KR20230006380A - Expansion tank part with miniaturized bladder and apparatus for treating expanded water including the same - Google Patents

Abstract

The present invention relates to an expansion water treatment apparatus. The expansion water treatment apparatus according to one embodiment of the present invention comprises: an expansion tank unit treating expansion water of heated water while circulating the water heated by a heating apparatus into a target object; and a water separator removing dissolved oxygen in the heated water while circulating the water heated by the heating apparatus into the target object. The expansion tank includes an expansion tank which has a sealed space at the interior, and is provided in a cylindrical shape in which the length direction is horizontal and both end surfaces are outwardly convex dome-shaped, wherein an entrance through which the expansion water and reduction water flow in and out is formed on the top surface thereof. Accordingly, a water separation tank separately provided on the expansion tank, the expansion tank unit capable of installing a multi-pump and another configuration, and the expansion water treatment apparatus including the same are provided.

Description

Bladder miniaturization expansion tank unit and expansion water treatment device including the same

The present invention relates to an expansion tank part for treating expansion water and an expansion water treatment device including the same, and more particularly, to an expansion tank part in which an expansion tank is installed in a horizontal direction and a bladder of a smaller capacity can be used, and It relates to an expansion water treatment device including the same.

In a heat exchange system used for district heating or the like, when the temperature of water in a heating pipe rises, the volume of the water expands, resulting in an increase in pipe pressure. If this increase in pipe pressure is neglected, damage to heating pipes and various devices may occur. Therefore, in order to solve this problem, an expansion tank is usually installed in the heating pipe.

1 is a cross-sectional side view showing an example of a general expansion tank. Referring to FIG. 1, a general closed expansion tank 1 has an entrance 2 through which expansion water enters and reduced water exits, and a bladder 3 connected to the entrance 2 is formed on the upper surface. Provided. In the case of the expansion tank 1 having such a structure, when the pipe pressure rises, the expansion water flows into the bladder 3 and the bladder 3 expands, and when the pipe pressure decreases again, the reduced water in the bladder 3 Expansion water is treated in such a way that the pressure in the expansion tank (1) discharges it through the port (2).

Such a conventional expansion tank 1 has a cylindrical shape in which both end faces are provided in a dome shape to distribute internal pressure. The expansion tank 1 of this shape is installed in the vertical direction so that both end surfaces are arranged in the vertical direction, and the entrance 1 is formed on the upper or lower surface of the dome shape. Therefore, since the upper surface of the expansion tank 1 is provided as a narrow curved surface, it is difficult to install other components. If the space between the bladder 3 and the upper surface of the expansion tank 1 is narrow, there is a problem in that the bladder may be damaged due to the structure penetrating the expansion tank 1 when the bladder 3 is inflated.

In addition, as described above, the conventional expansion tank 1 has a narrow upper surface, so it is difficult to provide two or more entrances 1, and only one bladder 3 can be provided, so that a larger capacity of expansion water can be processed. In the case of installing a larger size bladder 3 for this purpose, the possibility of damage to the bladder 3 increases due to a large load, the cost of the bladder itself increases as the size increases, and the labor cost when replacing the bladder 3 increases. it rises

Registered utility model 20-0344819 (2004. 03. 03.)

An object of the present invention is to solve the above-described problems, and an object of the present invention is an expansion tank unit capable of installing a water separation tank, a multi-pump, and other configurations separately provided on an expansion tank, and an expansion water treatment device including the same is to provide

In addition, an object of the present invention is to provide an expansion tank unit capable of applying a smaller size bladder and an expansion water treatment device including the same.

Expansion water treatment apparatus according to an embodiment of the present invention, the expansion tank unit for treating the expansion water of the heated water while circulating the water heated in the heating device to the inside of the object; and a water separator for removing dissolved oxygen in the heated water while circulating the water heated by the heating device into the object, wherein the expansion tank unit has a sealed space therein, and the longitudinal direction is horizontal and positive. An expansion tank having an end surface provided in a cylindrical shape, which is a dome shape convex outward, and having an entrance through which expansion water and reduced water enter and exit on the upper surface; a bladder provided within the expansion tank and communicating with the entrance and the inside; and an expansion pipe connected between the inlet and a pipe through which water circulates between the heating device and the object, wherein the water separator has a space for receiving water therein and is installed on an upper surface of the expansion tank. brackish water separation tank; an expansion water inlet pipe connecting the expansion pipe and the air separation tank so that water in the expansion pipe flows into the air separation tank; a reduced water discharge pipe connecting the expansion pipe and the steam separation tank so that water in the air separation tank is discharged to the expansion pipe; and a multi-pump installed on an upper surface of the expansion tank and applying force so that the water in the steam separation tank is discharged through the discharge pipe.

A plurality of entrances may be provided along the longitudinal direction of the expansion tank on the upper surface of the expansion tank, and a plurality of bladders may be provided so that the insides of the entrances communicate with each other.

The steam separator may include an expansion water inlet valve opening and closing the expansion water inlet pipe; Measuring the pressure of the expansion pipe, sending a signal to open the expansion water inlet valve to the expansion water inlet valve when the measured pressure is equal to or greater than the first pressure, and inlet of the expansion water when the measured pressure is less than the first pressure. a first pressure switch for sending a signal to close the valve to the expansion water inlet valve; and measuring the pressure of the expansion pipe, sending a signal for operating the multi-pump to the multi-pump when the measured pressure is less than or equal to the second pressure, and stopping the multi-pump when the measured pressure exceeds the second pressure. and a second pressure switch for sending a signal to the multi-pump, and the second pressure may be lower than the first pressure.

In addition, the present invention provides an expansion tank unit for treating the expansion water of the heated water while circulating the water heated by the heating device inside the object. According to one embodiment, the expansion tank unit has a space sealed therein, is provided in a cylindrical shape with a longitudinal direction in a horizontal direction and both end surfaces are outwardly convex dome-shaped, and an entrance through which expansion water and reduced water flow in and out on the upper surface. an expansion tank in which is formed; and a bladder provided within the expansion tank and communicating with the entrance and the inside.

An expansion tank unit and an expansion water treatment device including the expansion tank unit according to the present invention may install a separate steam separation tank and multi-pump and other configurations on the expansion tank.

An expansion tank unit and an expansion water treatment device including the expansion tank unit according to the present invention may apply a bladder smaller than 　.

1 is a cross-sectional side view showing an example of a general expansion tank.
2 is a view schematically showing an expansion water treatment device according to an embodiment of the present invention.
3 is a perspective view showing an example of the expansion water treatment device of FIG. 2 .
Figure 4 is a cross-sectional view showing an example of the inside of the expansion tank shown in Figure 2;
5 is a perspective view showing an expansion water treatment device according to another embodiment of the present invention.
6 is a cross-sectional view showing an example of the inside of the expansion tank shown in FIG. 5;
7 is a cross-sectional view showing the inside of another example of the expansion tank shown in FIG. 2;
8 is a schematic view of an expansion water treatment device according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described clearly and in detail to the extent that those skilled in the art can easily practice the present invention.

2 is a view schematically showing an expansion water treatment device according to an embodiment of the present invention. 3 is a perspective view showing an example of the expansion water treatment device of FIG. 2 . Figure 4 is a cross-sectional view showing an example of the inside of the expansion tank shown in Figure 2; Referring to FIGS. 2 to 4 , the expansion water treatment device 10 treats expansion water of a heat exchange system used for district heating and the like, and removes dissolved oxygen from the water. A heat exchange system circulates water heated by a heating device to objects such as apartments, buildings, or factories. According to one embodiment, the expansion water treatment device 10 may include an expansion tank unit 1000 and a water separator 2000.

The expansion tank unit 1000 treats the expansion water of the heated water while circulating the water heated by the heating device into the object. According to an embodiment, the expansion tank unit 1000 may include an expansion tank 1100, a bladder 1200, an expansion pipe 1300, and a support 1400.

The expansion tank 1100 has a sealed space therein. The expansion tank 1100 is provided in a cylindrical shape with both end surfaces convex outward in a dome shape. According to one embodiment, the expansion tank 1100 is installed such that the longitudinal direction is horizontal. An upper surface of the expansion tank 1100 is formed with an entrance 1110 through which expansion water and reduced water enter and exit. In this way, since the expansion tank 1100 is installed such that the longitudinal direction is horizontal, the upper surface can be provided wide, and as will be described below, configurations such as the water separation tank 2100 and the multi-pump 2400 can be provided. It can be installed on the expansion tank 1100. In addition, since the top of the separation tank 2100 is lowered, it is possible to easily access the top of the separation tank 2100 during maintenance and management of the separation tank 2100 .

According to one embodiment, the entrance 1110 is formed in an area adjacent to one of both ends of the upper surface of the expansion tank 1100. As described above, the expansion tank 1100 is placed so that the longitudinal direction is horizontal, so that the entrance 1110 of the expansion tank 1100 is biased toward one of both ends of the expansion tank 1100, so that the upper bladder As the area not adjacent to 1200 is widened, components such as the pressure gauge 1500, which must be installed through the upper surface of the expansion tank 1100, can be more easily installed without damaging the bladder 1200.

A bladder 1200 is provided within the expansion tank 1100. The inside of the bladder 1200 communicates with the entrance 1110 . The bladder 1200 may be made of a flexible and elastic synthetic rubber material such as EPDM. Expansion water is accommodated in the bladder 1200 .

The expansion pipe 1300 is connected between the entrance 1110 and a pipe through which water circulates between the heating device and the object. According to one embodiment, the expansion pipe 1300 may be connected between the entrance 1110 and the return pipe connecting the object and the heating device so that the return water of the object flows to the heating device. The expansion water generated in the heat exchange system is supplied to the expansion tank 1100 and/or the air separation tank 2100 through the expansion pipe 1300, and is expanded again from the expansion tank 1100 and/or the air separation tank 2100. It is returned to the heat exchange system through the pipe 1300.

The support 1400 is provided on the upper surface of the expansion tank 1100. The support 1400 is provided with a flat upper surface. Since the support 1400 provides a flat upper surface, components such as the air separation tank 2100 and the multi-pump 2400 to be described below can be more stably installed on the expansion tank 1100.

Hereinafter, a method for treating expansion water in the expansion tank unit 1000 according to the present embodiment will be described. As the temperature rises in the heat exchange system, the pressure in the expansion pipe 1300 is greater than the pressure in the expansion tank 1100, and the expansion water is supplied into the bladder 1200. Accordingly, the pressure inside the expansion tank 1100 increases as the bladder 1200 expands and the space inside the expansion tank 1100 except for the bladder 1200 narrows. Thereafter, when the temperature in the heat exchange system drops and the pressure inside the expansion pipe 1300 is lower than the pressure inside the expansion tank 1100, the bladder 1200 contracts, and the expansion water in the bladder 1200 serves as reduced water in the expansion tube ( 1300) is supplied.

A replenishment water supply line 1600 for supplying replenishment water to the heat exchange system may be connected to the expansion pipe 1300 . A replenishment water valve 1601, a check valve 1602, and a pressure reducing valve 1603 may be provided in the replenishment water supply line 1600.

The make-up water valve 1601 opens and closes the make-up water supply line 1600 . For example, the supplemental water valve 1601 may include a manual valve that is manually opened and closed. Alternatively, the replenishment water valve 1601 may include a valve that can be opened and closed automatically, such as a solenoid valve, by an electrical signal as needed.

The check valve 1602 prevents the fluid in the expansion pipe 1300 from flowing backward through the replenishment water supply line 1600 in a direction opposite to the direction in which replenishment water is supplied.

The pressure reducing valve 1603 reduces the pressure supplied with make-up water. Therefore, the pressure in the expansion pipe 1300 is excessively increased by the supplemental water supplied through the supplementary water supply line 1600, so that the fluid in the expansion tube 1300, not the expansion water, is discharged from the expansion tank 1100 and/or the air separation. Supply to the tank 2100 can be prevented.

The water separator 2000 removes dissolved oxygen in the heated water while circulating the water heated by the heating device into the object. In addition, the water separator 2000 may treat the expansion water of the heated water while circulating the water heated by the heating device into the object, separately from the expansion tank unit 1000. According to one embodiment, the separator 2000 includes a plurality of water separators including a water separation tank 2100, an expansion water inlet pipe 2200, a reduced water discharge pipe 2300, a multi-pump 2400, and an expansion water inlet valve V1. It may include valves V2 and V3, a first pressure switch 2500 and a second pressure switch 2600.

As will be described below, each of the valves V1, V2, and V3 can be partially opened and closed automatically according to specific conditions, and all of them can be manually opened and closed according to a user's manipulation.

The steam separation tank 2100 may have a rectangular parallelepiped structure in which a space for accommodating fluid is formed. Since the inside of the brackish water separation tank 2100 of the present embodiment is not maintained in a vacuum state, but is in an atmospheric pressure state, the upper and lower sides may have a rectangular parallelepiped shape rather than a semicircular pill shape. Accordingly, manufacturing and installation of the water separation tank 2100 may be facilitated. A vacuum release device (not shown) communicating with the outside may be installed on one side of the air separation tank 2100 to maintain an internal atmospheric pressure.

A level gauge 2700 may be provided on one side wall of the air separation tank 2100 . The level gauge 2700 shows the water level in the water separation tank 2100. The water level in the separation tank 2100 may be checked using the level gauge 2700 to prevent the water from overflowing in the separation tank 2100 . Unlike this, a see-through window through which the inside of the water separation tank 2100 can be checked separately from the level gauge 2700 or together with the level gauge 2700 may be provided on one side wall of the water separation tank 2100 . Since the water separation tank 2100 is provided in a rectangular parallelepiped shape, the side wall is provided as a flat surface rather than a curved surface, so that the installation of the viewing window is easy.

The air separation tank 2100 is installed on the upper surface of the expansion tank 1100. According to one embodiment, the air separation tank 2100 may be installed on a support 1400 provided on an upper surface of the expansion tank 1100.

The expansion water inlet pipe 2200 connects the expansion pipe 1300 and the air separation tank 2100 so that water in the expansion pipe 1300 flows into the air separation tank 2100 . According to one embodiment, the expansion water inlet pipe 2200 may be connected to the upper surface of the air separation tank 2100. After the water heated by the heating device of the heat exchange system transfers and uses heat through an object such as a building, it may be introduced into the air separation tank 2100 through the expansion pipe 1300 and the expansion water inlet pipe 2200. At this time, the multi-pump 2400 may be operated to supply the expansion water to the inside of the water separation tank 2100 through the expansion water inlet pipe 2200.

The reduced water discharge pipe 2300 connects the expansion pipe 1300 and the air separation tank 2100 so that water in the air separation tank 2100 is discharged to the expansion pipe 1300. According to one embodiment, the reduced water discharge pipe 2300 is connected to one side of the water separation tank 2100. One end of the reduced water discharge pipe 2300 may be connected to the air separation tank 2100, and the other end of the reduced water discharge pipe 2300 may be connected to the expansion pipe 1300.

The multi-pump 2400 applies force so that the water in the brackish water separation tank 2100 is discharged through the reduced water discharge pipe 2300. The multi-pump 2400 is installed on the upper surface of the expansion tank. The multi-pump 2400 may be provided in the reduced water discharge pipe 2300. According to one embodiment, the multi-pump 2400 may be installed on the support 1400 provided on the upper surface of the expansion tank 1100.

As described above, since the multi-pump 2400 and the air separation tank 2100 are installed on the upper surface of the expansion tank 1100, the installation area of the expansion water treatment device 10 is reduced and the structure of the heat exchange system 1000 is improved. can be abbreviated.

An expansion water inlet valve V1 is installed in the expansion water inlet pipe 2200. The expansion water inlet valve V1 opens and closes the expansion water inlet pipe 2200 . For example, the expansion water inlet valve V1 may include a solenoid valve.

The first pressure switch 2500 may be installed in the expansion water inlet pipe 2200 . The first pressure switch 2500 may measure the internal pressure of the expansion tube 1300 and generate a signal according to the measured pressure. The expansion water inlet valve V1 may be opened and closed by a signal from the first pressure switch 2500 . For example, the first pressure switch 2500 measures the internal pressure of the expansion pipe 1300, and sends a signal for opening the solenoid valve of the expansion water inlet valve V1 when the measured pressure is equal to or higher than the first pressure. It is sent to the inlet valve (V1), and accordingly, the solenoid valve of the expansion water inlet valve (V1) is opened so that the expansion water inlet pipe (2200) can be opened. In addition, the first pressure switch 2500 sends a signal to close the solenoid valve of the expansion water inlet valve V1 to the expansion water inlet valve when the measured pressure is less than the first pressure, and accordingly, the expansion water inlet valve V1 The expansion water inlet pipe 2200 may be closed by closing the solenoid valve.

The expansion water introduced into the separation tank 2100 through the multi-pump 2400 by opening the expansion water inlet valve V1 is temporarily stored inside the separation tank 2100, and the stored expansion water is naturally cooled to a temperature. By falling, the expanded water can be reduced to its original state. The expansion water reduced to its original state (hereinafter referred to as reduced water) moves to the expansion pipe 1300 through the reduced water discharge pipe 2300 and can continuously circulate through the heat exchange system.

A first discharge pipe valve V2 and a second discharge pipe valve V3 that open and close the reduced water discharge pipe 2300 may be installed in the reduced water discharge pipe 2300 . The first discharge pipe valve V2 is disposed between the steam separation tank 2100 and the multi-pump 2400, and the second discharge pipe valve V3 is disposed between the multi-pump 2400 and the other end of the reduced water discharge pipe 2300. It can be. For example, the first discharge pipe valve V2 may include a gate valve that is manually opened and closed. The second discharge pipe valve V3 may include a check valve that opens the water in the reduced water discharge pipe 2300 only in one direction toward the expansion pipe 1300 . The second discharge pipe valve V3 may prevent the reduced water in the reduced water discharge pipe 2300 from flowing back into the steam separation tank 2100 again.

The second pressure switch 2600 is installed in the reduced water discharge pipe 2300. The second pressure switch 2600 may measure the internal pressure of the expansion pipe 1300 and generate a signal according to the measured pressure. The multi-pump 2400 may be started and stopped by a signal from the second pressure switch 2600 . For example, the second pressure switch 2600 measures the internal pressure of the expansion pipe 1300 and sends a signal to operate the multi-pump 2400 to the multi-pump 2400 when the measured pressure is less than the second pressure. , Accordingly, the multi-pump 2400 can be operated. In addition, the second pressure switch 2600 sends a signal to stop the multi-pump 2400 to the multi-pump 2400 when the measured pressure exceeds the second pressure, and accordingly, the multi-pump 2400 can be stopped. there is. At this time, the second pressure may be a lower pressure than the first pressure. Alternatively, the multi-pump 2400 may be manually operated and stopped by a user's manipulation.

The reduced water discharge pipe 2300 may further include a filter (not shown) for filtering wastes in the reduced expansion water. According to one embodiment, the filter may be installed anywhere in the reduced water discharge pipe (OWL), and the location of the filter is not limited by the present invention. By installing the filter, it is possible to improve the quality of the reduced expansion water and prevent the accumulation of foreign substances in pipes through which the reduced expansion water flows.

The separator 2000 may further include a sensor 2801 installed in the separator tank 2100 to measure the amount of dissolved oxygen in the expansion water. In this embodiment, the sensor 2801 for measuring the amount of dissolved oxygen is installed in the separation tank 2100, but the sensor 2801 for measuring the amount of dissolved oxygen is disposed in the expansion water inlet pipe 2200 to introduce the expansion water. The amount of dissolved oxygen in the expansion water flowing through the pipe 2200 may be measured. Therefore, the present invention does not limit the position of the sensor 2801 for measuring the amount of dissolved oxygen. Meanwhile, in this embodiment, the sensor 2801 has been described as measuring the amount of dissolved oxygen, but may measure the overall water quality in the expansion water.

The steam separator 2000 may further include an overflow line 2901 communicating with the steam separation tank 2100 . The overflow line 2901 may be connected to a height adjacent to the limit water level in the air separation tank 2100 of one side wall of the air separation tank 2100. Therefore, when the water level in the brackish water separation tank 2100 exceeds the limit water level, it is discharged through the overflow line 2901.

A vacuum release device 2902 communicating with the outside may be installed in the overflow line 2901 to maintain atmospheric pressure in the air separation tank 2100 . Dissolved oxygen generated in the brackish water separation tank 2100 may be discharged to the outside through the vacuum relieving device 2902 . Alternatively, a separate dissolved oxygen discharge line (not shown) communicating with the outside may be connected to the brackish water separation tank 2100 . In this case, a valve for opening and closing the dissolved oxygen discharge line may be provided in the dissolved oxygen discharge line, and a sensor 2801 for measuring the amount of dissolved oxygen may be provided in the valve for opening and closing the dissolved oxygen discharge line. It can be opened and closed by a signal generated according to the value. That is, the sensor 2801 for measuring the amount of dissolved oxygen generates a signal to open and close the valve for opening and closing the dissolved oxygen discharge line when the measured amount of dissolved oxygen is higher than a specific value, and the valve for opening and closing the dissolved oxygen discharge line is opened accordingly. . In addition, the sensor 2801 for measuring the amount of dissolved oxygen generates a signal to close a valve that opens and closes the dissolved oxygen discharge line when the measured amount of dissolved oxygen is lower than a specific value, and the valve that opens and closes the dissolved oxygen discharge line is closed accordingly.

A level sensor 2802 measuring a water level in the air separation tank 2100 may be installed in the air separation tank 2100 . The level sensor 2802 may be provided as an electrode type including a plurality of electrodes having different lengths. According to an embodiment, the level sensor 2802 may generate a signal to open or close the expansion water inlet valve V1 and the supplemental water valve 1601 according to the measured water level value. For example, according to the value measured by the level sensor 2802, when the amount of water in the separation tank 2100 is less than a set range, the expansion water inlet valve V1 and the make-up water valve 1601 are opened and Make-up water may be provided through the separation tank 2100 . For example, when the water in the separation tank 2100 is 6v% or less, the expansion water inlet valve V1 and the replenishment water valve 1601 are opened and replenishment water may be provided. When the water in the separation tank 2100 is 12v% or more, the expansion water inlet valve V1 and the replenishment water valve 1601 may be closed and supply of replenishment water may be stopped.

Unlike this, a separate make-up water supply line (not shown) is connected to the steam separation tank 2100, and the make-up water supply line directly connected to the steam separation tank 2100 is the above-described method according to the signal of the level sensor 2802. It can be opened and closed under the same conditions as

Although not shown in the drawings of this specification, the water separator 300 according to the embodiments of the present invention may further include a status indicator light indicating whether each pump is operated/stopped and whether each valve is opened or closed.

5 is a perspective view showing an expansion water treatment device according to another embodiment of the present invention. 6 is a cross-sectional view showing an example of the inside of the expansion tank shown in FIG. 5; 5 and 6, according to an embodiment, the expansion tank unit 1000a of the expansion water treatment device 10a includes a compressor 1701, a venting unit 1702, and a third pressure switch 1801. ), a fourth pressure switch 1802, and a compressed air spraying unit 1900 may be further included.

A compressor 1701 supplies compressed air into the expansion tank 1100a. The venting portion 1702 exhausts air in the expansion tank 1100a. The third pressure switch 1801 and the fourth pressure switch 1802 independently measure the internal pressure of the expansion tank 1100a and generate a signal according to the measured pressure. The compressed air injection unit 1900 supplies the high-pressure air in the expansion tank 1100a to the device 20 where the high-pressure air is used.

According to one embodiment, since the compressor 1701 is provided to compress the bladder 1200a with a high pressure and discharge the water in the bladder 1200a to the expansion pipe 1300, the bladder 1200 of FIG. 2 A larger capacity bladder 1200a may be provided in the expansion tank 1100a. Therefore, in order to increase the capacity of the bladder 1200a, a plurality of entrances 1110a are formed on the upper surface of the expansion tank 1100a, and one bladder 1200a is provided for each entrance 1110a. ) can be connected. As described above, since the longitudinal direction of the expansion tank 1100a is provided in a horizontal direction, a plurality of entrances 1110a may be provided along the longitudinal direction of the expansion tank 1100a, and accordingly, a plurality of bladders 1200a may also be provided. can be provided as The sum of the capacities of the plurality of bladders 1200a may be equal to or greater than the bladder capacities required for the expansion tank 1100a. For example, as in the present embodiment, when the compressor 1701 is provided, the entire capacity of the bladder 1200a may be provided as 80% of the internal volume of the expansion tank 1100a. (1200a) may be provided with a capacity divided by a certain ratio of its 80% volume. For example, as shown in FIG. 6 , when two bladders 1200a are provided, each bladder 1200a may have a capacity of 40% of the internal volume of the expansion tank 1100a.

As such, the expansion tank unit 1000a of the present invention may provide a plurality of entrances 1110a on the upper surface by providing the longitudinal direction of the expansion tank 1100a in a horizontal direction, and thus a plurality of bladders 1200a. ) can be installed. Therefore, even when a large-capacity bladder is required, by installing a plurality of smaller bladders 1200a, the load of each bladder 1200a is reduced, thereby reducing the possibility of damage due to the load, and the plurality of bladders 1200a. Since only the damaged part can be replaced, and less manpower is required as the load is reduced, the replacement cost is reduced. 6 shows a case in which two bladders 1200a are provided, however, if necessary, three or more entrances 1110a along the longitudinal direction of the expansion tank 1100a and a corresponding number of bladders. 1200a may be provided.

The venting portion 1702 exhausts air in the expansion tank 1100a. According to one embodiment, the banting part 1702 may include a banting line 1710 and a banting valve 1720. The venting line 1710 connects the expansion tank 1100a to the outside so that air inside the expansion tank 1100a can be discharged to the outside. The banting valve 1720 opens and closes the banting line 1710. The banting valve 1720 may include a solenoid valve.

The third pressure switch 1801 may be installed in the expansion tank 1100a. The third pressure switch 1801 may measure the internal pressure of the expansion tank 1100a and generate a signal according to the measured pressure. The compressor 1701 may be started and stopped by a signal from the third pressure switch 1801 . For example, the third pressure switch 1801 measures the internal pressure of the expansion pipe 1300 and sends a signal to operate the compressor 1701 to the compressor 1701 when the measured pressure is less than or equal to the third pressure. Accordingly, the compressor is operated to increase the pressure in the expansion tank 1100a so that water in the expansion tank 1100a may be discharged to the expansion pipe 1300. Also, the third pressure switch 1801 sends a signal for stopping the compressor to the compressor when the measured pressure is less than the third pressure, and the compressor 1701 is stopped accordingly.

The fourth pressure switch 1802 may be installed in the expansion tank 1100a. The fourth pressure switch 1802 may measure the internal pressure of the expansion tank 1100a and generate a signal according to the measured pressure. The venting valve 1720 may be opened and closed by a signal from the fourth pressure switch 1802 . For example, the fourth pressure switch 1802 measures the internal pressure of the expansion pipe 1300, and sends a signal to open the venting valve 1720 to the venting valve 1720 when the measured pressure is equal to or higher than the fourth pressure. Accordingly, the venting valve 1720 is opened, and the pressure in the expansion tank 1100a decreases, so that water in the expansion pipe 1300 can more easily flow into the expansion tank 1100a. In addition, the fourth pressure switch 1802 sends a signal to close the venting valve 1720 to the venting valve 1720 when the measured pressure is less than the fourth pressure, and accordingly, the venting valve 1720 is closed. The fourth pressure may be greater than the third pressure.

Hereinafter, a method of treating expansion water using the expansion tank unit 1000a of the expansion water treatment device 10a according to the present embodiment will be described. As the temperature rises in the heat exchange system, the expansion water whose pressure in the expansion tube 1300 is greater than the pressure in the expansion tank 1100a is supplied into the bladder 1200a. Accordingly, the pressure inside the expansion tank 1100a rises as the bladder 1200a expands and the space inside the expansion tank 1100a except for the bladder 1200a narrows. At this time, when the pressure inside the expansion tank 1100a exceeds the fourth pressure, the venting valve 1720 is opened by a signal from the fourth pressure switch 1802 to accommodate a larger amount of expansion water into the bladder 1200a. It can be. Subsequently, when the pressure in the expansion tank 1100a becomes less than the fourth pressure, the venting valve 1720 is closed in response to a signal from the fourth pressure switch 1802 . Thereafter, when the temperature in the heat exchange system drops and the pressure inside the expansion pipe 1300 is lower than the pressure inside the expansion tank 1100a, the bladder 1200a contracts and the expansion water in the bladder 1200a serves as reduced water in the expansion tube ( 1300), whereby the pressure in the expansion tank 1100a drops. At this time, when the pressure inside the expansion tank 1100a is lower than the third pressure, the compressor 1701 is operated by a signal from the third pressure switch 1801, and the water in the bladder 1200a is reduced to the expansion pipe 1300. ) is released. Then, when the pressure inside the expansion tank 1100a exceeds the third pressure, the compressor 1701 is stopped by a signal from the third pressure switch 1801.

The compressed air injection unit 1900 may include a compressed air line 1910 and a compressed air valve 1920 . A compressed air line 1910 connects the expansion tank 1100a and the device 20 so that the high-pressure air in the expansion tank 1100a can be supplied to the device 20 requiring high-pressure air. A compressed air valve 1920 is provided in the compressed air line 1910 . Compressed air valve 1920 opens and closes compressed air line 1910 . Therefore, in the expansion water treatment device 10a according to the present embodiment, the high-pressure air formed in the expansion tank 1100a by the compressor 1701 is supplied by opening the compressed air valve 1920 as needed to supply various types of compressed air required. It has the effect of supplying equipment.

Other configurations, structures, functions and operation methods of the expanded water treatment device 10a of FIG. 5 may be provided identically or similarly to those of the expanded water treatment device 10 of FIG. 2 .

7 is a cross-sectional view showing the inside of another example of the expansion tank shown in FIG. 2; Referring to FIG. 7, as shown in FIG. 2, a plurality of entrances 1110b along the longitudinal direction of the expansion tank 1100b as shown in FIG. And a corresponding number of bladders 1200b may be provided. For example, as in the present embodiment, when the compressor is not provided, the entire capacity of the bladder 1200b may be provided as 20% of the internal volume of the expansion tank 1100b. At this time, each The bladder 1200b may be provided with a capacity divided by a predetermined ratio of its 20% volume. For example, as shown in FIG. 7 , when two bladders 1200b are provided, each bladder 1200b may be provided with a capacity of 10% of the internal volume of the expansion tank 1100b. In this embodiment, as needed, three or more bladders 1200b may be provided with capacities obtained by distributing 20% of the internal volume of the expansion tank 1100b at the same rate.

8 is a schematic view of an expansion water treatment device according to another embodiment of the present invention. Referring to FIG. 8, an additional pipe (ADL1) connected to the make-up water supply line 1600 in case the make-up water valve 1601, check valve 1602, and/or pressure reducing valve 1603 malfunction or fail. And, it may further include an additional valve (ADV1) disposed in the additional pipe (ADL1). The additional valve ADV1 may be a manual valve. Accordingly, opening and closing of the replenishing water supply line 1600 may be manually controlled.

In addition, the expansion water inlet valve V1 is controlled by the first pressure switch PS1, and when at least one of the first valve V1 and the first pressure switch PS1 malfunctions or fails, or the expansion tank ( 1100), an additional pipe (ADL2) connected to the expansion pipe 1300 and an additional valve (ADV2) disposed in the additional pipe (ADL2) are further provided in case expansion water exceeds the capacity of the bladder in the device is generated. can include The additional pipe ADL2 may be connected between the end of the expansion pipe 1300 and the expansion water inlet pipe 2200 connected to the air separation tank 2100. Also, the additional valve ADV2 may be a manual valve. Therefore, opening and closing of the expansion water inlet pipe 2200 can be manually controlled.

Other components, structures, functions, and operation methods of the expanded water treatment device 10b of FIG. 8 may be provided in the same or similar manner as those of the expanded water treatment device 10 of FIG. 2 . In addition, the aforementioned additional pipes ADL1 and ADL2 and additional valves ADV1 and ADV2 may be equally applied to the expansion water treatment device 10a of FIG. 5 .

As described above, the expansion water treatment apparatus according to embodiments of the present invention does not require a separate digital control device because each valve, multi-pump, and compressor are directly controlled according to pressure by pressure switches. Therefore, the expansion water treatment device according to embodiments of the present invention can prevent problems such as increased manufacturing cost, increased maintenance cost, and possibility of operation error that may occur due to providing a digital device.

In addition, the expansion water treatment device according to the embodiments of the present invention is installed so that the longitudinal direction of the expansion tank is horizontal, so that a configuration such as a water separation tank can be installed on the upper surface of the expansion tank, thereby saving installation space. Multiple bladders can be installed along the length of the expansion tank to reduce the size of each bladder, thereby reducing the possibility of bladder damage due to load and reducing the cost of replacing or repairing the bladder. .

The foregoing are specific examples for carrying out the present invention. In addition to the above-described embodiments, the present invention will also include embodiments that can be simply or easily changed in design. In addition, the present invention will also include techniques that can be easily modified and practiced using the embodiments. Therefore, the scope of the present invention should not be limited to the above-described embodiments and should not be defined, and should be defined by those equivalent to the claims of this invention as well as the claims to be described later.

10, 10a, 10b: Expansion water treatment device 1000, 1000a: Expansion tank unit
1100, 1100a, 1100b: expansion tank 1110, 1110a, 1110b: entrance
1200, 1200a, 1200b: Brader 1300: Expansion tube
1400: support 1500: pressure gauge
1600: make-up water supply line 1601: make-up water valve
1602: check valve 1603: pressure reducing valve
1701: compressor 1702: banting part
1710: banting line 1720: banting valve
1801: third pressure switch 1802: fourth pressure switch
1900: compressed air blowing part 1910: compressed air line
1920 compressed air valve 2000 water separator
2100: air separation tank 2200: expansion water inlet pipe
2300: reduced water discharge pipe 2400: multi-pump
2500: first pressure switch 2600: second pressure switch
2700: level gauge 2801: sensor for measuring the amount of dissolved oxygen
1802: level sensor 2901: overflow line
2902: vacuum release device V1: expansion water inlet valve
V2: first discharge pipe valve V3: second discharge pipe valve

Claims (4)

An expansion tank unit for treating the expansion water of the heated water while circulating the water heated by the heating device into the object; and
A water separator for removing dissolved oxygen in the heated water while circulating the water heated by the heating device into the object;
the expansion tank,
An expansion tank having a space sealed therein, provided in a cylindrical shape in which the longitudinal direction is horizontal and both end surfaces are outwardly convex dome-shaped, and an entrance through which expansion water and reduced water enter and exit is formed on the upper surface;
a bladder provided within the expansion tank and communicating with the entrance and the inside; and
An expansion pipe connected between the entrance and the pipe through which water circulates between the heating device and the object passes,
The water separator,
a water separation tank having a space for receiving water therein and installed on an upper surface of the expansion tank;
an expansion water inlet pipe connecting the expansion pipe and the air separation tank so that water in the expansion pipe flows into the air separation tank;
a reduced water discharge pipe connecting the expansion pipe and the steam separation tank so that water in the air separation tank is discharged to the expansion pipe; and
An expansion water treatment device comprising a multi-pump installed on an upper surface of the expansion tank and applying force so that the water in the separation tank is discharged through the discharge pipe. According to claim 1,
A plurality of the entrances are provided on the upper surface of the expansion tank along the longitudinal direction of the expansion tank,
A plurality of bladders are provided so that the inside communicates with each of the entrances. According to claim 1,
The water separator,
an expansion water inlet valve opening and closing the expansion water inlet pipe;
Measuring the pressure of the expansion pipe, sending a signal to open the expansion water inlet valve to the expansion water inlet valve when the measured pressure is equal to or greater than the first pressure, and inlet of the expansion water when the measured pressure is less than the first pressure. a first pressure switch for sending a signal to close the valve to the expansion water inlet valve; and
Measuring the pressure of the expansion pipe, sending a signal to operate the multi-pump when the measured pressure is less than the second pressure, and stopping the multi-pump when the measured pressure exceeds the second pressure A second pressure switch for sending a signal to the multi-pump;
The second pressure is a pressure lower than the first pressure. In the expansion tank part for treating the expansion water of the heated water while circulating the water heated by the heating device inside the object,
An expansion tank having a space sealed therein, provided in a cylindrical shape in which the longitudinal direction is horizontal and both end surfaces are outwardly convex dome-shaped, and an entrance through which expansion water and reduced water enter and exit is formed on the upper surface; and
An expansion tank unit including a bladder provided in the expansion tank and communicating with the entrance and the inside.

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