compressed air introduced into the inlet 200 collides and the condensed water is separated, and the body portion so that the compressed air separated from the condensed water is drawn out. The discharge port 400 provided at the top of the (100) and the drain 500 coupled to the lower portion of the body part 100 while being spaced apart from the discharge port 400 so that condensed water separated from the compressed air is discharged regularly Phosphorus filter replacement is unnecessary, condensate removal performance is prevented due to clogging of the filter, it can be used semi-permanently, and no additional power supply is required. The cleaning ratio than the air condensate removal apparatus relates to a condensate removal device for the possible removal of the condensed water separation, high-performance 95% to 99% of the compressed air.

Description

COMPRESSED AIR SEPARATOR TO REMOVE CONDENSATE WATER WITHIN}

The present invention relates to a device for filtering clean air by removing condensate from compressed air, and more particularly, to a device for removing condensate for compressed air using a filterless method.

The condensate removal device for compressed air, which is mainly used in the prior art, is a filter element type condensate removal device for compressed air such as an air filter or a line filter, and includes water vapor and water contained in the compressed air. In order to remove, a filter element composed of a microporous portion is used, and when compressed air passes through the filter element, moisture is trapped in the micro hole of the filter element, and thus is collected. The filter element type condensate removing device for compressed air has an effect of removing moisture, but also has the following performance degradation and maintenance problems.

First, in the conventional filter element type, when used for a certain period of time, foreign substances are collected in the filter grains, and the pressure loss increases, thereby decreasing the initial performance of condensate removal. In other words, the conventional filter element type is formed of a microporous structure such as a non-woven fabric, so that clogging of foreign substances due to dust or bacterial propagation inevitably occurs, initially exhibits normal performance, but as the time hardens, The clogging progresses, and as the clogging progresses, the cross-sectional area of the compressed air decreases, making it difficult for the compressed air to pass. Accordingly, the compressed air passes through the saturated state of the condensed water, resulting in a problem that the cleanliness rate is significantly lowered.

Due to the clogging phenomenon, regular replacement of the filter element type is inevitably involved. That is, when the pressure difference between the front end and the rear end of the filter element becomes larger than a certain amount, the filter element must be replaced frequently when compressed air with high cleanliness rate is required. As a result, the cost of parts and work are increased. There is.

In addition, there is a problem in that the installation cost is increased and the installation space is large, which is disadvantageous in terms of maintenance, such as the need to install a pressure gauge in order to grasp the exact replacement time, and to grasp the pressure difference of compressed air.

On the other hand, another foreign matter contained in the compressed air is a part of the compressor lubricating oil contained in the compressed air to flow out, there is also a problem that the cleanliness rate is lowered due to the clogging phenomenon as described above.

After all, in removing condensate, such as moisture or oil, contained in compressed air, there is no need to use a filter element, and it is required to separate and remove condensed water with high performance and excellent cleanliness.

In order to solve the above problems, regular filter replacement is unnecessary by not using a conventional filter-type condensate removal device for compressed air, and the degradation of condensate removal performance due to clogging of the filter is prevented and can be used semi-permanently. Therefore, maintenance is unnecessary, and no separate power supply is required. Therefore, the purpose of the present invention is to provide a condensate removal device for compressed air capable of separating and removing high-performance condensate with high cleanliness (or filtration rate) while reducing costs in terms of maintenance. There is this.

In order to achieve the above object, the condensed water removal device for compressed air according to the present invention includes a body portion 100 provided with an internal space; An inlet 200 provided on one side of the body portion 100 so that compressed air is introduced into the body portion 100; A separation plate 300 provided in the inner space of the body part 100 so that condensed water is separated by collision of compressed air introduced into the inlet 200; A discharge port 400 provided on the upper portion of the body portion 100 so that compressed air from which condensed water is separated is drawn out; And a drain 500 coupled to the lower portion of the body portion 100 while being separated from the discharge port 400 so that condensed water separated from the compressed air is discharged.

In addition, the separation plate 300 is provided as a first separation plate 310 and a second separation plate 320, wherein the first separation plate 310 is the body portion 100 so that the introduced compressed air collides It is provided on the vertical surface of the interior space, the second separation plate 320 is provided on the horizontal surface of the interior space of the body portion 100, the compressed air collided in the first separation plate 310 is raised to re-collide It is characterized by.

In addition, the first separation plate 310 is characterized in that it is formed inclined from the vertical surface of the interior space.

In addition, the first separation plate 310 has a spiral groove portion 311 is formed is characterized in that the introduced compressed air is induced upward in a spiral form.

In addition, the spiral groove portion 311 is formed such that the first spiral groove portion 311a is continuous, and the second spiral groove portion 311b is further partially or continuously formed between vertical intervals of the first spiral groove portion 311a. It is characterized by.

In addition, the first separation plate 310 has a curved guide plate 312 integral with the first separation plate so that compressed air drawn into the inlet 200 rotates along the first separation plate 310 immediately upon entering. It is characterized by being formed of.

In addition, the second separation plate 320 is provided with a collision surface 321 formed to protrude downward, and a first air hole H1 is provided on an inclined surface 322 at the edge of the collision surface to provide the collision surface 321 It is characterized in that the compressed air is separated from the collision is moved to the edge and is drawn out to the discharge port (400).

In addition, a locking protrusion 323 is formed on the outermost side of the second separation plate 320 so that the second separation plate 320 is coupled to an upper portion of the inner space of the body portion 100.

In addition, a third separation plate 330 is coupled to an upper side of the second separation plate 320, and a second air hole H2 is provided at the center of the third separation plate 330, and the second air A collision surface 331 is formed around the hole H2, and a horizontal surface 332 is provided on the outermost side of the third separation plate 330 to be seated on the horizontal support surface 324 of the second separation plate 320. It is characterized by being.

In addition, a fourth separation plate 340 is further coupled to an upper side of the third separation plate 330, and a support surface 341 is formed to protrude downward from the center of the fourth separation plate 340, wherein A third air hole (H3) is provided on one side of the support surface 341, and the lower end of the support surface 341 is seated on the fixing groove 333 of the third separation plate 330.

In addition, the discharge port 400 is provided on the upper portion of the body portion 100 is provided on the vertical surface of the interior space of the body portion 100, extending from the discharge port 400 to the interior space of the body portion 100 It is characterized in that the condensed water is discharged through the formed pipeline and the fifth air hole 420 provided on the pipeline.

By the above solution, regular filter replacement, which is a problem of the conventional filter-type compressed air condensate removal apparatus, is unnecessary, and the degradation of condensate removal performance due to clogging of the filter is prevented and can be used semi-permanently. There is also an advantage in that the reduction of cost in maintenance is remarkable because power supply is not required.

In addition, compared to a conventional condensate removal device for compressed air, there is an advantage in that high-performance condensate separation and removal with a clean rate (or filtration rate) of 95 to 99% is possible.

Further, by providing the second to fourth separation plates 320, 330, and 340, the compressed air collided by the first separation plate 310 is collided again, and the first separation plate 310 completely There is an advantage of purifying compressed air by separating and discharging the remaining water or oil that cannot be removed.

In addition, the first separation plate 310 is provided with a guide plate 312, so that compressed air forms a vortex by high-speed rotation or cyclone immediately upon entering, and at the same time, uniformly and stably with the first separation plate 310. Conditions for conflict may be provided.

In addition, since the first separation plate 310 is formed to be inclined, the centrifugation is more effectively caused by high-speed rotation or cyclone, while the rise of the compressed air can be smoothly performed.

In addition, since the spiral groove portion 311 is formed in the first separation plate 310, the introduced compressed air has an advantage that can be induced to rise in a spiral form.

Figure 1 shows a front view according to an embodiment of the condensate removal device for compressed air of the present invention.
FIG. 2 is a sectional view of a part of the condensate removal device for compressed air shown in FIG. 1.
FIG. 3 is an enlarged part of a condensate removal device for compressed air shown in FIG. 2.
4 is a cross-sectional view taken along line A-A 'in FIG. 3.
5 is an exploded cross-sectional view of the condensate removal device for compressed air shown in FIG.
FIG. 6 is an exploded perspective view of the second to fourth separator plates of the compressed air condensate removal apparatus shown in FIG. 1.
7 (a) to 7 (b) are explanatory diagrams showing the state of condensate separated from the flow of compressed air in the condensate removal device for compressed air shown in FIG.

The example of the condensate removal apparatus 10 for compressed air according to the present invention can be variously applied, and the most preferred embodiment will be described below with reference to the accompanying drawings.

1 shows a front view according to an embodiment of the condensate removal apparatus 10 for compressed air, which is the present invention, and FIG. 2 shows a cross-sectional view of a part of the condensate removal apparatus 10 for compressed air.

Referring to this, the condensed water removal device 10 for compressed air according to the present invention is provided on one side of the body part 100 so that compressed air is introduced into the body part 100 provided with an internal space and the body part 100. The inlet 200 is provided, the separation plate 300 provided in the inner space of the body portion 100 so that the compressed air introduced into the inlet 200 collides and the condensed water is separated, and the compressed air from which the condensed water is separated is drawn out. The discharge port 400 provided on the upper portion of the body portion 100 to be possible; And a drain 500 spaced apart from the discharge port 400 so as to discharge condensed water separated from the compressed air and coupled to the lower portion of the body portion 100.

Looking specifically, the body portion 100 is composed of a housing 110 having an inlet 200 on one side and a cap 120 coupled to an upper portion of the housing 110. A bolt portion 112 may be formed on an upper outer side of the housing 110 to be screwed with a nut portion 122 formed on the lower inner side of the cap 120 (see FIG. 5). Accordingly, an internal space may be provided in the body portion 100.

In addition, the inlet 200 provided on one side of the body portion 100 may be formed with a screw portion 210 so that the compressed air inlet pipe 11 is screwed. Thus, after the compressed air containing moisture or oil, etc. passes through the compressed hole 220 of the inlet 200 through the compressed air inlet pipe 11, it may be introduced into the body portion 100. .

3 is an enlarged cross-sectional view of a part of the condensate removal device 10 for compressed air, and FIG. 4 shows a cross-sectional view of the condensate removal device 10 for compressed air along the line A-A '.

Here, a separation plate 300 is provided in the inner space of the body portion 100, and the separation plate 300 is composed of a first separation plate 310 and a second separation plate 320. The first separation plate 310 is provided on the vertical surface of the inner space of the body portion 100 so that the compressed air introduced therein, the second separation plate 320 is a horizontal surface of the inner space of the body portion 100 It is provided in the first separation plate 310 may be re-collided by the impact of the compressed air rises.

Specifically, the first separation plate 310 is formed in a cylindrical shape in contact with the compressed air, so that the compressed air introduced through the inlet 200 causes high-speed rotation or cyclone. Accordingly, compressed air is subjected to centrifugal force by high-speed rotation or cyclone, and since the specific gravity of the compressed air is about 800 times larger than that of air, a relatively large centrifugal force acts (centrifugal force is proportional to the unit mass). ). As a result, the moisture is rotated relatively outwardly, so that the first separation plate 310, which is the inner circumferential surface of the body portion 100, is uniformly and stably collided or frictiond. Due to this collision or friction, the moisture contained in the compressed air forms water droplets, and consequently, the moisture contained in the compressed air can be separated and discharged by the principle of hydrodynamics such as centrifugal separation and collision separation (see FIG. 7). ).

The oil, which is a foreign substance contained in compressed air, is part of the compressor's lubricating oil and is contained in compressed air. Unlike moisture, most of them exist in the form of oil vapor, but they are also separated simultaneously by centrifugal force due to high-speed rotation. It may be, and may be discharged separately by collision or friction with the first separation plate 310.

Here, the condensed water containing water or oil, etc., is attached to the first separation plate 310 which is the inner circumferential surface of the body part 100, and rotates at a relatively slower speed than compressed air due to viscosity, thereby cohesive each other. When combined, they form larger droplets. As this process is repeated, the water droplet becomes larger, and the centrifugal force acts more greatly. On the contrary, the compressed air has a relatively small specific gravity compared to condensed water, so the centrifugal force is relatively small and spaced apart from the first separation plate 310 so that the body part is separated. By rotating from the inside of the interior space of (100), as the compressed air rises upward, the cleanliness of the compressed air is improved.

In addition, the first separation plate 310 has a curved guide plate 312 integral with the first separation plate so that compressed air drawn into the inlet 200 rotates along the first separation plate 310 immediately upon entering. It can be formed of. That is, the guide plate 312 is spaced apart from the first separation plate 310, which is the inner circumferential surface of the body portion 100, at a predetermined distance, and the compressed air introduced through the inlet 200 is the first separation plate ( It may be formed in a curved shape to rotate along 310. Accordingly, the compressed air forms a vortex by high-speed rotation or cyclone immediately upon entering, and at the same time, conditions for uniformly and stably colliding with the first separation plate 310 are provided.

According to an embodiment of the present invention, the guide plate 312 may be formed to be bent at a predetermined angle (α) at the point where it first collides with compressed air. The angle of the guide plate 312 and the extension part extending from the first separation plate 310 should be an acute angle. Compressed air in contact with the guide plate 312 changes rapidly in the flow direction, at which time pressure loss occurs. The guide configuration for controlling the flow of compressed air is generally such that the compressed air is gently bent (that is, the angle of the bent part forms an obtuse angle) in order to reduce the pressure loss, but in contrast, in the present invention, the compressed air collides By changing the angle of more rapidly, condensate can be more effectively removed using the characteristics of compressed air when the flow direction is changed.

In addition, the first separation plate 310 may be formed to be inclined from the vertical surface of the interior space, and preferably, an inclination within 0 to 10 degrees from the vertical surface may be formed. As a result, the centrifugation is more effectively caused by high-speed rotation or cyclone, while the compressed air can be smoothly raised.

Meanwhile, a spiral groove portion 311 may be formed in the first separation plate 310. Specifically, the spiral groove portion 311 is formed such that the first spiral groove portion 311a is continuous, and the second spiral groove portion 311b is further partially or continuously formed between vertical gaps of the first spiral groove portion 311a. You can.

Accordingly, there is an advantage that the introduced compressed air may be induced to rise in a spiral form. That is, while effectively controlling the flow of compressed air by effectively forming the rotation or cyclone of the compressed air introduced, it has the advantage of inducing that the condensate separated by centrifugation or collision is adhered to the surface of the spiral groove and discharged downward.

Preferably, the second spiral groove portion 311b may be formed by rotating the second spiral groove portion 311b halfway between vertical gaps formed by one rotation of the first spiral groove portion 311a. In addition, it is a matter of course that at least two or more spiral grooves may be formed between vertical gaps formed by the first spiral groove portion 311a being rotated once.

Here, an uneven surface 310a may be formed on the surface of the first separation plate 310 including the spiral groove part 311. Specifically, the protrusion spacing of the uneven surface 310a is preferably formed to be 0.5 to 1 mm in which condensed water is easily adhered. By providing the uneven surface 310a, the effective area where the compressed air introduced collides with the first separation plate 310 increases, so that condensate contained in the compressed air can be separated and discharged more effectively.

Meanwhile, the second separation plate 320 may be horizontally provided on the top of the housing 110. As a result, compressed air that has been collided by the first separation plate 310 is collided again, and is not completely removed from the first separation plate 310, and there is an advantage of further cleaning the compressed air by separating and discharging the remaining moisture or oil. .

FIG. 5 is an exploded cross-sectional view of the condensate removal device 10 for compressed air, and FIG. 6 is an exploded view of the second to fourth separation plates 320, 330, and 340 of the condensate removal device 10 for compressed air. 7 (a) to 7 (b) are explanatory views showing the state of condensate (dashed arrow) separated from the flow (solid arrow) of the compressed air in the condensed water removing device 10 for compressed air. It is.

Specifically, the second separation plate 320 is provided with a collision surface 321 formed to protrude downward, and a first air hole H1 is provided on an inclined surface 322 at the edge of the collision surface. In addition, a locking protrusion 323 may be formed on the outermost side of the second separation plate 320 so that the second separation plate 320 is coupled to the stepped portion 111 formed on the upper end of the housing 110. .

Accordingly, compressed air, which is separated from the collision surface 321 by collision, moves to the edge and is introduced into the first air hole H1.

Here, an uneven surface 320a may be formed on the surface of the collision surface 321 like the first separation plate 310. Specifically, the protrusion spacing of the concave-convex surface 320a is preferably formed to be 0.5 to 1 mm in which condensed water is easily adhered. By providing the concave-convex surface 320a, the effective area where the compressed air introduced collides with the second separation plate 320 increases, so that condensate contained in the compressed air can be separated and discharged more effectively.

Meanwhile, a third separation plate 330 is coupled to an upper side of the second separation plate 320, and a second air hole H2 is provided at the center of the third separation plate 330, and the second air A collision surface 331 is formed around the hole H2, and a horizontal surface 332 is provided on the outermost side of the third separation plate 330 to be seated on the horizontal support surface 324 of the second separation plate 320. It may be provided.

Accordingly, compressed air introduced into the first air hole H1 is collected in the first separation plate 310 by centrifugal force in the inner space partitioned by the second separation plate 320 and the third separation plate 330. As it is formed, separation phenomena such as moisture or oil are generated on the same principle. Accordingly, there is an advantage in that compressed air is further cleaned by supplementally separating and discharging the remaining water or oil that is not completely removed from the first separation plate 310 or the second separation plate 320. Thereafter, the compressed air is introduced into the second air hole (H2).

5 to 6, a fourth separation plate 340 is further coupled to an upper side of the third separation plate 330, and a support surface 341 is lower to a central portion of the fourth separation plate 340. It is formed so as to protrude, a third air hole (H3) is provided on one side of the support surface 341, the lower end of the support surface 341 in the fixing groove 333 of the third separation plate 330 Can settle down. An edge surface of the fourth separation plate 340 may be provided with an upper surface 343 formed with a locking portion 342 that can be coupled to a stepped portion 111 formed on the upper end of the housing 110.

As a result, compressed air introduced into the second air hole H2 is collected in the first separation plate 310 by centrifugal force in the inner space partitioned by the third separation plate 330 and the fourth separation plate 340. As it is formed, separation phenomenon such as moisture or oil occurs on the same principle. Accordingly, the first separation plate 310 to the third separation plate 330 is not completely removed, there is an advantage to further clean the compressed air by separating and discharging the remaining moisture or oil. Thereafter, the compressed air passes through the third air hole H3 and is introduced into the fourth air hole H4 formed on the other side of the upper surface 343.

On the other hand, the upper portion of the cap 120 is provided with a discharge port 400, the compressed air from which the condensate is separated and removed may be finally drawn out. A thread portion 410 may be formed inside the discharge port 400 so that the compressed air drawing pipe 12 is screwed. Accordingly, the compressed air clean through the compressed air drawing pipe 12 may be transferred to a device such as an air sprayer (not shown). The discharge port 400 is provided on the upper portion of the body portion 100 may be provided on the vertical surface of the interior space of the body portion 100. In addition, air from which condensate has been removed may be discharged through a pipe line extending from the discharge port 400 to the internal space of the body portion 100 and a fifth air hole 420 provided on the upper portion of the pipeline. . Since the fifth air hole 420 is provided at the upper portion of the pipeline, only gas components included in the compressed air are discharged in the direction of the discharge port 400.

In addition, the drain 500 is provided under the body portion 100. Referring to FIG. 7, water or oil separated by collisions by the first separation plate 310 to the fourth separation plate 340 flows down along the inner circumferential surface of the body portion 100, so that the body portion 100 It is transferred to the drain 500 through the condensate chamber 114 through the discharge hole 113 provided in the lower portion of the interior space. At this time, a convex portion 115 is formed at the lower center of the inner space of the body portion 100 to serve to guide condensate toward the discharge hole 113.

In the drain 500, a guide unit 510 for visually checking the amount of storage of condensate is provided on one side, and a drain valve unit 520 of a manual or automatic type is provided at the bottom to discharge hose (not shown). It is possible to discharge the stored condensate to the outside by connecting.

The apparatus for removing condensate for compressed air according to the present invention has been described above. It will be understood that the technical configuration of this invention can be implemented in other specific forms by those skilled in the art to which the invention pertains without changing its technical spirit or essential features.

Therefore, the above-described embodiments are to be understood in all respects as illustrative and not restrictive.

10: compressed air condensate removal device 11: compressed air inlet pipe
12: compressed air drawing tube 100: body
200: inlet 300: separation plate
310: first separation plate 311: spiral groove
312: guide plate 320: second separation plate
330: third separation plate 340: fourth separation plate
400: outlet 500: drain

Claims (11)

Body portion 100 is provided with an interior space;
An inlet 200 provided on one side of the body portion 100 so that compressed air is introduced into the body portion 100;
A separation plate 300 provided in the inner space of the body part 100 so that condensed water is separated by collision of compressed air introduced into the inlet 200;
A discharge port 400 provided on the upper portion of the body portion 100 so that compressed air from which condensed water is separated is drawn out; And
Includes; drain 500 coupled to the lower portion of the body portion 100 while being spaced apart from the discharge port 400 to discharge the condensate separated from the compressed air;
The separation plate 300 includes a first separation plate 310 and a second separation plate 320,
The first separation plate 310 is provided on a vertical surface of the inner space of the body portion 100 so that the compressed air that is introduced collides, but is inclined to increase in diameter as it goes toward the discharge port 400, and the second separation plate 320 is provided on the horizontal surface of the interior space of the body portion 100, the compressed air collided in the first separation plate 310 rises and re-crashes,
A locking protrusion 323 is formed on the outermost side of the second separation plate 320 so that the second separation plate 320 is coupled to an upper portion of the interior space of the body portion 100,
A third separation plate 330 is coupled to an upper side of the second separation plate 320, and a second air hole H2 is provided at the center of the third separation plate 330, and the second air hole ( A collision surface 331 is formed around the H2), and a horizontal surface 332 is provided on the outermost side of the third separation plate 330 to be seated on the horizontal support surface 324 of the second separation plate 320,
A fourth separation plate 340 is further coupled to an upper side of the third separation plate 330, and a support surface 341 is formed to protrude downward from the center of the fourth separation plate 340, and the support surface A third air hole (H3) is provided on one side of the (341), the lower end of the support surface 341 is seated on the fixing groove 333 of the third separation plate 330,
The discharge port 400 is provided on the upper portion of the body portion 100 is provided on the vertical surface of the interior space of the body portion 100,
The discharged air is discharged through the pipeline extending from the discharge port 400 to the inner space of the body portion 100 and the fifth air hole 420 provided at the upper portion of the pipeline,
On the surface of the first separation plate 310, an uneven surface 310a having a protrusion spacing of 0.5 to 1 mm is formed,
The second separating plate 320 is provided with a collision surface 321 protruding downward, a first air hole H1 is provided on an inclined surface 322 at the edge of the collision surface, and the collision surface 321 The condensed water removal device for compressed air, characterized in that the uneven surface (320a) having a protrusion interval of 0.5 to 1㎜ is also formed on the surface of the.
delete delete According to claim 1,
The first separation plate 310 has a spiral groove portion 311 is formed, the compressed air is introduced condensate removal device for compressed air, characterized in that the induction is induced in a spiral form.
According to claim 4,
The spiral groove portion 311,
The first spiral groove portion 311a is formed to be continuous, and the second spiral groove portion 311b is partially or continuously formed between the vertical intervals of the first spiral groove portion 311a, so that the condensate removing device for compressed air is further formed. .
According to claim 1,
In the first separation plate 310, a curved guide plate 312 is formed integrally with the first separation plate so that compressed air drawn into the inlet 200 rotates along the first separation plate 310 immediately upon entering. Condensate removal device for compressed air, characterized in that.
delete delete delete delete delete

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