KR20120001601U - Bladder type expansion tank having a water leakage detecting function - Google Patents

Abstract

The present invention relates to a diaphragm expansion tank, and more specifically, a diaphragm expansion having a leak detection function capable of detecting an alarm when a leak occurs due to thermal damage or pressure damage of the diaphragm. It's about tanks.
The diaphragm expansion tank according to the present invention includes a closed tank body in which air is accommodated; A rubber diaphragm provided inside the tank body and accommodating the water flowing out from the circulation system; A first pressure probe for detecting pressure in the upper region inside the tank body; A second pressure probe for detecting pressure in the inner lower region of the tank body; Leak detection to detect the difference in pressure detected from the first pressure probe and the second pressure probe, and if there is a difference between both pressures, determines that the water contained in the rubber diaphragm has leaked and displays the determination result outside. Means;

Description

TYPE EXPANSION TANK HAVING A WATER LEAKAGE DETECTING FUNCTION

The present invention relates to a diaphragm expansion tank, and more specifically, a diaphragm expansion having a leak detection function capable of detecting an alarm when a leak occurs due to thermal damage or pressure damage of the diaphragm. It's about tanks.

As air-conditioning systems, individual air-conditioning, central air-conditioning, community energy system (CES) or district air-conditioning are used. Individual air-conditioning is a method of transferring heat to a load side from a heat source facility such as a small boiler or a heat pump in each household or in each room. Central air-conditioning is installed in a machine room in an entire apartment building or a complex composed of several apartment buildings. This is to supply heating and heating source to each household or each room of the whole building. On the other hand, district heating or district heating is a large-scale collective energy that supplies heat from heat sources such as incinerators, waste heat, cogeneration plants, etc. to heat exchangers in machine rooms installed in each customer's building. To each household or room. Regardless of the size, one heat supply circulation pipe receives the heat from the heat source equipment or the heat exchanger and transfers it to the load side (or heat medium, which is usually water or brine), the circulation pump that circulates the water, It consists of a circulating piping to be transported and an expansion tank to accommodate the contraction or expansion of the temperature change of the pipe water.

As shown in FIG. 1, the conventional air conditioning and heating system includes a circulation pipe 10 connected to a load 10a of a customer, for example, a cooling and heating device, and a pipe water on one side of the circulation pipe 10. A heat source facility (1) installed to cool, a pump installed to circulate the heated or cooled pipe water through the heat source facility (1) on one side of the circulation pipe (10), and one side of the circulation pipe (10) It is composed of an expansion tank (20) installed to accommodate the water branched to expand or contract according to the temperature.

Looking at the operation of the conventional air-conditioning system as described above, first heating the pipe water by using the heat source equipment (1), and then circulating the heated water by driving the pump (P), the transfer equipment, the circulated water The air is heated and cooled through the load 10a such as a heating and cooling device installed in the building while passing in the building along the pipe. In this case, as the temperature of the pipe water circulating in the sealed pipe increases, the pipe water expands, and the expanded pipe water expands through the expansion pipe 10b formed on one side of the circulation pipe 10. 20) and when the expansion water contracts as the temperature decreases again, the expansion water in the expansion tank 20 is sent to the circulation pipe 10 through the expansion pipe 10b and recycled.

The expansion tank 20 used in such a conventional heating and cooling system is divided into an open expansion tank and a closed expansion tank according to whether the inside of the expansion tank is open to the outside atmosphere, and the closed expansion tank has a rubber diaphragm therein. It is divided into a diaphragm expansion tank and a non-diaphragm expansion tank according to whether or not.

Conventionally, open expansion tanks in which the inside of the tank is open to the outside atmosphere have been widely used because of low installation cost and easy supply of replenishment water. There are disadvantages such as energy damage, high installation position, freezing concerns, and the like.

As a way of improving the disadvantages of the open expansion tank as described above, a non-diaphragm sealed expansion tank has been developed. The non-diaphragm sealed expansion tank has a structure in which the expansion amount is sucked while the pressure is changed by an air cushion in contact with the expansion water in the pressure tank. In such a non-diaphragm sealed expansion tank, air is continuously dissolved in water and consumed during use, and air is discharged out of the pipe through an air vent, so that the air in the tank disappears and water only becomes full over time. Water logging, which can't absorb the expansion water, occurs, so in most cases air compressors continue to supply air.

As shown in FIG. 1, the diaphragm expansion tank is provided with a rubber diaphragm 22 in the sealed tank main body 22, and the outside of the rubber diaphragm 22 has air for pressure control in the tank main body 22. Or it is composed of an air chamber filled with nitrogen gas, the inside of the rubber diaphragm 22 is composed of a water chamber for receiving the piping water (expansion water) flowing out of the circulation pipe 10 and outflow. In the case of a diaphragm expansion tank having such a rubber diaphragm 22, air or nitrogen gas is separated from the plumbing water by the rubber diaphragm 22 and is not directly contacted. There is an advantage that can significantly reduce the problem.

However, in the conventional cooling and heating system having such an expansion tank, since the expansion tank 20 is directly connected to the circulation pipe 10, the heat of the expanded pipe water (expansion water) is transferred to the expansion tank (20). It is delivered as it is. In particular, when the temperature of the expanded water is a high temperature (100 ℃ or more) in the case of the diaphragm expansion tank having a rubber diaphragm 22, there is a risk that the rubber diaphragm 22 is deformed or broken by heat. In addition, even when the temperature of the expanded water is excessively low (-5 ° C. or less), there is a fear that damage due to exceeding the limit temperature of the rubber diaphragm 22 may occur. In addition to such thermal damage, the rubber diaphragm 22 may be damaged or burst due to excessive pressure or other factors of the expansion water.

When the rubber diaphragm provided in the expansion tank is damaged in this way, the expanded water stored in the rubber diaphragm leaks out of the rubber diaphragm, and as a result, the expansion tank cannot perform its function so that the pressure control of the circulation system becomes impossible. However, there is a danger of the expansion tank exploding due to the pressure of the leaked water. However, even if the leak occurs outside the rubber diaphragm as described above, since it is generated inside the expansion tank, it is impossible to detect the leak from the outside, thereby preventing early detection of a dangerous situation. Therefore, a situation in which a safety device capable of real-time detection of leakage due to damage to the rubber diaphragm in the expansion tank and displaying it outside is required.

The present invention was devised to solve the problems of the conventional diaphragm expansion tank as described above, and by detecting in real time the leakage caused by the damage of the rubber diaphragm provided in the expansion tank in real time to the malfunction of the expansion tank It is equipped with a leak detection function that protects the circulation system and prevents accidents such as explosion of the expansion tank due to pressure increase due to corrosion of the tank body due to leaked water and melt of compressed air due to loss of expansion tank function. It is an object to provide a diaphragm expansion tank.

The diaphragm expansion tank according to the present invention for achieving the object as described above, the sealed tank body in which air is accommodated; A rubber diaphragm provided inside the tank body and accommodating the water flowing out from the circulation system; A first pressure probe for detecting pressure in the upper region inside the tank body; A second pressure probe for detecting pressure in the inner lower region of the tank body; Leak detection to detect the difference in pressure detected from the first pressure probe and the second pressure probe, and if there is a difference between both pressures, determines that the water contained in the rubber diaphragm has leaked and displays the determination result outside. Means;

Here, it is preferable that the first pressure probe is installed at a height higher than or equal to the middle point of the tank body height, and the second pressure probe is installed at the bottom of the tank body.

The leak detection means detects the pressure in the upper portion of the tank body delivered from the first pressure probe and the lower portion of the lower portion of the tank body transferred from the second pressure probe to detect a difference value between the two pressures. Wow; A microcomputer that receives a difference value of the pressure detected by the differential pressure sensor and determines that a leak occurs when a difference exists between the two pressures; A display unit which displays a leak determination result of the microcomputer; And a warning device for issuing an alarm to the outside when it is determined that a leak occurs in the microcomputer.

Here, the first pressure probe, the second pressure probe and the differential pressure sensor may be installed inside the tank body, and the microcomputer and the display unit may be installed outside the tank body.

In addition, the microcomputer pre-stores the water level data of the tank body according to the difference between the pressure of the tank body upper region delivered from the first pressure probe and the pressure of the tank body lower region delivered from the second pressure probe, and the water level data It is preferable to determine the water level of the tank body corresponding to the difference value of the actual pressure transmitted from the differential pressure sensor based on the output.

In addition, the leak detection means preferably further comprises a communication module for transmitting the information determined by the microcomputer to a remote place.

According to the present invention as described above, by detecting in real time the leakage of the rubber diaphragm in the expansion tank and the degree of leakage occurs in real time by displaying and alerting to the outside, to quickly prepare for the malfunction of the expansion tank It protects the circulation and prevents accidents such as explosion of expansion tank in advance.

1 is a block diagram of a conventional conventional heating and cooling system,
2 is a block diagram of an expansion tank having a leak detection function according to the present invention,
3 is a block diagram showing the configuration of the leak detection means according to the present invention,
4 is a view showing a preferred installation configuration of the leak detection means according to the present invention.

Hereinafter, the specific configuration of according to the present invention will be described in detail with reference to the preferred embodiments and the accompanying drawings.

As shown in FIG. 2, the diaphragm expansion tank 20 according to the present invention includes a tank main body 22, a rubber diaphragm 24, and a leak detection means 100. As shown in (a) of Figure 2, the rubber diaphragm 24 may be configured to be connected to the expansion tube (10b) in the upper side of the tank body 22, as shown in (b) of FIG. Likewise, the tank body 22 may be configured to be connected to the expansion pipe 10b in the lower side. The tank body 22 and the rubber diaphragm 24 have the same configuration as the conventional diaphragm expansion tank 20, and a detailed description thereof will be omitted. Hereinafter, the specific configuration of the present invention will be described.

The leak detection means 100 is a means for detecting the leakage of water stored in the rubber diaphragm 24 into the air chamber between the rubber diaphragm 24 and the tank body 22, the upper and lower parts of the tank body 22 If there is a pressure differential in the zone, a leak is considered to have occurred.

Typically, the space between the expansion tank 20, the tank body 22 and the rubber diaphragm 24 is filled with air or nitrogen (hereinafter, referred to as "air") that is a compressive fluid, the expansion tank Since the tank body 22 of 20 is hermetically sealed, the pressure between the tank body 22 and the rubber diaphragm 24 is represented by the pressure of the filled air, which is in all areas inside the tank body 22. Will do the same.

However, if water leaks from the rubber diaphragm 24 and water fills the air chamber between the tank main body 22 and the rubber diaphragm 24, since water rises from the lower region of the tank main body 22, In the lower section of the tank body 22, the pressure is further increased by the head pressure of water.

Therefore, the leak detection means 100 measures the fluid pressure in the upper region and the lower region of the tank body 22 and determines that the leakage occurs when a pressure difference occurs. As such, in order to measure the pressure of the upper and lower sections of the tank body 22, the leak detection means 100 is provided with a first pressure probe 30 and a second pressure probe 40.

The first pressure probe 30 connects the leak detection means 100 and the upper region of the tank main body 22, so that the pressure in the upper region of the tank main body 22 is transferred to the leak detection means 100. 22) A probe that guides the fluid in the upper zone. The second pressure probe 40 connects the leak detection means 100 and the lower region of the tank main body 22 so that the pressure in the lower region of the tank main body 22 is transferred to the leak detection means 100. (22) A probe that guides fluid in the lower zone. Here, the upper section and the lower section of the tank body 22 are divided based on the midpoint of the height of the tank body 22, but the first pressure probe 30 is above the midpoint of the height of the tank body 22. Once installed, the second pressure probe 40 is preferably connected to the bottom surface of the tank body 22 so as to detect a change in pressure even when a small amount of water leaks.

Here, the air existing in the upper region of the tank body 22 is introduced into the first pressure probe 30 and is delivered to the leak detection means 100. In addition, air existing in the lower section of the tank body 22 is introduced into the second pressure probe 40 and is delivered to the leak detection means 100, and when the leaked water is leaked, the leaked water is leaked. 100).

3 is a block diagram illustrating a specific configuration of the leak detection means 100. As shown, the leak detection means 100 includes a differential pressure sensor 110, the microcomputer 120, the display unit 130 and the communication module 150.

The differential pressure sensor 110 is a sensor provided at the ends of the first pressure probe 30 and the second pressure probe 30 to detect a difference between the pressure in the upper region of the tank body 22 and the pressure in the lower region.

The microcomputer 120 receives the pressure difference value detected from the differential pressure sensor 110 to determine whether there is a difference between the pressure in the upper region of the tank body 22 and the pressure in the lower region, and the difference between the two pressures. If present, it is determined that a leak occurs, and the display unit 130 displaying whether the leak is externally and controls the alarm device 140 to issue an alarm upon leakage.

On the other hand, the microcomputer 120 is preferably configured to calculate and calculate the amount of water leaked in addition to determining whether or not the leakage occurs. To this end, the microcomputer 120 is the pressure of the upper portion of the tank body 22 is delivered from the first pressure probe 30 and the pressure of the lower portion of the tank body 22 transferred from the second pressure probe 40 The water level data of the tank body 22 according to the difference is stored in advance, and the water level of the tank body 22 corresponding to the difference value of the actual pressure transmitted from the differential pressure sensor 110 is determined and output based on the water level data. It is preferred to be programmed in advance.

The display unit 130 is a means for displaying whether or not the water leakage value determined by the microcomputer 120 and the water level inside the tank body 22 is preferably composed of a display window such as LCD. In addition, the alarm device 140 is a means for issuing an alarm when a leak occurs, it is preferable that the alarm device to be configured with a buzzer or a lamp that sounds an alarm to the outside. The communication module 150 transmits the information determined by the microcomputer 120 to a remote location, that is, an external manager terminal or a central control device, and covers wireless or wired or network communication means.

On the other hand, Figure 4 shows another installation configuration of the leak detection means 100 according to the present invention. As shown, the first pressure probe 30, the second pressure probe 30, and the differential pressure sensor 110 of the leak detection means 100 may be installed in the tank body 22. In addition, the microcomputer 120, the display unit 160, and the communication module 180 are installed outside the tank body 22, and the output signal line of the differential pressure sensor 110 is drawn out to the outside and connected to the microcomputer 120. do. Through such a configuration, the first pressure probe 30, the second pressure probe 40, and the differential pressure sensor 110 are not exposed to the outside, thereby ensuring a space around the tank body 22, and also providing pressure for each pressure probe. It is possible to reduce the error of the pressure due to the length of the.

As described above, according to the present invention, by measuring the differential pressure between the upper region and the lower region of the tank body 22, it is determined that the leakage occurred when the differential pressure occurs, by checking the expansion tank 20 in advance to prevent a large accident By converting and displaying the water level of the leaked water from the differential pressure, it is possible to accurately identify and cope with the leak state and the leak amount from the outside.

So far, the present invention has been described in detail with reference to the embodiments of the present invention, but the scope of the present invention is not limited thereto, and will include the embodiments and the substantial equivalent range of the present invention.

20: expansion tank
22: tank body
24: rubber diaphragm
30: first pressure probe
40: second pressure probe
100: leak detection means
110: differential pressure sensor
120: micom
130: display unit
140: alarm device
150: communication module

Claims (6)

A closed tank body in which air is accommodated;
A rubber diaphragm provided inside the tank body and accommodating the water flowing out from the circulation system;
A first pressure probe for detecting pressure in the upper region inside the tank body;
A second pressure probe for detecting pressure in the inner lower region of the tank body;
Leak detection to detect the difference in pressure detected from the first pressure probe and the second pressure probe, and if there is a difference between both pressures, determines that the water contained in the rubber diaphragm has leaked and displays the determination result outside. A diaphragm expansion tank comprising means. The method of claim 1,
The first pressure probe is installed at a height above the midpoint of the tank body height, the second pressure probe is a diaphragm expansion tank, characterized in that installed on the bottom of the tank body. The method according to claim 1 or 2,
The leak detection means includes: a differential pressure sensor for detecting a pressure difference between the two pressures by sensing a pressure in the upper portion of the tank body transferred from the first pressure probe and a lower portion of the tank body transferred from the second pressure probe; A microcomputer that receives a difference value of the pressure detected by the differential pressure sensor and determines that a leak occurs when a difference exists between the two pressures; A display unit which displays a leak determination result of the microcomputer; Diaphragm-type expansion tank comprising an alarm for warning the outside when it is determined that the leak occurs in the microcomputer. The method of claim 3, wherein
The first pressure probe and the second pressure probe, and the differential pressure sensor is installed in the tank body, the microcomputer and the display unit diaphragm expansion tank, characterized in that installed on the outside of the tank body. The method of claim 3, wherein
The microcomputer pre-stores the water level data of the tank main body according to the difference between the pressure of the tank main body upper region transferred from the first pressure probe and the pressure of the tank main lower region transmitted from the second pressure probe, and based on the water level data. Diaphragm expansion tank characterized in that for outputting by determining the level of the tank body corresponding to the difference value of the actual pressure transmitted from the differential pressure sensor. The method of claim 3, wherein
The leak detection means further comprises a communication module for transmitting the information determined by the microcomputer to the remote diaphragm expansion tank.

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