KR200381429Y1 - drainage water tank - Google Patents

Abstract

The present invention relates to a drainage basin in which water is supplied and stored in connection with a water purification plant. The drainage basin is designed to reduce and maintain the drainage pressure of the water through an outlet pipe at an appropriate level to improve leakage or durability of related equipment. It is related to this, the water is supplied through the inlet pipe and is provided with an outlet pipe for drainage, the inlet pipe and the outlet pipe is a flow meter is installed and equipped with a water level meter (10); An auxiliary water tank 20 formed in the water tank and separated from the water tank by the partition wall and connected to the outflow pipe; A valve 26 formed on one side of the auxiliary water tank to open and close; It is located in the auxiliary water tank to detect the water level of the auxiliary water tank (23); consisting of the drain water tank to the technical gist that the water is discharged to the outflow pipe by the water pressure of the auxiliary water tank to regulate the water level of the auxiliary water tank The present invention also relates to a drainage tank characterized in that the auxiliary tank is formed outside the main tank.

Description

Drainage water tank

The present invention relates to a drainage that is installed in the highlands, the water is supplied and stored, and drains the water to the jersey. The present invention relates to a drainage tank that can be solved.

Conventionally, since there is no method of controlling the water pressure of the water flowing out of the drainage, the water pressure supplied to the water supply area is changed according to the level of the drainage, and thus the supply water pressure fluctuates largely and is often supplied with excessive water pressure.

As such, when the water pressure of the drained water is high, the impact acting on the pipe network increases, so that leakage occurs in the pipe network, and in the pipe where the water leak occurs, there is a problem that the flow rate decreases and the flow rate decreases.

There was such a problem, but until now, the water pressure at the time of drainage is controlled by adjusting the drainage level. However, the drainage level control method has problems in securing the proper quantity and maintaining the pump (increasing the number of pump operations), and its effect is limited.If the drainage level is lowered, the drainage basin level function can be achieved for stable water supply in case of emergency. There was a problem that became impossible.

In addition, the application of this method to control the water level in the drainage basin also causes a conflict between the water purification plant and the waterworks plant. In other words, the water purification plant tries to increase the amount of water to the drainage at night time to reduce the electricity cost, but the waterworks office wants to keep the drainage level as low as possible because the water level is increased due to the high water level in the midnight hours. There is a problem that the interests of both parties are in conflict.

Therefore, the present invention is to solve the above problems, regardless of the level of the water tank in the sump so that the water tank can always be stored up to the highest level, and by installing a separate auxiliary tank to control the water level in the auxiliary tank outflow It is an object of the present invention to provide a drainage tank that enables proper control of drainage pressure when draining through a pipe.

The present invention for achieving the object as described above, the water is supplied through the inlet pipe is provided with an outlet pipe for drainage, the inlet pipe and the outlet pipe is a flow meter is installed and equipped with a water level meter; An auxiliary tank formed in the main tank and separated from the main tank by a partition wall and connected to an outlet pipe; A valve formed at one side of the auxiliary water tank to open and close; It is located in the auxiliary tank and an auxiliary water level meter for detecting the water level of the auxiliary tank; consisting of a drain water tank having a technical gist that the water is drained to the outflow pipe by the water pressure of the auxiliary water tank to regulate the water level of the auxiliary water tank.

In addition, the present invention is the water supply is supplied through the inlet pipe and the inlet pipe and the flow meter is installed with a water level meter; An auxiliary tank formed on an outer surface of the main tank and connected to an outlet pipe having a flow meter; A valve installed at a boundary wall of the main tank and the auxiliary tank to open and close the valve; It is located in the auxiliary tank is an auxiliary water level for detecting the water level of the auxiliary tank; is configured to regulate the water level of the auxiliary tank to a drain tank having a summary that the water is drained to the outlet pipe by the water pressure of the auxiliary tank.

The drain water tank relates to a drain water tank having a flow control device configured to receive a data of a flow meter, a water level meter, and an auxiliary water level, and to control a valve to maintain a level of the water level of the auxiliary water tank.

In addition, the main water tank relates to a drainage tank characterized in that a plurality of dividing walls to guide the flow of water is formed.

The drainage tank of the present invention has a separate auxiliary tank inside or outside the ordinary main tank and adjusts the water level in the auxiliary tank so that a constant water pressure can always be discharged to the outlet pipe regardless of the water level change of the main tank. It is characterized by the presence.

Hereinafter, the drainage tank will be described in detail through a preferred embodiment of the present invention.

1 is a schematic cross-sectional view showing the shape of a sump according to an embodiment of the present invention.

It is made of a concrete structure of a rectangular shape and the inside is formed with an empty space portion for the fresh water, and a plurality of ditch walls 11 is provided. An auxiliary water tank 20 is provided at one side of the main water tank 10 as described above. The water tank 10 may be manufactured in a concrete structure as in the present example, but in addition, it may be manufactured in a material such as plastic.

In addition, the ditch wall 11 serves to guide the flow of water introduced into the water tank 10 and is arranged to be staggered to allow water to flow in a zigzag direction as shown. By doing this, it is possible to solve the problem that the water of a certain part does not flow well.

The auxiliary tank 20 is separated from the main tank 10 by the partition 25 and has a structure in which the water of the main tank flows into the auxiliary tank through the valve 26.

In more detail, the inlet pipe 12, which is a pipe connected to the water purification plant, is connected to the upper portion of the main water tank 10, and a water level gauge 13 capable of detecting a water level is installed. And the inlet pipe 12 is attached to the flow meter 14 that can check the flow rate flowing into the water tank (10).

An outlet pipe 15 through which water is drained is formed at one lower portion of the main tank 10 forming the drainage basin, and the auxiliary tank 20 is positioned thereon. That is, the outlet pipe 15 is completely separated from the main water tank 10 by the auxiliary water tank 20, and the flow pipe 14 is also provided with a flow meter 14 for checking the flow rate of drainage.

In the auxiliary water tank 20, an auxiliary water level gauge 23 for level adjustment is also provided, and a valve 26 is installed at one side of the partition wall 25 forming the auxiliary water tank. In accordance with the opening and closing operation of the valve 26, the water stored in the water tank 10 is introduced into the auxiliary water tank as necessary.

In addition, although the installation position of the said valve may be located in the partition 25 like this example, it can also install in the conduction wall 11 which forms one wall of an auxiliary tank.

Opening and closing of the valve 26 is opened and closed by the valve opening and closing control device 30 provided outside the water tank, which is operated according to an electrical signal to control the opening and closing of the valve.

More preferably, it is suitable to maintain not only the water level of the auxiliary water tank but also the water level of the main water tank, and for this purpose, a flow control device 40 capable of controlling the entire drainage tank is provided.

2 is a block diagram in which the level control in the sump tank is made by the flow control device.

The flow control device 40 is connected to the flow meter 14, the water level meter 13, the auxiliary water level meter 23, and the valve control device 30, and the data provided from each is collected and programmed in the flow control device. PID control and necessary data are stored. Through the PID control, the opening and closing of the valve provided in the auxiliary tank is controlled to adjust the amount of water flowing into the auxiliary tank, and the opening rate of the valve is transmitted to the hydraulic control device through the potentiometer to perform repeated PID control.

The PID control mentioned is a commonly used control method among the automatic control methods, where P stands for Proportional, I stands for Integral, and D stands for Differential. Flexible control is possible by controlling these three combinations. .

That is, in the case of simple ON / OFF control, since the control operation amount is between 0% and 100%, the change of the operation amount is too big and becomes a control that achieves severe irregularities near the actual target value, whereas PID control quickly follows the target value. It shows the characteristics to be made.

Therefore, by receiving various data from the flow control device and PID control to open and close the valve so that the water level in the auxiliary water tank maintains the target value, it is possible to form and maintain stable water pressure by applying the preceding control that reacts quickly to the change in flow rate.

This PID control method is a well-known technique widely used throughout the industry, so further detailed description will be omitted and will be readily understood by those skilled in the art.

The water level of the water tank is also controlled by the flow control device, so that when the water drops below a certain level, the water can be filled up to the highest level of the water tank. The pump operates according to the signal sent from the flow controller and the water from the purification plant is supplied.

In the present invention, the operation of the flow meter, the water gauge, and the control of various valves can be achieved by known techniques, and thus, further detailed description thereof will be omitted.

Valve control in the auxiliary tank is good to be controlled by dividing the morning, afternoon and night time, and unless the specific control command, the flow control device changes the opening rate of the valve by morning, afternoon, and night time according to the water level. The valve is operated according to the amount of water, that is, the water level, so that efficient control can be achieved.

Next, the drainage tank according to the present invention as another form will be described and refer to FIG. 4.

As in the above-described embodiment of the present invention, the main tank 10 and the auxiliary tank 20 are provided. In particular, the auxiliary tank is located outside the main tank and has a structure connected to the main tank.

An inlet pipe 12 is formed above the water tank 10, and a flow meter 14 is installed in the inlet pipe, and a water gauge 13 is provided inside the water tank. In addition, a plurality of conductive walls 11 are arranged inside the water tank to induce the flow of water.

As shown, a separate auxiliary tank 20 is connected to the lower end of the outer right side of the main tank (10). An interior of the auxiliary water tank forms an empty space so that water can be filled, and an auxiliary water level gauge 13 for detecting a water level is installed. The valve 26 is provided on the boundary wall 25a between the main water tank and the auxiliary water tank. In addition, an outlet pipe 15 for supplying water to the water supply area is connected to a lower surface of the auxiliary water tank 20, and the outlet pipe is also provided with a flow meter 14.

The valve 26 is opened and closed by the valve opening and closing control device 30, the amount of water flowing into the auxiliary water tank from the main tank according to the opening and closing degree. In addition, as in the case of the embodiment is provided with a flow control device which is connected to the flow meter or water level meter installed in the main water tank and the auxiliary water tank to perform PID control to properly control the opening and closing of the valve.

By opening and closing the valve by the PID control, the water level of the auxiliary tank does not greatly deviate from the target value range, which causes the water pressure generated by the auxiliary tank to be almost constant.

According to the water level control method of the drain water tank as described above, there is an effect of reducing the leakage amount as follows.

That is, when the water level decreases by 1m, the water pressure decreases by 0.1Kg / ㎠ and the water pressure in the water supply area is about 3.0 Kg / ㎠ when the existing drainage tank is used, but according to the drain water tank of the present invention, the water pressure in the water supply area is 2.7Kg / ㎠ It has a decompression effect of about 0.3 Kg / cm 2.

The accompanying Figure 3 corresponds to an explanatory diagram to help understand the amount of water leakage due to such a reduced pressure.

In general, the rate of leakage reduction is calculated as follows.

Leakage calculation formula

(1) Q = c.a.P ^0.5 : Theoretical formula

Here, Q is the leakage amount, c is the coefficient by the shape coefficient of the leak hole, a is the area of the leak hole, P is the water pressure.

(2) Q = c · a ㆍ P ^1.15 : Experimental formula (1997. Japan Water Association)

(3) Q = ^{c.a.P 1.18} : UK

In equation (1), the exponential 0.5 power is calculated by assuming that the shape of the leak point is circular. It was obtained as a field experiment considering the flow. The exponent 1.18 in the equation (3) is an empirical equation obtained from the United Kingdom.

Since it is impossible to derive the exact relationship between the actual leakage and the water pressure, in this example, the formula (2) is applied.

According to the formula (2), when the water pressure decreases from 3.0 Kg / ㎠ to 2.7 Kg / ㎠, the leakage decreases by 11.4%.

The leakage reduction rate calculation is as follows.

Thus, the rate of leak reduction is

(3.0 ^1.15 - 2.7 ^1.15) is a (3.134 3.537) / 3.537 = 11.4% / 3.0 = ^1.15.

In addition, the increase in flow rate increases the flow rate by 1.4% when the water pressure decreases the water pressure to 2.7 Kg / cm2 in the region where the water leakage rate is 15% and the average water pressure of 3.0 Kg / cm2.

Flow rate increase rate is calculated as follows.

Flow rate = Flow rate (rate) / Supply * 100 (%)

 As described above, according to the drainage tank according to the present invention, there are many advantages and effects unlike conventional ones.

First, by reducing the water pressure in the pipe to the water supply area, the existing leakage can be reduced by more than 10%, and the occurrence of new leakage can also be reduced.

Second, lowering the existing high water pressure to the proper water pressure has the effect of reducing the failure of water facilities and increasing the service life. In other words, even if the pressure increases less than 1 Kg / ㎠ in the drainage pipe, the frequency of breakage of the pipe increases rapidly and the breakage frequency of the long-term pipe decreases even with slight pressure reduction. , Korea Water Resources Corporation)

Third, by increasing the height of the tank in the reservoir, the land area can be reduced due to the increase of low water volume, and when the maximum water level is increased by 50% (eg 5m → 7m), the area of the tank can be reduced by about 30%.

Fourth, there is an effect of reducing the power cost by reducing the amount of water to be sent to the drainage, the reduction of the number of changes to the drainage pumping pump operation, and the reduction of power costs by increasing the use of midnight power.

In addition, high water pressure increases the amount of water used to increase the budget input of the public sector due to the increase in water supply facilities such as the expansion of the supply landscape, and the use of more water than required by the consumer, thereby reducing such unnecessary losses.

1 is a schematic cross-sectional view showing the shape of a sump according to an embodiment of the present invention.

2 is a block diagram in which the water level control in the sump tank is made by the flow control device.

3 is an explanatory diagram that helps to understand the decrease in leakage due to pressure reduction.

Figure 4 is a cross-sectional view showing an embodiment of a drain tank according to another embodiment of the present invention.

<Description of Major Symbols Used in Drawings>

10: water tank 12: inlet pipe

13: water meter 14: flow meter

15: outlet pipe 20: auxiliary water tank

23: water level gauge 25: bulkhead

26: valve 30: valve opening and closing device

40: flow control device

Claims (4)

A water tank (10) provided with water through an inlet pipe and having an outlet pipe for drainage, and an inflow pipe and an outlet pipe having a flow meter and having a water level meter; An auxiliary water tank (20) formed in the water tank (10) and separated from the water tank by a partition (25) and connected to the outflow pipe (15); A valve (26) formed at one side of the auxiliary water tank (20) for opening and closing; And an auxiliary water level meter (23) positioned inside the auxiliary water tank (20) to sense the water level of the auxiliary water tank, wherein the water is drained to the outlet pipe by regulating the water level of the auxiliary water tank. water tank. A water tank (10) which is supplied with water through an inflow pipe, and has a flow meter installed therein and a water level meter; An auxiliary water tank (20) formed at an outer surface of the main water tank and connected to an outlet pipe having a flow meter; A valve (26) provided at the boundary wall (25a) of the main water tank and the auxiliary water tank to open and close; And an auxiliary water level meter (23) positioned inside the auxiliary water tank to detect the water level of the auxiliary water tank, wherein the water is drained to the outlet pipe by regulating the water level of the auxiliary water tank. The said sump tank of Claim 1 or 2, And a flow control device (40) which receives the data of the flow meter, the water level gauge, and the auxiliary water level, and controls the valve to maintain the level of the auxiliary water tank at a constant level. The water tank according to claim 3, wherein A drainage tank characterized in that a plurality of dike walls (11) are formed to guide the flow of water.