KR102052614B1 - Apparatus for discharging air and measuring discharged air - Google Patents

Abstract

The present invention relates to a gas measurement combined discharge device, the present invention is a container having an inlet for the liquid flows in, and an outlet for the liquid flows out; A bubble separation unit provided inside the container and guiding bubbles contained in the liquid flowing into the inlet to the upper side of the container; A valve body coupled to an upper portion of the container and having an exhaust passage; An opening / closing unit for opening and closing the exhaust passage of the valve body; A sensing unit for sensing an amount of gas filled in the upper portion of the container; And a control unit controlling the opening and closing unit according to the detection signal of the detection unit. According to the present invention, it is possible to not only increase the efficiency of discharging bubbles flowing with the liquid in the piping system to the outside, but also to measure the discharge of the bubbles.

Description

Discharge device for combined gas measurement {APPARATUS FOR DISCHARGING AIR AND MEASURING DISCHARGED AIR}

The present invention relates to a gas measurement combined discharge device.

Domestic boilers, thermal power plants, plant equipment, water supply facilities, etc. are equipped with a piping system through which a liquid such as water flows. Domestic boilers, thermal power plants, and plant facilities heat the water in a heating system (boiler) that heats the water and flow it through the piping system, and the water supply facility delivers the purified water to the user through the piping system. Will be supplied.

Meanwhile, in the process of heating water in the heating device that heats water, bubbles are generated by oxygen due to shrinkage and expansion of volume according to the temperature change of water, and bubbles are generated by oxygen, and the air flows through the piping system. When they flow together. In addition, water and oxygen are separated from the pipe connection, expansion, and condensation of the piping system to generate bubbles and the bubbles flow with the water. When water flows through the piping system, bubbles not only generate noise, but also expand the water pressure due to resistance of the water flow caused by the expanded bubbles. In particular, in the case of the plumbing system of the domestic boiler, the heat transfer to the room floor is poor due to the bubbles contained in the water, thereby reducing the heating efficiency.

In Korean Utility Model Utility Model Publication No. 20-0379648 (registered date of March 14, 2005) (hereinafter referred to as prior art), a cylindrical body is connected to a pipe through which water flows, and a buoyancy body is moved up and down inside the body. An air vent device that is coupled to move and discharges bubbles while the buoyancy body moves up and down is disclosed. However, the prior art has a disadvantage in that the bubble is escaped between the inner circumferential surface of the main body and the outer surface of the buoyancy body so that the flow of the bubble is not smooth and the bubbles contained in the water flowing in the pipe is not sufficiently discharged. In addition, the flow path through which the air escapes to the upper portion of the main body is always open, there is a disadvantage that the water flowing into the pipe is leaked through the flow path.

SUMMARY OF THE INVENTION An object of the present invention is to provide a gas measurement combined discharge device that not only increases the efficiency of discharging bubbles flowing together with liquid in the piping system to the outside, but also measures the discharge of bubbles.

In addition, another object of the present invention is to provide a gas measurement combined discharge device for preventing the liquid inside the piping system leaks to the outside with bubbles.

In order to achieve the object of the present invention, there is provided a container having an inlet through which liquid is introduced and an outlet through which the introduced liquid flows out; A bubble separation unit provided inside the container and guiding bubbles contained in the liquid flowing into the inlet to the upper side of the container; A valve body coupled to an upper portion of the container and having an exhaust passage; An opening / closing unit for opening and closing the exhaust passage of the valve body; A sensing unit for sensing an amount of gas filled in the upper portion of the container; Provided is a gas measurement combined discharge device comprising a; control unit for controlling the opening and closing unit according to the detection signal of the detection unit.

The opening and closing unit preferably includes an opening and closing member for opening and closing the exhaust passage, and a solenoid for moving the opening and closing member according to the control of the control unit so that the opening and closing member opens and closes the exhaust passage.

The sensing unit has a sensing rod positioned vertically in the interior of the container, the sensing rod is movable up and down on the sensing rod to move up and down according to the liquid surface inside the container, and the vertical position of the floating body. It is preferable to include a position sensor for detecting a signal to generate a signal to the control unit.

The sensing unit may include a pressure sensor, a reed switch, or a capacitive meter for sensing the gas pressure on the upper portion of the container.

Preferably, the exhaust passage further includes a backflow prevention unit for preventing backflow of external air.

Inlet and outlet of the vessel is preferably connected to the piping of the piping system.

The control unit, it is preferable to measure the discharge of the gas in accordance with the time and the number of times the opening and closing unit opened the exhaust passage.

The present invention is provided with an inlet and an outlet in the container and is provided with a bubble separation unit in the interior of the container, the liquid containing the bubbles are introduced into the container through the inlet, the pressure is lowered and the exposed area of the liquid to the top of the container is widened In addition, by the bubble separation unit, bubbles contained in the liquid are sufficiently separated from the liquid and moved to the upper portion of the container so that only the liquid from which the bubbles are removed is discharged to the outlet of the container. As a result, bubbles are removed from the liquid exiting through the container, thereby preventing noise from being generated while the liquid flows through the piping system, and reducing the flow resistance.

In addition, the present invention when the air of the bubble filled in the upper portion of the container is above the set pressure by the control unit of the opening and closing unit to open the exhaust passage to discharge the air inside the container to the outside, the air inside the container is discharged to the container When the internal pressure is less than the set pressure, the opening and closing unit closes the exhaust flow path by the control of the control unit to facilitate the discharge of the air filled in the container as well as to measure the amount of air discharged. As it is possible to measure the discharge amount of bubbles contained in the liquid of the present invention, it is possible to measure the amount of bubble generation in the main part of the piping system.

In addition, the present invention is a state in which the opening and closing unit is always closing the exhaust passage of the valve body, and when the opening and closing unit opens the exhaust passage of the valve body, the air is filled in the upper portion of the container more than the set amount, the level of the liquid level in the container is lowered When the air flows out through the exhaust passage and the air in the upper portion of the container is less than the set amount, the opening and closing unit to block the exhaust passage of the valve body to prevent the liquid filled in the container from leaking through the exhaust passage.

1 is a front sectional view showing an embodiment of a combined gas measurement apparatus according to the present invention,
Figure 2 is a front sectional view showing another embodiment of the bubble separation unit constituting an embodiment of the combined gas measurement and discharge device according to the present invention,
Figure 3 is a front sectional view showing the valve seat of the exhaust flow passage constituting an embodiment of the combined gas measurement and discharge device according to the present invention,
Figure 4 is a front sectional view showing another embodiment of the sensing unit constituting an embodiment of a combined gas measurement and discharge device according to the present invention,
Figure 5 is a front sectional view showing a backflow prevention unit constituting an embodiment of a combined gas measurement and discharge device according to the present invention,
Figure 6 is a front sectional view showing the exhaust state of the combined gas measurement apparatus according to the present invention,
Figure 7 is a front cross-sectional view showing a blocked state of the exhaust flow path of the combined gas measurement apparatus according to the present invention.

Hereinafter, with reference to the accompanying drawings, an embodiment of a gas measurement combined discharge device according to the present invention.

1 is a front sectional view showing an embodiment of a combined gas measurement and discharge device according to the present invention.

As shown in FIG. 1, in one embodiment of the combined gas measurement apparatus according to the present invention, a container 10, a bubble separation unit 20, a valve body 30, an opening / closing unit 40, and a sensing unit 50 are provided. ), And a control unit 60.

The container 10 is provided with an inlet 11 through which liquid is introduced and an outlet 12 through which the introduced liquid flows out. The spout which is opened in the upper part of the container 10 is provided, the inlet 11 and the outlet 12 are each provided on the side of the container 10, it is preferably provided in a position facing each other. Inlet 11 and outlet 12 of vessel 10 are preferably located on a horizontal line. Meanwhile, the inlet 11 of the container 10 may be provided at the side of the container 10, and the outlet 12 of the container 10 may be provided at the bottom surface of the container 10, and may also be provided at the bottom of the container 10. An inlet 11 may be provided at the bottom of the container 10 and an outlet 12 of the container 10 may be provided at the side of the container 10. The liquid inlet pipe P1 through which the liquid flows into the inlet 11 of the container 10 is connected, and the liquid outlet pipe P2 is connected to the outlet 12 of the container 10. The material of the container 10 may be a material such as metal, nonmetal, plastic, or the like.

The bubble separation unit 20 is provided inside the container 10, and guides bubbles contained in the liquid flowing into the inlet 11 to the upper side of the container 10. That is, in the process in which the liquid flows into the container 10 through the liquid inlet pipe P1 and the inlet 11 and flows into the container 10 through the outlet 12 and the liquid outlet pipe P2. As the liquid flowing into the container 10 through the liquid inlet pipe P1 passes through the bubble separation unit 20, bubbles contained in the liquid float in the vertical direction to move above the water surface of the container 10. In one example of the bubble separation unit 20, the bubble separation unit 20 includes a plurality of cylindrical bodies (21). Preferably, the cylinders are provided with slits. The plurality of cylindrical bodies are filled up to a set height inside the container 10, but are filled higher than the inlet 11 and the outlet 12 of the container 10. In another embodiment of the bubble separation unit 20, the bubble separation unit 20, as shown in Figure 2, includes a mesh plate (mesh plate) (22). The mesh plate 22 is preferably in a bent form. On the other hand, a plurality of mesh plates 22 may be configured.

The valve body 30 is coupled to the upper portion of the container 10, the exhaust flow path (F) is provided. It is preferable that the valve body 30 seals the spout of the container 10. As an example of the exhaust flow path F, the exhaust flow path F is an agent that connects the opening / closing space 31 provided at the upper portion of the valve body 30 with the interior of the container 10 and the opening / closing space 31. The first flow path 32, the opening and closing space 31 and the second flow path 33 for communicating the outside of the valve body 30 is included. It is preferable that one side of the second flow passage 33 communicates with the bottom surface of the opening / closing space 31, and the other side of the second flow passage 33 communicates with the side surface of the valve body 30. It is preferable that a valve seat 34 having an annular protruding annular hole of the second flow path 33 on the bottom surface of the opening / closing space 31 is provided.

The opening and closing unit 40 opens and closes the exhaust flow path F of the valve body 30. In one example of the opening and closing unit 40, the opening and closing unit 40 is an opening and closing member 41 for opening and closing the exhaust flow path (F), and the opening and closing member 41 to open and close the exhaust flow path (F). It includes a moving opening and closing member drive unit 42. The opening and closing member 41 opens and closes the exhaust flow path F by opening and closing the second flow path 33 of the exhaust flow path F while moving in the exhaust flow path F opening and closing space 31 of the valve body 30. That is, when the opening / closing member 41 contacts the valve seat 34 provided on the bottom surface of the opening / closing space 31, the second flow path 33 is blocked, and the opening / closing member 41 of the opening / closing space 31 is closed. The second flow path 33 is opened when it is separated from the bottom surface. As an example of the opening and closing member driving unit 42, the opening and closing member driving unit 42 preferably includes a solenoid for moving the opening and closing member 41 according to the control of the control unit 60. Opening and closing member drive unit 42 is preferably coupled to the upper portion of the valve body (30).

The sensing unit 50 detects an amount of gas filled in the upper portion of the container 10. As an example of the sensing unit 50, the sensing unit 50 is provided with a sensing rod 51 which is located in the vertical direction in the interior of the container 10, and capable of moving up and down on the sensing rod 51 to the container ( 10) includes a floating body 52 moving up and down according to the liquid surface inside, and a position detecting sensor 53 for detecting a vertical position of the floating body 52 and generating a signal to the control unit 60. Sensor rod 51 is preferably coupled to the valve body (30). The upper end of the sensing rod 51 is coupled to the valve body 30 so that the sensing rod 51 is vertically positioned inside the container 10. Floating body 52 is preferably formed in a ring shape. The floating body 52 is coupled to the sensing rod 51 so that the sensing rod 51 is inserted into the inner hole of the floating body 52. The position sensor 53 includes a lower sensor S1 and an upper sensor S2, and the lower sensor S1 is positioned so that the floating body 52 is positioned between the lower sensor S1 and the upper sensor S2. It is provided on the lower end of the sensing rod 51 and the upper sensor (S2) is provided on the sensing rod 51 to be located above the floating body (52). The upper sensor S2 is positioned on the sensing rod 51 such that the upper surface of the floating body 52 and the upper sensor S2 are separated by a set distance in a state in which the floating body 52 is in contact with the lower sensor S1. .

When the amount of air filled in the upper part of the container 10 increases, and the increase in the air pressure thereof lowers the water level (liquid level) of the liquid filled in the container 10, the floating body 52 is detected accordingly. It moves downward along the rod 51 to contact the lower sensor (S1), the amount of air filled in the upper portion of the container 10 is reduced, the lower of the air pressure for it is the When the water surface (liquid level) becomes high, the floating body 52 moves upward along the sensing rod 51, thereby contacting the upper sensor S2.

The control unit 60 controls the opening and closing unit 40 according to the detection signal of the detection unit 50. That is, when the amount of air filled in the upper portion of the container 10 increases, and the floating body 52 contacts the lower sensor S1 due to an increase in the air pressure in the upper portion of the container 10, a detection signal is sent to the control unit 60. The opening and closing unit 40 opens the exhaust passage F of the valve body 30, and the exhaust passage F of the valve body 30 opens, so that the air filled in the upper portion of the container 10 is exhaust passage ( When the air pressure is discharged to the outside through the F) to reduce the air pressure of the upper portion of the container 10, and thus the floating body 52 contacts the upper sensor S1, the detection unit is transmitted to the control unit 60 to open and close the unit 40. ) Closes the exhaust flow path F of the valve body 30. The control unit 60 controls the solenoid of the opening and closing unit 40. It is preferable that the display device 70 is connected to the control unit 60. The control unit 60 records the number of times that the opening / closing unit 40 opens and closes the exhaust flow path F of the valve body 30, and based on the data, the control unit 60 stores the inside of the container 10 through the display unit 70. Displays the amount of air exhausted. At this time, when the opening and closing unit 40 is inputted in advance the amount of air discharged when opening and closing once, the opening and closing unit 40 when the number of times to open and close the exhaust flow path (F) of the valve body 30 for a unit time is input unit time It is possible to display the discharge of the air during the period, the discharge of the air is the amount of air generated inside the container (10). On the other hand, the control unit 60 can display the discharge amount of the air by the data to open and close the exhaust passage (F) in the unit 40 and the number of times the opening and closing the exhaust passage (F) during the unit time.

In another embodiment of the sensing unit 50, the sensing unit 50 includes a pressure sensor 54 for sensing gas pressure above the vessel 10. As shown in FIG. 4, the pressure sensor 54 is preferably provided on the bottom surface of the valve body 30 so as to be located inside the container 10. On the other hand, the pressure sensor may be mounted on the upper portion of the container (10). When the pressure detected by the pressure sensor 54 is greater than or equal to the set pressure, the detection signal is sent to the control unit 60, and when the pressure detected by the pressure sensor is less than or equal to the set pressure, the detection signal is transmitted to the control unit 60. Sent to). The control unit 60 opens and closes the open / close unit 40 according to the detection signal transmitted by the pressure sensor 54.

In the exhaust passage F of the valve body 30, it is preferable that a backflow prevention unit 80 is provided to prevent backflow of external air. As shown in FIG. 5, the backflow prevention unit 80 includes an expansion space 35 formed in the first flow path 32 of the exhaust flow path F so as to have an inner diameter larger than the inner diameter of the first flow path 32. And a stopper member 81 coupled to the opening / closing space 31 of the expansion space 35 and having a through hole therein, and a ball shape which is movably positioned in the expansion space 35 to open and close the flow path. The ball member 82 of the. A plurality of protrusions 81a are provided at the edges of the through-holes of the stopper member 81 so that when the air on the container 10 is pressurized, the ball member 82 moves toward the stopper member 81 to the protrusions 81a. When the air flows between the protrusions 81a in a supported state, and when external air flows into the second flow path 33 and the opening / closing space part 31, the ball member 82 is expanded into the expansion part 35. The first flow path 32 is blocked by moving to the hole of the container 10 side, thereby preventing external air from flowing into the container 10.

The liquid inlet pipe P1 and the liquid outlet pipe P2 respectively connected to the inlet 11 and the outlet 12 of the container 10 are respectively connected to the piping system or the liquid flow. That is, the liquid inlet pipe (P1) is connected to one side of the piping system of the liquid pipe and the liquid outlet pipe (P2) is connected to the other side of the pipe liquid flowing through the piping of the piping system vessel through the liquid inlet pipe (P1) (10) flows into the interior and flows through the liquid outlet pipe (P2) to the piping of the piping system. The piping system may be a piping system of a domestic boiler, a piping system of a thermal power plant, a water supply piping system, a sewage discharge piping system, or the like.

Hereinafter, the operation and effects of the combined gas measurement and discharge device according to the present invention.

In the state where the gas measuring combined discharge device according to the present invention is installed in the piping system, the liquid flowing through the piping system flows into the inside of the container 10 through the liquid inlet pipe P1 and separates the bubbles inside the container 10. While flowing through the unit 20 to the piping system through the liquid outlet pipe (P2), as shown in Figure 6, the liquid introduced into the container 10 through the liquid inlet pipe (P1) is the container 10 As the pressure is lowered inside the bubble separation unit 20, bubbles contained in the liquid are caught by the bubble separation unit 20 and floated above the container 10 to fill the upper portion of the container 10. You lose. As the air of the bubbles is filled in the upper portion of the vessel 10, the amount of air increases and the air pressure in the upper portion of the vessel 10 increases, so that the level of the liquid filled in the vessel 10 is lowered. As the float 52 of the sensing unit 50 moves downward as the level of the liquid filled in the container 10 comes into contact with the lower sensor S1, a detection signal is sent to the control unit 60 and the detection is performed. In response to the signal, the control unit 60 moves the opening / closing member 41 of the opening / closing unit 40 to open the exhaust passage F of the valve body 30. As the exhaust passage F of the valve body 30 is opened, air of bubbles filled in the container 10 is exhausted to the outside through the exhaust passage F.

As the air of the bubbles filled in the container 10 is exhausted to the outside through the exhaust flow path (F), the amount of air in the container 10 decreases, so that the air pressure drops, so that the liquid level filled in the container 10 is reduced. Will go up. As shown in FIG. 7, when the level of the liquid filled in the container 10 rises, the floating body 52 moves upward and comes into contact with the upper sensor S2 to send a detection signal to the control unit 60. In response to the detection signal, the control unit 60 moves the opening / closing member 41 of the opening / closing unit 40 to block the exhaust passage F of the valve body 30. As the exhaust passage F of the valve body 30 is blocked, air of bubbles is filled in the container 10.

By repeating this operation, air bubbles contained in the liquid flowing along the piping of the piping system are exhausted to the outside of the piping system.

On the other hand, by controlling the number of times of opening and closing the opening and closing unit 40 in the control unit 60 during the unit time to measure the amount of air discharged from the piping system during the unit time as well as the amount of bubbles generated in the piping system I can figure it out.

In the present invention, since the inlet 11 and the outlet 12 are provided in the container 10 and the bubble separation unit 20 is provided in the inside of the container 10, the liquid including bubbles is introduced into the container 10 through the inlet. As the pressure decreases, the exposed area of the liquid is widened to the upper part of the container 10, and the bubbles contained in the liquid are sufficiently separated from the liquid by the bubble separation unit 20 to move to the upper part of the container 10. As a result, only the liquid from which the bubbles have been removed exits the outlet 12 of the container 10. As a result, bubbles are removed from the liquid exiting through the container 10 to prevent noise from being generated while the liquid flows through the piping system, and to reduce the flow resistance.

In addition, according to the present invention, when the air of the bubble filled in the upper portion of the container 10 is equal to or higher than the set pressure, the opening / closing unit 40 opens the exhaust flow path F by the control of the control unit 60 to open the inside of the container 10. When the air is discharged to the outside and the internal air of the container 10 is discharged so that the internal pressure of the container 10 is equal to or less than the set pressure, the opening / closing unit 40 is controlled by the control unit 60 to discharge the air flow path F. Since the closing of the air filled in the container 10 is smoothly discharged as well as the amount of air discharged can be measured. According to the present invention, the amount of bubbles contained in the liquid can be measured, and thus the amount of bubble generated in the main part of the piping system can be measured.

In addition, the present invention is a container when the opening and closing unit 40 is always closing the exhaust flow path (F) of the valve body 30, and also the opening and closing unit 40 opens the exhaust flow path (F) of the valve body 30 When the air is filled in the upper portion of the upper portion (10) or more and the level of the liquid filled in the container 10 is lowered, the air escapes through the exhaust flow path (F) and the air in the upper portion of the vessel 10 is lower than the set amount The opening / closing unit 40 blocks the exhaust passage of the valve body 30 to prevent the liquid filled in the container 10 from leaking through the exhaust passage F.

10; Container 20; Bubble Separation Unit
30; Valve body 40; Opening Unit
50; Sensing unit 60; Control unit

Claims (7)

A container having an inlet through which liquid is introduced and an outlet through which the inflowed liquid flows out such that the inlet and the outlet are connected to a pipe of a piping system;
A bubble separation unit provided inside the container and guiding bubbles contained in the liquid flowing into the inlet to the outlet and directed toward the upper side of the container;
A valve body coupled to an upper portion of the container, the valve body having an exhaust passage through which gas of bubbles guided into an upper side of the container is exhausted out of the container;
An opening / closing unit for opening and closing the exhaust passage of the valve body;
A sensing unit for detecting a change in the level of the liquid in the container by a pressure change in accordance with a change in the amount of gas above the inside of the container;
When the pressure in the upper portion of the vessel is increased to detect that the liquid level is lower than the set value in the sensing unit, the opening / closing unit opens the exhaust passage to exhaust the gas in the upper portion of the vessel, and the pressure in the upper portion of the vessel. A control unit configured to control the opening and closing unit so that the opening and closing unit closes the exhaust flow path when the sensing unit detects that the liquid level of the liquid is an upper set value, and records data of the number of opening and closing per unit time of the opening and closing unit;
And a display unit configured to display an amount of gas exhausted per hour based on the data data generated by the control unit.
The sensing unit has a sensing rod positioned vertically in the interior of the container, the sensing rod is movable up and down in the sensing rod and moves up and down according to the level of the liquid in the container, and the vertical position of the floating body. It includes a position detecting sensor for detecting a signal to generate a signal to the control unit,
The position sensor includes a lower sensor for detecting the position of the lower set point of the float, and an upper sensor for sensing the position of the upper set point of the float,
The exhaust passage has an opening and closing space provided on the upper portion of the valve body, a first flow path provided in the valve body to communicate with the opening and closing space of the container, the bottom surface of the opening and closing space provided in the valve body and A second flow path communicating with a side surface of the valve body, and a valve seat protruding from a hole edge of the second flow path of the bottom surface of the opening and closing space,
The opening and closing unit opens and closes under the control of the control unit to open and close the exhaust flow path to open and close the exhaust flow path while contacting or falling contact with the valve seat while moving in the opening and closing space portion of the exhaust flow path. A solenoid for moving the member,
An expansion flow preventing unit further preventing a backflow of external air in the exhaust passage of the valve body, wherein the backflow preventing unit is formed in the first passage of the exhaust passage to have an inner diameter larger than the inner diameter of the first passage; And a stopper member coupled to the open / close space portion of the enlarged space portion and having a through hole therein, and a ball-shaped ball member movably located in the enlarged space portion to open and close a flow path. A gas measurement and combined discharge device, characterized in that a plurality of projections are provided in contact with the ball member at the edge of the through hole. delete delete delete delete delete delete

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