KR100209486B1 - Water service installation by air pressure - Google Patents

Abstract

The present invention miniaturizes the use of the pneumatic water supply system while allowing both the water supply and the fire supply to be used. That is, the water supply system and the fire water supply system are connected to each other using a hydraulic gate valve to supply water to the water tank and control and control. Panels were used for both systems.

In addition, the bogies required in the feedwater tank are automatically viewed by the PLC controller regardless of the starting and braking of the pump in the PLC controller to realize the miniaturization of the feedwater tank, which adopts the automatic view of the jet pump.

In addition, the present invention can be used in all buildings, such as high-rise buildings and large-capacity water supply buildings, and does not require reinforcement of columns or beams due to the installation of high water tanks, thereby reducing construction costs and reducing construction periods. At the same time, it prevents secondary pollution of water quality, which not only contributes to national health, but also completely resolves the lack of water pressure in the upper part of the building.

Description

Miniaturized life, firefighting water supply system

1 is an installation circuit diagram of the present invention.

2 is a structure of a hydraulic gate valve of the present invention.

3 is a structure of the jet system of the present invention.

4 is a principle of the electric control system of the present invention.

5 is a water supply device for exclusive use of the present invention.

6 is a fire fighting water supply device of the present invention.

7 is a nitrogen automatic boosting fire water supply apparatus of the present invention.

* Explanation of symbols for main parts of the drawings

BYG- (SX): Water supply system for both living and fire fighting SB: Domestic water supply system

XB: Fire Fighting Water Supply System GS: Life Supply Pipe

D: Butterfly Valve H: Smorensky Check Valve

CS: Water Tank ZS: Main Check Valve

SJ: Hydraulic gate valve BX: Fire fighting pump

QS: Pressure supply tank DYx: Electric contact pressure gauge for fire fighting

DYs: Electric contact pressure gauge for daily use HB: Pneumatic pressure check valve

QW: Water level controller PB: Jet pump BYG- (S): Water supply for living

BYG- (X): Fire Fighting Water Supply Unit BYG-

(W): Nitrogen boosting fire water supply system

LJ: FLOW SWITCH DF: Solenoid Valve

Bo: Auxiliary Pump 21: Valve Body

22 bushing 23 differential piston

25, 26: asbestos packing 31: absorption tube

32: part 33: fountain tube

34 Absorption chamber 35 Reduction tube

36: magnifying tube

The present invention relates to a pneumatic water supply device which enables both a reduced life water supply and a fire fighting water supply. More specifically, the purpose of the pneumatic water supply system is to make it possible to use both water supply and firefighting water, while miniaturizing the water supply system. The control panel allows both systems to be used in common.

In addition, the required view in the water supply tank is automatically viewed from the PLC controller regardless of the pump starting and braking in the PLC (PROGRAMMABLE LOGIC CONTR OLLER) controller to realize the miniaturization of the water supply tank. It was.

In addition, the present invention can be used in all buildings, such as high-rise buildings and large-capacity water supply buildings, and it is not necessary to reinforce the pillars or beams of the buildings due to the installation of the high water tank, thereby reducing construction costs and at the same time reducing the air. By preventing secondary pollution of the water quality, it not only contributes to national health, but also makes it possible to completely eliminate the lack of water pressure in the upper part of the building.

[Technical field to which the invention belongs and the prior art in that field]

The present invention is to enable the miniaturized living water supply and firefighting water to be used as a combination of most conventional high-rise buildings are connected to the living water supply pipe and the firefighting water supply pipe to the high-priced tank, respectively, using the respective water supply pump and firefighting water pump. Water was drawn from the underground reservoir and water was supplied to the two pipe lines using the level difference in the elevated tank. This gravity water supply method saves electricity and the facility is relatively simple. Until now, the gravity water supply method has realized automatic fire fighting by gravity even in the event of power failure. However, since the high water tank should have the water storage function of living water supply and fire water supply at the same time, it must be designed considering sufficient safety strength when designing the structure of a high-rise building due to its large weight. Not only can't get water supply pressure, but there are many inconveniences such as not being able to shower due to lack of water pressure. In addition, there was a significant problem that adversely affects public health due to secondary pollution of drinking water. So, in recent years, many attempts have been made to replace high water tanks using various water supply devices at home and abroad. And several times at home and abroad, the nitrogen automatic booster pressure fire fighting water supply system was tested. However, long-term sealing and storage of high pressure nitrogen could not be solved, and there have been no successful cases.

[Technical problem to be achieved]

The present invention is to reduce the weight due to the high water tank on the roof by installing in the pump room of the high-rise basement to have a miniature living and fire fighting water supply performance in order to solve the conventional problems, the biggest problem of the fire hydrant pressure of the upper part of the building It is possible to solve the shortage problem, to realize the initial evolution, to prevent the secondary pollution of drinking water, and to have the characteristics such as no electricity consumption of the fire fighting system at all times when a fire does not occur. For the purpose of convenience, the pressure and water supply system combined with fire fighting is called BYG- (SX) type for convenience.) By increasing or decreasing the pump based on the BYG- (SX) type and changing the piping line appropriately, it is a BYG-S type. ) And fire fighting water supply device (BYG- (X) type) and nitrogen automatic boosting fire water supply device (BYG- (W)) are both within the scope of the present invention. Will.

In addition, this compact life and fire-fighting water supply system is operated without electricity, that is, the hydraulic pressure and air pressure control principle, adopting the automatic system of nitrogen boosting pressure, it has the capability of high pressure fire fighting equipment. This completely solved the firefighting problem of high-rise buildings even under blackouts.

[Configuration and Function of Invention]

The present invention will be described in detail with reference to the accompanying drawings.

1 is a life, fire-fighting water supply device of the present invention, namely BYG- (SX) type, which consists of a four-part system: a domestic water supply system, a fire fighting pump water supply system, a pneumatic water supply tank auxiliary system, and an electric control system.

Herein, the living water supply system is called an SB system. Two to three pumps (Bo, Bs ₁ and Bs ₂ ) are connected in parallel by the amount of water supply on the water supply pipe (Gs), and these pumps are all compact pumps and have a relatively smooth HQ characteristic. Reduce the head change by driving at. Most installations of SBs generally have two to five pumps connected in parallel, the first of which is an auxiliary pump and the flow rate is about half of the main life pump. In addition, a lock lever wafer type butterfly valve (D) is installed at the inlet and outlet of each pump, and a Smolensky check valve (H) is installed between the valve and the pump. Is connected to the water storage tank (CS) by using an absorption tube, and one end of the life water supply pipe (Gs) is connected to the household pipe of each household through the main check valve (Zs), and the other end is a hydraulic gate. It is connected to the firefighting water supply pipe Gx via the valve SJ.

The fire fighting water supply system (XB) has two to four fire fighting pumps (Bx) connected in parallel by the amount of fire flow rate on the fire fighting water supply pipe (Gx), one of which is a spare pump. Before and after each pump, a butterfly valve and a check valve are installed as in the life pump water supply system (Gs), and at one end of the fire water supply pipe (Gx), a main check valve (Hx) and a flow switch (LJ) And T tube G ₄ are connected, and the three outlets of the T tube G ₄ are provided with gate valves Zx of the same standard. Two of them are connected to the annular pipe of the fire pipe network, and the other one is connected to the storage tank (CS) using a return pipe (Gh) to circulate the fire water in the underground water tank regularly. Operate fire fighting facilities and inspect their condition. In addition, the outlet of the first fire pump (Bx ₁ ) was connected to the control port of the hydraulic gate valve (SJ), a pipe (GK) divided in front of the check valve. This valve is a BYG- (SX) type dedicated valve whose structure is assembling the bushing 22 tightly to the thread on the upper part of the valve body 21 as shown in FIG. 2 and the asbestos packing of type 0 inside the bushing. 25) and (26) insert the differential piston (23), the lower middle of the differential piston (23) is a thick flat piston rod on both ends, and the bushing upper part is tightly closed by the valve cover (24) When (GK) is connected to the hole in the center of the valve cover 24 to start the first fire pump Bx ₁ , the pressure water flows into the upper part of the differential piston 23 to move the piston downward so that the valve Close the hole to prevent fire water from entering the living system. However, when the fire pump is not operated, there is no water pressure in the upper part of the piston so that the living water at the bottom of the valve body enters the differential piston 23 to move the hydraulic gate valve (SJ) to be open all the time. As a result, there is almost no wear of type 0 asbestos packing, so the service life is very long.

In addition, the pneumatic water supply tank auxiliary system installs two electric contact pressure gauges (DY) on the top of the tank body centering on the miniaturized pneumatic water supply tank (QS), among which the pressure gauges (DYs) are living water supply systems (SB). The pressure gauge DYx controls the fire fighting system XB. And is, install a liquid level controller (QW) Heavy portion of the tank body and the water supply pipe on the bottom of the tank body is a pneumatic holding pressure check valve (HB) and the T-tube G3 a via connected to one another and ipsugu of the jet pump and the T-tube of G ₃ The other end is connected to the filter (GL) to the fire water supply pipe (Gx). As shown in FIG. 3, the configuration of the jet pump PB first inserts the inlet of the fountain pipe 33 into the absorption chamber 34, assembles the parts 32, and connects it with the absorption tube 31. The other end of 34 is inserted into the reduction tube 35 and connected to the expansion tube 36 and the bowl. Then, a waterproof solenoid valve (DF) is installed at the outlet of the expansion pipe 36 and connected to the absorption pipe of the living pump. Here, when the solenoid valve DF is closed to block the outlet of the enlarged tube 36, the water flowing into the absorber tube 31 is rotated and absorbed by 180 degrees while pressing the reduced tube 35 through the fountain tube 33. The bogie tank BQ above it is pressed from the seal 34. On the contrary, when the solenoid valve DF is opened, the pressure water introduced into the absorber tube 31 is restricted by the flow twice at the outlet of the component 32 and the fountain tube 33, and then the shrinkage tube 35 at a high speed. Since the vacuum is generated in the absorption chamber 34, the water of the bogie tank BQ is sucked up to the absorption chamber 34 and enters the expansion tube 36 together with the injected water, and the kinetic energy of the mixing is The water is drained to the reservoir as it is changed to static pressure. At this time, the ratio of the suction water amount and the injection water amount within the same time is referred to as the flow rate ratio q of the jet pump. This flow rate ratio changes significantly with water pressure. Therefore, the present invention adopts a simple method of changing the diameter dx of the component 32, so that the pressure can be applied to other water supply equipment, thereby reducing the product type and specification of the jet pump to a minimum. In addition, the intake valve (XQ) and the check valve (Ho) are installed at the top of the bogie tank (BQ), and the pipe is connected to the air pressure tank (QS) to replenish air and water.

The electrical system is as in FIG. At the heart of this system is a tiny programmable controller (PROGRA MMABLE LOGIC CONTROLLER) controller. The parameters input from each system described above are used to connect each contact of the PLC controller in the electric panel with two electric contact pressure gauges (DY2 and DYx), water level controller (QW), electric switch (NK1), and blow switch ( It is connected to the contact point related to relay (Kx) and reservoir tank low level indicator (SW) in the middle of LJ) and supplies 24V DC to the PLC controller. And at the output terminal, it was connected with circuits such as electric pump, electromagnetic contactor (CJi) of electric machine, solenoid valve (DF) and low water tank low level alarm. All of them used 220V AC power. The automatic switching of the two power supplies, the actuation of the anti-pressure program of the large power fire pump, the operation of the alarm sound and the alarm sound when the fire occurs, and the operation state of each major part do not belong to the scope of the present invention. Does not. In addition, only the operating principle of the control part of the logic logic process of the PLC controller will be described briefly. Combining FIG. 1 to FIG. 4, the operation principle of the living, fire fighting water supply system (BYG- (SX)) type of the present invention will be described.

First, the water supply consumption (Qu) is less than 1/2 of the discharge flow rate of the auxiliary pump, that is, the pulsation water supply process in the range of Qu ≤ Qo / 2. Lower than the air pressure in the pressure supply tank (QS), the water in the tank opens the opening / closing door of the pressure check valve (HB) to the end, enters the T-tube G₃, and passes through the hydraulic gate valve (SJ) from the filter (GL) again. Water is supplied to the pipe GS. Due to the water supply by air pressure, the air pressure in the air pressure supply tank (QS) drops to the lower contact pressure set in the electric contact pressure gauge (DYs) according to the water level, and when the pump operating pressure PK, the pressure gauge sends pump operation command SKs and the PLC controller Because of this signal, the flow rate of the auxiliary pump Bo is greater than the used water supply flow rate, so that the remaining water enters the pneumatic water supply tank QS through the hydraulic gate valve SJ, the filter GL, and the T-tube G ₃ . At this time, if the pressure of GS is higher than the pressure tank pressure Pk, the check valve in the holding pressure check valve (HB) on one side of the T-tube G₃ is closed, and the flow of water enters the jet pump (PB) and rotates 180 degrees. While filling the bogie tank BQ through the absorption chamber 34, the check valve Ho is opened to supply water to the atmospheric pressure water supply tank QS. As the water is replenished in this manner, the pressure in the tank gradually increases, and when the pressure rises to the Pt pressure which is the upper point of the electrical contact pressure gauge DYs, the electrical contact pressure gauge DYs issues the pump stop command Sts. At this time, PLC controller starts for a certain time input to PLC controller even after receiving this signal, then stops auxiliary pump and repeats the above-mentioned pressure draining process. When the pressure in the pressure tank drops to Pk, the pump is operated. Look again. This process of watering is called a pulsating watering process. At this time, the PLC controller detects the time T of the air pressure draining process every time and compares it with the time [Ts] previously entered in the PLC controller. If T [Ts], the pump continues to start the pump without stopping the pump. To control the number of pulsations of 1 to 2 times per hour. Conversely, if T [Ts], the pump stops only when the time Ts input to the PLC controller is rotated to limit the number of pulsations to 4th-6th orders. By adopting this method, it is possible to reduce the volume of the QS tank to a minimum.

The stable water supply in all flow zones of Qu Qo / 2 means that when the water supply is increased, the auxiliary pump (Bo) does not pulsate again within the flow range between Qo / 2 and Qo, and according to HQ characteristics. Stable automatic flow control When the water supply volume Qu becomes large, the pressure in the water supply pipe Gs decreases due to the lowering of the pump head H. Then, the water in the air pressure supply tank (QS) is introduced into the water supply pipe (GS) in accordance with the air pressure draining process described above. When the air pressure in the tank drops to the pump working pressure Pk of the electrical contact manometer (DYs), the PLC controller immediately starts one of the two main pumps (eg: Bs ₁ ) to stop the operation of the auxiliary pump. When the water supply exceeds the set flow rate of one main pump, the electric contact pressure gauge (DYs) issues the start command Sks again, and the PLC controller starts the second main pump again to increase the water supply flow rate.

On the contrary, when the water consumption Qu is reduced, the pump head is increased according to the HQ characteristics, and the pressure in the water supply pipe (GS) increases, so that some of the water in the pipe presses the tank according to the water replenishment process of the air pressure supply tank (QS) described above. As a result, the pressure in the tank is also increased. When the pump stop pressure Pt of the electrical contact pressure gauge DYs rises, the PLC controller stops the main pump (for example, Bs ₁ ) first started by the pump stop command Sts sent by the pressure gauge. If the water supply continuously decreases, the electric contact pressure gauge (DYs) again sends a pump stop signal to stop the last one main pump and immediately start the auxiliary pump (Bo). If the water supply Qu is changed near the set flow rate Qo of the auxiliary pump, the PLC controller causes one of the two main pumps to start alternately.

The automatic viewing process of the injection pump-viewing system first starts when the needle of the electric contact pressure gauge (DYs) moves from the lower contact point to the upper contact point and reaches the upper contact point whenever the feed water pump is started. The valve is opened by electricity to generate the injection process of the injection pump (PB) described above, and the water in the bogie tank is sucked into the drain pipe. At this time, the check valve Ho is closed, and the pressure in the bogie tank drops below atmospheric pressure so that the outside air opens the intake valve XQ and is sucked into the bogie tank. At this time, when the bogie tank is filled with air, the PLC controller closes the solenoid valve (DF) and changes the water flow direction of the injection pump 180 degrees, enters the bogie tank through the absorption chamber 34 and compresses the air therein. Close the (XQ) and open the check valve (Ho) to replenish the pneumatic water supply tank (QS) once and then add water. If for some reason the compressed air in the air supply tank (QS) is very low and the water level is high, for example, when the present invention is installed for the first time, electricity is supplied to the switch (NK1) so that the PLC controller can open the solenoid valve (DF) at intervals of several tens of seconds. ) If the water level in the tank drops to the water level controller (QW) -limited level by repeating the above automatic view process, it sends a stop signal to stop. At this time, the switch NK1 is cut off to the normal automatic viewing state.

The fire water supply process causes all equipment, including the fire switch or blow switch (LJ), to operate the relay (Kx) once a fire occurs. Then, the PLC controller starts the first fire pump Bx1 and at the same time shuts down the circuit of the solenoid valve DF to stop the view. When the fire pump is started, the fire water in the reservoir tank is sucked up to the first fire pump, increased and then flows into the fire pump (GX) to close the hydraulic gate valve (SJ). At this time, the fire water flows along the firefighters, passes through the check valve (Hx) and the blow switch (LJ), passes through the T-shaped pipe G4, and fills the fire water in the firefighters at each level and the firefighters in each floor. Have pressure. If the amount of fire water is higher than the discharge flow rate of the first fire pump, the pump operating pressure Pkx is detected when the pressure of the air pressure water tank QS drops to the lower contact point of the electrical contact pressure gauge DYx, as in the principle of SB. The pump operation signal Skx is sent, and the PLC controller starts the second fire pump Bx2 to increase the water supply flow rate. Here, even if two pumps are started, if the water supply flow rate is insufficient and the needle of the electric contact pressure gauge (DYx) does not leave the lower limit, the PLC controller starts the preliminary fire pump Bx3 to terminate the fire. If the amount of fire is reduced during the fire, the pressure in the air supply tank (QS) increases and rises to the upper contact point of the electrical contact pressure gauge (DYx). Then, the pump stop pressure Ptx at the upper contact point is detected and the detected signal is sent to the PLC controller which sends the pump stop signal Stx to stop the second fire pump first. After that, the spare pump Bx3 is stopped again. However, the first fire pump Bx1 can only be stopped manually after the fire. As described above, the life and fire fighting water supply device BYG- (SX) of the present invention has the following technical features.

First, the hydraulic gate valve (SJ) was adopted to connect the two systems of the living water supply system (SB) and the fire fighting system (XB) to each other. The system (XB) and the fire pipe network were to maintain a constant pressure at all times. The lowest pressure of the SB is the pump working pressure Pk. Where Pk is generally

However, the water in the fire pipe network does not flow. Therefore, the static pressure before the rooftop firefighting

Therefore, the showerhead needs in the field of living are fully met the requirement to be greater than 0.7 kg / m 2. In addition, in the fire fighting pipe network of the fire fighting system (XB), pressure water can always be supplied from the living water supply side without adding a separate pressure so that no extra electric energy is consumed. Since the water pressure of the rooftop tank is sufficient, the rooftop tank and two firefighters were connected as shown in FIG. In the rooftop tank, only the fire water is stored so that the high water tank can be small, so that the weight of the high water tank can be reduced, and the secondary water can prevent the secondary pollution and the length of the granular pipe of the water supply pipe can be reduced.

Second, in the pulsation water supply period of the auxiliary pump, the pressure control drainage time is detected by using a PLC controller to control the pulsation order and method. In fact, the QS tank has a function of a certain capacity of the container, so that the water flow rate at the time of actual measurement can be known so that it can be controlled again by the actually detected pulsation order and method. Therefore, the pressure drainage in each pressure drainage process is almost similar and the volume calculation method is as follows.

V/T는 실제의 급수사용량이다. 그래서 T [Ts]는 어느 순간에서의 용수유량이 설정유량보다 크다는 것을 설명하며, 정지시킬 필요가 없어 1시간당 기동과 정지과정의 운전횟수를 감소시킨다. T ≥ [Ts]는 용수유량이 설정된 유량보다 작다는 것을 설명하는 것으로 이는 운전횟수를 적절히 가속화하고 용수가 정지하면 적절한 때에 운전을 정지시킬 수 있어 펌프의 발열과 고장을 방지한다. 따라서 펌프의 맥동횟수는 더 이상 기압태크의 용적크기와 펌프의 유량에 달려있지 않고 사용자의 상황에 의하여 마음대로 PLC제어기 내에 맥동횟수를 설정하고 제어시킬 수 있다.Drain time T, ie Qu =

V / T is the actual water consumption. Thus, T [Ts] explains that the water flow rate at any moment is greater than the set flow rate and does not need to be stopped, thus reducing the number of times of starting and stopping processes per hour. T ≥ [Ts] explains that the water flow rate is less than the set flow rate. This speeds up the operation time properly and stops the operation at the appropriate time when the water stops, thus preventing the heat generation and failure of the pump. Therefore, the pulsation frequency of the pump is no longer dependent on the volume size of the air pressure tag and the flow rate of the pump, and the pulsation frequency can be set and controlled in the PLC controller at will according to the user's situation.

In this way, the miniaturization of the pneumatic tank can be achieved, and the size of the pneumatic water supply system is made very small, and the life of the water supply system is maximized and the cost is greatly reduced. No such innovative technology can be found in conventional water supplies. In addition, the booster of BOOSTER type water supply system used in each country has a large pump difference and the number of pulsations is 20-100 times per hour. The pressure tank has been miniaturized by various measures such as assembling and assembling a blower switch and a timer. However, this method has a high electrical energy consumption and a method that fails to extend the life of the water supply equipment. It is not a product made with the latest technology.

Third, by installing a jet pump (PB) and a miniaturized bogie tank (BQ) at the lower part of the side of the miniaturized pneumatic water supply tank, the water flow in the bogie tank (BQ) is changed automatically when the solenoid valve (DF) is opened and closed. The new automatic viewing method is adopted to Compared with the traditional high-level gravity viewing method, this new viewing method is not limited by the high and low level of the underground reservoir, and it is possible to view by the dynamic power without relying on the large power feed pump, exhaust valve, solenoid valve. It is possible to simplify the structure and reduce the demand for components, thereby reducing the cost. If the time for supplying electricity to the solenoid valve DF is changed by reducing the magnitude dx of the diameter of the component 32 and the PLC controller, the present invention can also be used for water supply devices having different pressures and flow rates.

3 혹은 4.5㎜, PDF-40 전자밸브 등 규격이 서로 다른 BYG-(SX)형 겸용장치 혹은 생활, 소방배관의 질소자동승압장치 등과 같은 다른 장치에도 적용하여 사용할 수 있으며 QS시스템의 소량생산방식을 대량 생산방식으로 전환하여 원가를 대폭적으로 절감하고 제품품질을 높힐 수 있다.Thus, by adopting the present invention, all the pressure tank auxiliary systems can be standardized to be the same standard. For example, (QS) tank volume: 0.22㎥, BQ tank volume: 5L, diameter of water spray hole of PB pump:

It can be applied to other BYG- (SX) type devices such as 3 or 4.5mm, PDF-40 solenoid valves, etc., or other devices such as nitrogen boosters for life and fire pipes. By switching to mass production, the cost can be greatly reduced and product quality can be improved.

Fourth, any type of pneumatic water supply system or high water tank system should always maintain the required water pressure on the top floor of the building, and the maximum water flow rate Qmax in the pump system must be the instantaneous flow rate. If not, water shortage may occur. Therefore, the instantaneous flow rate should be 4 to 6 times greater than the daily average water supply. If the capacity of one pump is the instantaneous capacity, it will be a low efficiency operation in the low flow area and the electric waste will be very large. Therefore, the present invention adopts a method of parallel or replacement operation of the main water feed water pumps Bs ₁ and Bs ₂ during water supply (high water supply time water supply) near the pump stop. Therefore, the auxiliary pump (Bo) was operated near the flow rate zone below Qmax / 4. Therefore, the feed pump can operate stably in small pressure difference and high efficiency area. However, in the water supply zone where the water supply Qu is less than Qu ≤ Qmax / 8, the auxiliary pump Bo pulsates the water a very small number of times to save energy. In particular, XB system does not consume electricity at all, adopts injection pump (PB) method that consumes very little electricity, adopts high efficiency viewing method, and maintains pressure in water supply tank in case of power failure. Designed pressure check valve (HB) is adopted to achieve breakthrough energy savings.

Fifthly, the present invention has adopted the following measures to increase the quality of the product to improve the reliability and superiority of the water supply device.

1) Highly reliable PLC controller is adopted.

2) The always-operated bogie check valve (Ho), intake valve (XQ) opening and closing doors, and reverse check valves of the pressure check valve (HB) are all made of special rubber packing, which adopts an extremely small cross-section sealing method, so that It was possible to maintain the sealing performance.

3) The differential piston sealed in the hydraulic gate valve (SJ) and the pressure check valve (HB) is always in a non-moving state so that the zero-type rubber ring does not wear out.

4) The filter (GL) is automatically cleaned by using the principle that the direction of water flow in the T-tube G₃ is always changed to prevent clogging caused by dirt.

5) Install fire check valve (Hk) in the fire water supply pipe (Gx) line to prevent the water in the fire pipe from flowing back to the water supply to prevent contamination of the water supply of the life supply system (SB) in the life supply field. It was. However, the pressure of water in the firefighter is continuously higher than Pk.

6) Install T-shaped pipe G₃ on the fire pipe as shown in Fig. 1, and connect the return drain pipe (Gh) to the underground reservoir at one of them. In addition, the fire water was drained to regularly check the performance of the fire fighting system (XB).

In general, the present invention adopts a hydraulic gate valve (SJ) to connect two systems of the living water supply system (SB) and the fire fighting water supply system (XB) to share the method of the pneumatic water tank auxiliary system and the electric control method. It is possible to make one system that can do it, which completely solves all the problems in the water supply system for the living water and the fire water supply. In addition, since the miniaturization of the air pressure tank was realized, the reliability was higher than that of the conventional product, and the air pressure water tank (QS) system was miniaturized and the standard was unified. And it can be used for water supply equipment of various standards. In other words, the present invention can save energy, at the same time, excellent reliability, cost savings, and can be applied to other water supply devices by applying the principles of the present invention. For example, as shown in FIG. 5, the fire fighting system (XB) can be eliminated, and the configuration can be changed slightly to BYG- (S) type, which can provide daily water supply or dedicated water supply for production equipment. Then, if the water supply system (SB) is removed and one pressure supplement pump (ZB) is installed, the pressure supplement pump (ZB) and the air pressure supply tank (QS) system remain only when the main fire pump is removed according to the principle shown in FIG. As shown in Fig. 7, the BYG- (W) type of firefighter can be changed into a device capable of maintaining a constant pressure, and these belong to the scope of the present invention.

Finally, if the nitrogen automatic boosting system manufactured on the principle of hydraulic pore is installed on this compact fire fighting water supply device, it can automatically boost the power without power for a certain period of time (10-20 minutes). It can be a very good water supply.

Example 1

BYG-V (SX), Life, Fire Fighting Water Supply

Example 2

BYG-2 (S), Home Water Supply System

As described above, the present invention miniaturizes the use of the pneumatic water supply device while allowing both the water supply and the fire supply to be used. That is, the water supply system and the fire supply system are connected to each other using a hydraulic gate valve to supply water. Tanks, electrical and control panels were used for both systems.

The present invention can be used in all buildings, such as high-rise buildings and large-capacity water supply buildings, and there is no need for reinforcement of buildings or beams due to the installation of high water tanks, which can reduce construction costs and shorten construction periods. In addition, it prevents secondary pollution of water quality and contributes to the health of the people, and also makes it possible to completely eliminate the lack of water pressure in the upper part of the building.

Claims (5)

It consists of four parts system: SB, fire pump water supply system (XB), air pressure tank auxiliary system and electric control system, where SB is in the middle of GS water pipe. Connect two to three miniaturized vertical water supply pumps (Bo, Bs ₁ , Bs ₂ ) in parallel, install a butterfly valve (D) before and after them, install a check valve (H) at the pump outlet, and One end of Gs) is connected to the water supply pipe through the main check valve (Zs), and the other end is connected to the fire fighting pipe (Gx) through the hydraulic gate valve (SJ). ) Connects two to four fire pumps and butterfly valves in parallel with the water supply system (SB) on the fire pipe (Gx), one of which is reserved and the first fire pump (Bx ₁ ) exits. Draw piping (GK) from the hydraulic gate valve (SJ) The main check valve (Hx), the blow switch (LJ), and the cross-joint pipe (D ₄ ) are installed at the ends of the fire pipe (Gx) and the gate valves of the same size (ZX) at all three outlets of the pipe. ) Is connected to the annular pipe of two fire extinguishing systems, and the other is connected to the fire storage tank (S) by using a return pipe (Gh), and the pressure tank auxiliary system is a tank centered on a compacted pressure tank. In the upper part of the body, two electric contact pressure gauges (DYs and DYx) are installed, one of which is the electric contact pressure gauge (DYs) controls the living water supply system (SB), and the other is the fire contact water supply system (DYx). (XB), and the water level controller (QW) is installed in the lower and lower part of the tank body, and the water supply pipe at the lower part of the tank body passes through the pneumatic pressure check valve (HB) and the T-shaped pipe G₃ and the suction pipe of the jet pump (PB). The other end of the T tube G₃, It is connected to firefighting water supply pipe (Gx). The solenoid valve (DF) is installed at the outlet of the jet pump, the drain pipe is connected to the suction pipe of the fire pump, and the electric control system has a small PLC controller of the SP series at the terminal. Two electrical contact pressure gauges (DYs and DYx), level controller (QW), switch (NK1), relay (Kx) in the middle of the flow switch (LJ), and the lowest level indicator (SW) of the reservoir tank. In the PLC controller that provides 24V DC electricity inside the PLC controller, circuits such as the magnetic contactor (CJ), solenoid valve (DF) and water tank low level alarm of the electric pump electric machine In connection with this, all the PLC controllers are supplied with 220V AC power. According to claim 1, If the water supply capacity Qu is less than 1/2 of the discharge amount of the auxiliary pump (Bo), the pump is in the pulsation supply process and the PLC controller detects the drainage time T of the water in the air pressure supply tank (QS) every time. Compared with any drainage period [Ts] inputted in the T, if the T [Ts], the PLC controller controls the start and braking frequency of the auxiliary pump one to two times, and if T ≥ [Ts], increase it to four to six times. The air pressure and water supply system for both fire and fire that realized the miniaturization of the air pressure water supply tank (QS), which is commonly used in BYG series water supply equipment with different specifications. The living water supply system (SB) and the fire fighting water supply system (XB) are connected by a hydraulic gate valve (SJ) to form a dedicated gate valve of BYG- (SX) type, which is the upper part of the valve body 21. The screw at the top of the bushing (22) is tight, and the inside of the bushing has a differential piston (23) fitted with a type 0 asbestos packing (25) (26). The middle of the lower part of the differential piston (23) is thin and both ends are coarse. Piston rod, the upper bushing is tightly closed by the valve cover (24) life, fire fighting water supply system. The bogie tank (BQ) having a check valve (Ho) and an intake valve (XQ) is installed at an upper portion of the absorption chamber of the jet pump (PB), and the solenoid valve (DF) is provided at the outlet of the jet pump (PB). The jet pump (PB) first inserts the inlet of the fountain tube 33 into the absorption chamber 34, assembles the asbestos packing with the component 32, connects the absorption tube 31 to the bowl, and absorbs the chamber 34. The other end of the) is inserted into the reduction tube (35) and then connected to the expansion tube (36) with a bowl, a fire fighting water supply for both. The method of claim 1, wherein when the fire fighting system (XB) is removed, the water supply system (BYG- (S)) for production is changed to BYG- (S) type, and one pressure supplement pump (SB) is removed. When ZB) is installed, it becomes a fire-fighting water supply system (BYG- (X)). If the main pump is removed according to this principle, only the pressure supplement pump (ZB) and the QS system remain. Life and firefighting pressure supply system which can be derived from various water supply equipment such as being able to change into a device that can maintain the

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