KR101297923B1 - Automatic drainage of concentrated water - Google Patents

Abstract

PURPOSE: An apparatus for automatically discharging condensate is provided to be automatically discharge condensate generated from an air compressor, and a discharge port is easily cleaned. CONSTITUTION: An apparatus for automatically discharging condensate comprises a first housing (10), a second housing (20), a condensate inlet (30), a condensate outlet (40), an air discharge port (50), an air path (60), a condensate discharging device (70), and an air device (80). The first and second housings are formed in a cylindrical shape. The condensate inlet allows the condensate to travel to the first housing. The condensate outlet discharges the condensate to the second housing. The air discharge port discharges air in the second housing to the outside. The air travels in the air path. The condensate discharging device automatically discharges the condensate to the outside. The air device opens and closes the air discharge port.

Description

Automatic drainage of concentrated water

The present invention relates to an automatic discharge device for condensate, and more particularly, to automatically discharge the condensate generated inside the air compressor to the outside by buoyancy, and to clean the discharge port by the foreign matter. The present invention relates to an automatic condensate drainage device that can be easily cleaned through.

In general, the compressed air generated from the air compressor includes moisture in the compressed air due to various factors such as heat caused by the operation of the compressor and air introduced from the outside. Such moisture causes problems such as corrosion by moisture in the inside, and the moisture inside the discharged compressed air causes corrosion and malfunction of the equipment using the compressed air, and thus, it is required to remove moisture generated from the air compressor.

However, the conventional condensate discharge device, there is a problem that damage to the equipment occurs if the management of the condensate by continuously operating by the user to remove the condensed water in the storage tank stored compressed air. In addition, when a phenomenon in which the outlet port is blocked by a foreign matter inside the storage tank, there is a problem in that the foreign material must be removed after stopping the operation of the air compressor.

In addition, the compressor used in the precision industry or medical industry, such as a semiconductor production plant, there is a problem that the precision device is directly damaged by the condensed water sprayed with the high pressure air.

In this regard, the technology for the condensate discharge structure of the drain unit for the air compressor installation is disclosed as Korea Patent Publication No. 10-2006-0094558, but is installed on the bottom of the storage tank generated by the air compressor to operate the user Since the condensate is to be discharged by the need for continuous management of the condensate. In addition, when a phenomenon in which the outlet port is blocked by a foreign matter inside the storage tank, there is a problem in that the foreign material must be removed after stopping the operation of the air compressor.

Republic of Korea Patent Publication No. 10-2006-0094558 (2006.08.30.)

The present invention has been made in order to solve the above problems, an air compressor or a condensate discharge device for automatically discharging the condensate generated by the air compressor to the outside provided on the track to move the compressed air generated by the air compressor The purpose is to provide.

In addition, another object of the present invention is to provide a condensate discharge device capable of cleaning the condensate outlet by a simple operation of a user with foreign substances in the condensate outlet.

The problems to be solved by the present invention are not limited to the above-mentioned problems, and other problems to be solved by the present invention, which are not mentioned here, can be clarified to those skilled in the art from the following description It can be understood.

Condensate discharge device according to the invention, the lower end is open, is formed in a cylindrical shape having a space therein, the first housing is provided with a first fastener on one side of the lower end, the upper end is open, having a space therein A second housing formed in a cylindrical shape and having a second fastener fastened to the first fastener on one side of the upper end; and provided on an upper end of the first housing, and a condensate inlet through which condensed water flows into the first housing; And a condensate outlet configured to penetrate from an inner lower end to an outer side of the second housing to discharge the condensed water stored inside the second housing to the outside of the second housing, and provided at a side of the second housing. An air outlet having a through hole formed therein so as to discharge the air stored therein, and formed in the second housing structure, and at the condensate outlet An air movement passage having a flow path through which air moves to the air outlet, and a side of the condensate outlet formed inside the second housing, and automatically discharge the condensate stored in the first housing and the second housing to the outside; And an air opening and closing device provided at the air outlet and enabling the user to open and close the air outlet by a user's operation, wherein the condensate discharge device is provided at one side of the condensate outlet formed inside the second housing. Is provided, the fastener is formed to protrude in the inner direction of the second housing, one side is fastened rotatably with the fastener, the lower end is a lever and the lower end is formed with a first stopper for opening and closing the condensate outlet is fastened with the lever And a float that stores air therein to generate buoyancy depending on the level of condensate. Characterized in that the open configuration.

The air opening and closing device includes a shaft provided through the air discharge port, a second stopper provided at an end of the shaft inserted into the second housing, and restraining the discharge of air stored in the second housing; The shaft is provided on the axis line and is formed to surround a third stopper for restraining the discharge of air moving through the air movement flow path, and the shaft protruding outward of the second housing, and the pressure is generated by a user's operation. A cap which moves inwardly of the second housing, an end of the cap and an outer side of the second housing, an elastic body that provides an elastic force in the second housing outer direction, and a side of the second housing; It characterized in that it comprises a guide for guiding the movement of the air opening and closing device.

A first flow path for storing an antifreeze is formed in an outer wall forming the first housing, and a second flow path for storing an antifreeze is formed in an outer wall for forming the second housing, and the first housing and the second housing are formed. The first and second fasteners are fastened by the first fastener and the second fastener, and the first flow path and the second flow path are formed in a waste flow path.

On the outer surface of the first housing and the second housing, a polygonal nut is formed at one side of the condensate inlet and the condensate outlet to be joined to the first housing and the second housing to fasten the first housing and the second housing. This can be facilitated.

The depth of the first housing and the second housing, the second housing is formed shorter than the first housing, it is easy to repair the condensate discharge device and the air opening and closing device provided inside the second housing It is done.

By the means for solving the above problems, the condensate discharge device of the present invention, the air compressor or the compressed air generated by the air compressor is provided on the line to move the effect of automatically discharging the condensate generated by the air compressor to the outside There is.

In addition, there is an effect that can clean the condensate outlet with a simple operation of the user of the foreign matter of the condensate outlet.

1 is a side cross-sectional view showing an automatic condensate discharge device according to the present invention.
Figure 2 is a detailed view of the condensate discharge device and the air opening and closing device of the automatic condensate discharge device according to the present invention.

The above and other objects, features and advantages of the present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG. BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention and the manner of achieving them will become apparent by reference to an embodiment which will be described in detail below with reference to the accompanying drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in more detail with reference to the accompanying drawings.

As shown in FIG. 1, the condensate discharge device of the present invention has a cylindrical first housing 10 having a lower end and a space therein, and a cylindrical second housing having an upper end and a space therein. 20, a condensate inlet 30 provided at one side of the first housing 10, a condensate outlet 40 provided at one side of the second housing 20, and a side surface of the second housing 20. An air discharge port 50 provided to discharge air to the outside, and formed inside the second housing 20 structure, and formed from the condensate discharge port 40 to the air discharge port 50; It is configured to include a condensate discharge device 70 provided on one side of the condensate discharge port 40 to discharge the condensate to the outside.

First, the first housing 10 is provided in the condensate discharge device of the present invention. The first housing 10 is formed in a cylindrical shape having a lower end and having a space therein. That is, the first housing 10 forms a space for storing the condensed water contained in the compressed air.

The first fastener 12 is provided at one side of the first housing 10. The first fastener 12 is provided on one side of the lower end of the first housing 10 to serve to fasten with the second fastener 22 to be described below.

In the condensate discharge device of the present invention, a second housing 20 is provided. The second housing 20 is formed in a cylindrical shape having an upper end and having a space therein. That is, the second housing 20 forms a space for storing the condensed water contained in the compressed air in the same manner as the first housing 10.

A second fastener 22 is provided at one side of the second housing 20. The second fastener 22 is provided at an upper end side of the second housing 20 and fastened to the first fastener 12.

That is, the first housing 10 and the second housing 20 are coupled by the first fastener 12 and the second fastener 22 provided at one side, and can store condensed water therein. It consists of a cylinder with a space formed. In addition, the first fastener 12 and the second fastener 22 can withstand the pressure of the compressed air stored by the first housing 10 and the second housing 20, and the condensed water stored To close tightly to prevent leakage.

The condensate inlet 30 is provided at an upper end of the first housing 10. The condensate inlet 30 serves to allow the condensed water contained in the compressed air to flow into the first housing 10. That is, the condensate inlet 30 is formed to penetrate from an upper end to an inner upper end of the first housing 10 to serve to introduce condensate into the first housing 10.

An air outlet 50 is provided at the side of the second housing 20. The air discharge port 50 is formed as a through hole to discharge the air stored in the second housing 20 to the outside. That is, the air discharge port 50 discharges the compressed air stored in the first housing 10 and the second housing to the outside of the second housing 20, and at the same time, the air movement passage to be described below. Providing air to move the 60.

An air movement passage 60 is provided inside the second housing 20 structure. The air flow passage 60 is provided in the second housing 20 structure, and is formed as a flow path through which air can move from the condensate outlet 40 to the air outlet 50. That is, the compressed air flow path 60, when the compressed air stored in the second housing 20 is discharged by the air outlet 50, some of the compressed air through the air flow path (60) Will move. This serves to remove foreign matters by the pressure of the compressed air moving through the air flow passage 60 to the foreign matters accumulated in the condensate outlet 40.

Inside the second housing 20, a condensate discharge device 70 is provided. The condensate discharge device 70 is provided at one side of the condensate discharge port 40 formed inside the second housing 20 to automatically discharge the condensate stored in the second housing 20 to the outside. do. That is, the condensate discharge device 70 automatically stores or discharges the condensate according to the level of the condensate stored in the first housing 10 and the second housing.

The condensate discharge device 70 includes a fixture 72 formed inside the second housing 20, a float 78 for generating buoyancy, and a lever 74 for opening the condensate discharge port 40. It is configured to include.

First, the fastener 72 is provided in the condensate discharge device 70. The fixture 72 is provided on one side of the condensate outlet 40 formed inside the second housing 20, and protrudes in the second housing 20 inward. That is, the fastener 72 serves to fasten the lever 74 to be described below rotatably.

In addition, the condensate discharge device 70 is provided with a lever 74. One side of the lever 74 is rotatably fastened to the fixture 72, and a lower end of the lever 74 is provided with a first stopper 76 to open and close the condensate outlet 40. That is, the lever 74 is moved up and down in accordance with the level of the condensate by the float 78, which will be described below. When the level of the condensate is increased, the lever 74 is moved upward to the condensate outlet ( When opening 40 and the level of condensate is lowered, the lever 74 moves downward to close the condensate outlet 40 by the first stopper 76.

In addition, a float 78 is provided in the condensate discharge device 70. The float 78 has a lower end coupled to the lever 74 and serves to generate buoyancy according to the level of condensate by storing air therein. That is, the float 78 generates a buoyancy force to move the lever 74 in the up and down direction according to the level of the condensate stored in the first housing 10 and the second housing 20. This, when the water level of the condensate is high buoyancy is generated by the float 78 serves to automatically discharge the condensate stored in the first housing 10 and the second housing 20 to the outside. do.

The air opening and closing device 80 may include a shaft 81 provided through the air discharge port 50 and a second stopper for opening and closing the air discharge port 50 formed inside the second housing 20. 82), a third stopper 83 for opening and closing the air outlet 50 formed inside the air movement passage 60, and the shaft 81 protruding outside the second housing 20; A cap 84 to be formed, an elastic body 85 provided between the end of the cap 84 and the outside of the second housing 20, and a guide 86 provided on one side of the second housing 20. It is configured to include.

First, the air opening and closing device 80, the shaft 81 is provided. The shaft 81 is provided to penetrate through the air outlet 50, and is driven by the cap 84 and the elastic body 85 to be described below.

In addition, the air opening and closing device 80 is provided with a second stopper 82. The second stopper 82 is provided at the end of the shaft 81 inserted into the second housing 20 to restrain the discharge of air stored in the second housing 20. That is, the second plug 82 slides together with the shaft 81 and serves to open and close the air outlet 50 formed inside the second housing 20. This serves to move the air inside the second housing 20 to the outside of the air flow passage 60 or the air outlet 50.

In addition, the air opening and closing device 80 is provided with a third stopper 83. The third stopper 83 is provided on the axis 81 to restrain the discharge of the air moving through the air movement passage 60. That is, the third stopper 83 slides together with the shaft 81 and serves to open and close the air outlet 50 formed on the air movement passage 60.

In addition, the air opening and closing device 80 is provided with a cap 84. The cap 84 is formed to surround the shaft 81 protruding to the outside of the second housing 20, and enables sliding of the shaft 81 with a pressure generated by a user's operation. That is, the cap 84 moves the shaft 81 inward to the second housing 20 by the pressure generated by the user's operation, and the second stopper 82 formed on the shaft 81. ) And the third stopper 83 also moves together with the shaft 81 to open the air outlet 50.

In addition, the air opening and closing device 80 is provided with an elastic body 85. The elastic body 85 is provided between the end of the cap 84 and the outer side of the second housing 20, and provides an elastic force in the outer direction of the second housing 20 to drive the shaft 81 in a sliding manner. It plays a role in making it possible. That is, when the elastic body 85 removes the pressure acting on the cap 84, the elastic body 85 moves the shaft 81 to the outer side of the second housing 20 by the elastic body 85. The second outlet 82 and the third plug 83 serves to close the air outlet 50.

In addition, the air opening and closing device 80 is provided with a guide 86. The guide 86 is provided on one side of the second housing 20 to guide the movement of the air opening and closing device 80. That is, the guide 86 serves to guide the movement of the shaft 81 and the cap 84.

In addition, the air opening and closing device 80, the compressed air by the simple operation of the air opening and closing device 80 to remove the foreign matter accumulated in the condensate outlet 40 as described above the air movement passage 60 By moving to the condensate outlet 40 through the foreign matter accumulated in the condensate outlet 40 can be removed. In addition, the air opening and closing device 80 serves to prevent damage to the equipment by discharging the compressed air stored in the storage tank to the outside when the air compressor is not in use.

The first flow path 14 and the second flow path 24 are provided on the outer wall forming the first housing 10 and the second housing 20. The first flow passage 14 and the second flow passage 24 are provided at the center of the outer wall forming the first housing 10 and the second housing 20, and the antifreeze is stored therein. That is, in the first flow passage 14 and the second flow passage 24, the first housing 10 and the second housing 20 are connected to the first fastener 12 and the second fastener 22. The first flow path 14 and the second flow path 24 are fastened to form a waste flow path to store the antifreeze. This serves to prevent the condensed water stored by the antifreeze stored in the first flow passage 14 and the second flow passage 24 from being frozen by the low temperature.

Nuts 90 are formed on the outer surfaces of the first housing 10 and the second housing 20. The nut 90 may include the first housing 10 and the second housing at one side of the condensate inlet 30 and the condensate outlet 40 formed on the outer surfaces of the first housing 10 and the second housing 20. It is bonded with 20 to form a polygonal shape. That is, when the nut 90 fastens the first housing 10 and the second housing 20 by the first fastener 12 and the second fastener 22, the nut 90 is easily fastened. It plays a role.

In addition, the inner depth of the first housing 10 and the second housing 20 is shorter than that of the first housing 10. This is because the inner depth of the second housing 20 is shorter than that of the first housing 10 so that the condensate discharge device 70 and the air opening / closing device 80 provided inside the second housing 20. It serves to facilitate the repair.

In addition, the present invention automatic condensate discharge device is provided on the transport line for transporting the compressed air in addition to the storage tank for storing the compressed air serves to automatically discharge the condensate contained in the compressed ball.

As described above, it is to be understood that the technical structure of the present invention can be embodied in other specific forms without departing from the spirit and essential characteristics of the present invention.

Therefore, it should be understood that the above-described embodiments are to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than the foregoing description, All changes or modifications that come within the scope of the equivalent concept are to be construed as being included within the scope of the present invention.

10: first housing 12: first fastener
14: first flow path 20: second housing
22: 2nd fastener 24: 2nd flow path
30: condensate inlet 40: condensate outlet
50: air outlet 60: air flow path
70: condensate discharge device 72: fixture
74: lever 76: the first stopper
78: float 80: air opening and closing device
81: axis 82: second stopper
83: third stopper 84: cap
85: elastic 86: guide
90: nut

Claims (5)

A first housing having a lower end and a cylindrical shape having a space therein, wherein a first fastener is provided at one side of the lower end;
A second housing having an upper end opened and formed in a cylindrical shape having a space therein, and having a second fastener fastened to the first fastener on one side of the upper end;
A condensate inlet provided at an upper end of the first housing and allowing condensed water to flow into the first housing;
A condensate outlet formed through the inner bottom of the second housing to the outside and discharging the condensed water stored inside the second housing to the outside of the second housing;
An air outlet provided on a side of the second housing and having a through hole formed therein to discharge the air stored in the second housing to the outside;
An air movement passage formed in the second housing structure and having a flow path through which air moves from the condensate outlet to the air outlet;
A condensate discharge device provided at one side of the condensate discharge port formed inside the second housing and configured to automatically discharge the condensate stored in the first housing and the second housing to the outside;
Included in the air outlet, the air opening and closing device for opening and closing the air outlet by the user's operation;
The condensate discharge device,
A fixture provided on one side of the condensate outlet formed inside the second housing and protruding in the second housing inner direction;
One side is rotatably coupled to the fixture, the lower end of the lever is formed with a first stopper for opening and closing the condensate outlet; And
The bottom is fastened to the lever, the air is stored therein float to generate buoyancy according to the level of condensate;
Condensate discharge device characterized in that it comprises a. The method of claim 1,
The air opening and closing device,
A shaft provided through the air outlet;
A second stopper provided at an end of the shaft inserted into the second housing and configured to restrict discharge of air stored in the second housing;
A third stopper provided on the axis line and configured to restrict discharge of air moving through the air movement passage;
A cap formed to surround the shaft protruding to the outside of the second housing and moving the shaft inward to the second housing with a pressure generated by a user's operation;
An elastic body provided between an end of the cap and an outer side of the second housing and providing an elastic force in an outer direction of the second housing; And
Is provided on one side of the second housing, the guide for guiding the movement of the air opening and closing device;
Condensate automatic discharge device, characterized in that comprising a. The method of claim 1,
On the outer wall forming the first housing, a first flow path for storing the antifreeze is formed,
A second flow path for storing an antifreeze is formed on an outer wall forming the second housing,
The first and second housings are fastened by the first fastener and the second fastener so that the first flow path and the second flow path is formed in the shape of a waste flow path to automatically store the condensate, characterized in that for storing the antifreeze . The method of claim 1,
On the outer surface of the first housing and the second housing,
A polygonal nut is formed at one side of the condensate inlet and the condensate outlet to be joined to the first housing and the second housing to facilitate fastening of the first and second housings. Ejector. The method of claim 1,
Depth of the first housing and the second housing,
The second housing is shorter than the first housing, the condensate automatic discharge device, characterized in that to facilitate the repair of the condensate discharge device and the air opening and closing device provided in the second housing.

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