KR100868069B1 - Apprautus for auto-supplying replenishing water to Priming tank - Google Patents

Abstract

The present invention relates to a priming tank replenishing water automatic supply device, and more particularly, to a priming tank replenishing water automatic supply device to prevent the external air flow into the pump.

Priming tank replenishing water automatic supply device according to the present invention, the cooling water inlet pipe 101, the cooling water discharge pipe 102 and the air discharge pipe 110 is formed on one side, the buoy sensor 120 for detecting the level of the cooling water inside Priming tank 100 is installed;

The supplementary water pressurized by the lowering of the piston 210 installed at the upper portion of the priming tank 100 and installed to move vertically along the inner wall is discharged to the priming tank 100 along the supplemental water discharge pipe 220. This is made, the internal air of the priming tank 100 is introduced into the upper space of the piston 210 along the air discharge pipe 110, the piston 210 when the replenishment water is introduced by the opening of the replenishment water inlet pipe 240 The supplementary water tank 200 is configured to be raised and discharged to the outside through the air discharge pipe 230, the internal air of the priming tank 100 introduced into the upper space of the piston 210; And a pressurizing valve 310 installed at an upper portion of the supplemental water tank 200 and a pressurizing rod 320 fixed to press the piston 210 upper portion of the supplemental water tank 200 by being drawn out from a lower portion of the pressurizing valve 310. It includes a pressurizer 300 having a).

Priming tank, make-up water, make-up water tank, cooling water, make-up water supply

Description

Priming tank replenishing water to Priming tank {Apprautus for auto-supplying replenishing water to Priming tank}             

1 is a block diagram of a general cooling water supply device to which a conventional priming tank automatic water supply device is applied.

Figure 2 is a schematic diagram showing the configuration of the priming tank automatic water supply device according to the present invention.

Figure 3a and 3b is a cross-sectional view showing the operating state of the buoy sensor installed in the priming tank according to the present invention, respectively.

<Explanation of symbols for the main parts of the drawings>

Priming tank 101 ... Cooling water inlet pipe

102 Cooling water discharge pipe 110,230 Air discharge pipe

120 Buoy sensor 121 Main unit

122. Internal body 123 ... Electrolyte

124 Electrodes 200 Refill Water Tank

210 ... piston 220 ... Supplement water discharge pipe

240.Refill water inlet pipe 310 ... Pressure valve                 

300 ... Pressurizer 320 ... Pressure rod

321 ... indicator 330a, 330b ... limit switch

The present invention relates to a priming tank replenishing water automatic supply device, and more particularly, to a priming tank replenishing water automatic supply device to prevent the external air flow into the pump.

Generally, a cooling water supply is installed on the ground to supply the cooling water to the upper part which needs cooling.

As shown in FIG. 1, the cooling water supply device has a pump 3 connected to the motor 2 to supply the cooling water stored in the groundwater tank 1 to the upper side, and the cooling water pressurization action at the start of the pump 3 is effectively performed. A priming tank 4 is provided to fill the pump 3 with cooling water at all times, and a priming tank supplement water is supplied to supply replenishing water when the cooling water is insufficient in the priming tank 4 on one side of the priming tank 4. The device 5 is installed.

The priming tank 4 is provided with a coolant inlet pipe 6 connected to the groundwater tank 1 on one side of the upper portion, and an air discharge pipe 7 through which air in the priming tank 4 is discharged to the outside, and on the lower side of the priming tank 4. The cooling water discharge pipe 8 through which the cooling water introduced into the tank 4 is discharged is installed. Cooling water discharge pipe (8) is connected to the pump (3), the cooling water discharge pipe (9) for supplying the cooling water introduced through the cooling water discharge pipe (8) to the upper portion where a cooling device (not shown) is installed. ) Is installed.

The initial priming tank 4 is in a state where a certain amount of cooling water is accommodated, and at this time, the pump 3 is in a state filled inside by the cooling water introduced through the cooling water discharge pipe 8 of the priming tank 4. After that, when the pump 3 is operated by the driving of the motor 2 and the cooling water flows into the pump 3 side through the priming tank 4, the pressure inside the priming tank 4 decreases and the pressure is relatively decreased. Cooling water stored in the elevated tank is introduced into the priming tank (4) through the coolant inlet pipe (6). At the same time, the cooling water introduced into the pump 3 is pressurized and discharged to the upper cooling device side through the cooling water discharge pipe 9 of the pump 3.

On the other hand, the priming tank replenishment water supply device 5 is installed in the upper portion of the priming tank (4) is connected to the replenishment water inlet pipe (5a) and the replenishment water inlet pipe (5a) is connected so that the replenishment water flows into the priming tank (4) A valve 5b is provided.

In the priming tank supplemental water supply device 5 having the above configuration, the coolant is not smoothly supplied from the water tank 1 to the priming tank 4, and the level of the coolant contained in the priming tank 4 is the coolant discharge pipe 8. In order to prevent external air from flowing into the pump 3 as it is lowered, the valve 5b is opened to introduce supplemental water into the priming tank 4, and in this process, the internal air of the priming tank 4 is supplied. It is discharged to the outside through the air discharge pipe (7). After the replenishment water is sufficiently introduced, the valve 5b of the replenishment water inlet pipe 5a is closed and the inflow of the replenishment water is blocked.

In particular, when the above cooling water supply device is installed in the coke-gun type fire extinguishing system installed at a high place of 20m-30m above the ground, when external air flows into the pump 3, the cooling occurs due to the pressure drop in the pump 3 Since the supply of the cooling water to the device is not made smoothly, the cooling fan of the cooling device is stopped and the cooling fan is stopped, thereby preventing the inflow of external air necessary for gas combustion from the outside, thereby stopping the combustion. This causes a serious consequence that the gas accumulating inside the cooling system is a risk of explosion and the heat of the coke is not properly cooled, the production of power and steam is stopped.

However, in the conventional priming tank refill water supply device 5 described above, both the replenishment water supply and the internal air discharge operation of the priming tank 4 are performed by a worker manually.

That is, when the manager always checks the cooling water level of the priming tank 4 with the naked eye and the replenishment water is insufficient, the replenishment water inlet pipe 5a and the air discharge pipe 7 are simultaneously opened to supply the replenishment water into the priming tank 4. Discharge of the internal air of the priming tank 4 is made, followed by the inconvenience of having to repeat the series of closing the valves 4 and 7 after the replenishment water is sufficiently supplied.

Therefore, with the conventional priming tank replenishing water supply device 5 which is operated manually, it is difficult to precisely control the time of replenishment water supply and its supply amount, so that it is difficult to effectively prevent external air from entering the pump 3. Occurs.

The present invention has been made to solve the above problems, and an object of the present invention is to provide an automatic priming tank replenishing water supply device in which replenishing water is automatically supplied into a priming tank so that external air is not introduced into the pump.

In order to achieve the above object, the present invention, the cooling water inlet pipe, the cooling water discharge pipe and the air discharge pipe is formed on one side, the priming tank is installed in the buoy sensor for detecting the level of the cooling water inside;

The supplementary water pressurized by the lowering of the piston installed at the upper part of the priming tank and installed to move vertically along the inner wall is discharged to the priming tank along the replenishing water discharge pipe, and the air inside the priming tank is discharged from the air discharge pipe. The water flows into the upper space of the piston, and when the supplemental water is introduced by the opening of the supplementary water inlet pipe, the piston rises and the internal air of the priming tank introduced into the upper space of the piston is discharged to the outside through the air discharge pipe. Tank; And

And a pressurizer having a pressurizing valve installed at the top of the make-up water tank and a pressurizing rod fixed to press the piston upper portion of the make-up water tank by being drawn out from the lower part of the pressurizing valve.

One end of the air discharge pipe is installed in the upper portion of the priming tank, the other end is installed in the upper portion of the replenishment water tank, one end of the replenishment water discharge pipe is installed in the lower portion of the replenishment water tank, the other end and the priming tank Connected.

In addition, the buoy sensor has a hollow sealed body which is fixed to the inside of the priming tank and fixed to the cooling water to change the inclination according to the water level, and the inner cylinder body fixed to change the inclination as the body is inclined inside the body It is provided inside the inner cylinder so as to be electrically connected to the main body, the electrolyte injected into the inner cylinder and the pressure valve, and provided with a pair of electrode rods in contact with the electrolyte is limited as the inner cylinder is inclined.

In addition, the pressurizer according to the present invention is attached to one side of the pressure bar, the indicator indicating the state of movement of the pressure bar, and a pair of limit switches for limiting the movement range of the pressure bar by detecting contact with the indicator further Can be installed.

The features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings. Prior to this, the terms or words used in the present specification and claims are defined in the technical spirit of the present invention on the basis of the principle that the inventor can appropriately define the concept of the term in order to explain his invention in the best way. It must be interpreted to mean meanings and concepts.

As shown in FIG. 2, the priming tank 100 is connected to a coolant inlet pipe 101 through which a coolant is introduced from a water tank in which coolant is stored, and a coolant discharge pipe through which the coolant introduced into the priming tank 100 is discharged. 102 is installed. Cooling water inlet pipe 101 is connected to the upper portion to facilitate the introduction into the priming tank 100, the cooling water discharge pipe 102 is preferably installed below the priming tank 100 to facilitate the discharge.

In addition, the upper portion of the priming tank 100 is installed with an air discharge pipe 110 for discharging the internal air to the outside in order to prevent the pressure in the priming tank 100 is increased by the introduction of the cooling water, the internal air is discharged In order to prevent backflow in the process, a non-return valve 112 is installed.

In addition, the buoy sensor 120 is installed in the priming tank 100 to be suspended by the connection member 127 to detect the level of the coolant.

As shown in FIGS. 3A and 3B, the part sensor 120 is fixed to the main body 121 and the main body 12 in which the inclination changes according to the level of the coolant hanging on one side of the priming tank 100. A pair of electrode rods 124 in which contact with the electrolyte 123 is restricted as the inner cylinder 122, the electrolyte 123 injected into the inner cylinder 122, and the inner cylinder 122 are inclined. )

The main body 121 is a waterproof body sealed to have a buoyancy is suitable, while hanging in the surface of the cooling water while suspended in the priming tank 100, the inclination of the main body 121 is changed in accordance with the cooling water level.

To this end, the connecting member 127 connecting the main body 121 and the priming tank 100 is preferably a chain or a flexible strap so that the movement of the connected main body 121 is free.

An inner cylinder 122 having an electrode rod 124 electrically connected to the pressure valve 300 is fixed to an inner upper center of the main body 121, and the inner cylinder 122 has the same direction as the main body 121 is inclined. Inclined to The electrolyte 123 is injected into the inner cylinder 122, and the electrolyte 123 flows to one side as the inner cylinder 122 is inclined, and any one of the electrode rods 124 of the pair of electrodes 124 and 124 is inclined. Contact is limited. On the other hand, in the inner cylinder 122, it is preferable that a blocking wall 125 isolating the electrode rod 124 and the electrode rod 124 in order to prevent the flow when the electrolyte 123 flows. The blocking wall 125 evenly distributes the inside of the inner cylinder 122 to the left and right, and a flow path 126 through which the electrolyte 124 can flow is formed at the lower end.

As shown in FIG. 2, the replenishment water tank 200 installed at the upper portion of the priming tank 100 is connected to the air discharge pipe 110 of the priming tank 100 on the tank upper portion, and the air discharge pipe 110 is disposed. An air discharge pipe 230 for discharging the internal air of the priming tank 100 introduced into the replenishment water tank 200 to the outside is installed. In addition, the replenishment water tank 200 is connected to the replenishment water inlet pipe 240 through which the replenishment water discharge pipe 220 for replenishing water discharged to the priming tank 100 is installed.

Inside the replenishment water tank 200, a piston 210 which is raised and lowered according to the operation of the pressurizer 300 installed on the replenishment water tank 200 is installed. As the piston 210 descends, the replenishment water in the replenishment water tank 200 is pressurized, and the replenishment water is introduced by the pressure difference in the replenishment water tank 200 generated while rising. Therefore, the piston 210 should be closely installed so that supplemental water and air do not leak through the contact surface with the supplemental water tank 200.

On the other hand, the air discharge pipe 110, the supplemental water inlet pipe 240, the supplemental water discharge pipe 220 are provided with solenoid valves (111,241,221) for controlling the flow of the fluid in the pipe.

The pressurizer 300 installed at the upper portion of the supplemental water tank 200 is provided with a pressure valve 310 operated according to a signal from the buoy sensor 120 and a pressure valve 310 installed below the pressure valve 310. According to the operation of having a pressure rod 320 is moved.

The pressure valve 310 is installed vertically apart from the make-up water tank 200, for this purpose, a leg 301 fixed to the top of the make-up water tank 200 is formed at the lower end of the pressure valve 310.

The pressure rod 320 is vertically connected between the pressure valve 310 and the piston 210 installed in the replenishment water tank 200 to move up and down according to the operation of the pressure valve 310 to move the piston 210 up and down. Let's do it.

On the other hand, one side of the pressure bar 320 is attached to the display body 321 indicating the state of movement of the pressure bar 320, the movement range of the pressure bar 320 by detecting the contact with the display body 321. A limiting pair of limit switches 330a and 330b may be further installed. The limit switches 330a and 330b are separated by an upper limit switch 330a installed at an upper limit point at which the display body 321 is moved and a lower limit switch 330b installed at a lower limit point, respectively. You can limit the range of movement.

On the other hand, reference numeral 128 is a wire for electrically connecting the electrode and the pressure valve.

Referring to the operation of the priming tank 100 automatic replenishment water supply device of the present invention having such a configuration as follows.

As shown in FIG. 2, when the cooling water is smoothly supplied from the water tank to the pump side, the normal water level is maintained in a state where the cooling water is sufficiently stored in the priming tank 100, and thus the buoy sensor 120 in the priming tank 100 is maintained. ) Is floating in a state in which the main body 121 is inclined on the surface of the coolant.

As shown in FIG. 3A, when the main body 121 of the buoy sensor 120 is inclined, the inner cylinder 122 is inclined in the same direction as the main body 121 and injected into the inner cylinder 122. Since the electrolyte 123 flows in one direction and contacts only one of the electrodes 124 and 124 inside the inner cylinder 122, no current is generated.

At this time, the replenishment tank 200 is in a state where the replenishment water is sufficiently stored, and therefore, the piston 210 in the replenishment tank 200 is positioned above the replenishment tank 200.

However, as shown in FIG. 3B, when the coolant is not smoothly introduced into the priming tank 100, the coolant discharge pipe 102 is larger than the amount of the coolant flowing through the coolant inlet pipe 101 of the priming tank 100. As the amount of cooling water discharged to the pump side increases, the cooling water level in the priming tank 100 is lowered. When the water level of the cooling water is lowered, the buoy sensor 120 in the priming tank 100 detects this and sends a supplementary water supply signal to the pressure valve 310. That is, when the coolant level is lowered, the buoy sensor 120 rises upright from the water surface, and is gradually upright. The electrolyte 123 inside the buoy sensor 120 is also gradually moved through the flow path 126 of the blocking wall 125. As a result, current is generated while contacting with both electrodes 124 and 124. This current sends a supplemental water supply signal to the pressure valve 310 electrically connected to the electrode 124. Therefore, the water level change of the cooling water in the priming tank 100 can be precisely checked by the buoy sensor 120.

When the supplemental water supply signal is input to the pressure valve 310, the pressure valve 310 is opened, and at the same time, the air discharge pipe 110 of the priming tank 100 and the supplement water discharge pipe 220 of the supplement water tank 200 are provided. The solenoid valves 111 and 221 installed in all are opened.

When the pressure valve 310 is opened, the pressure rod 320 introduced into the pressure valve 310 is pushed toward the lower side by the force of the compressed air introduced into the pressure valve 310 and the supplemental water tank 200. Lower the piston 210 inside. When the piston 210 is lowered, the replenishment water in the lower space of the piston 210 is pressurized, and the pressurized replenishment water is discharged to the priming tank 100 along the open replenishment water discharge pipe 220, thereby cooling water level of the priming tank 100. Is raised.

As the coolant level rises, the internal air of the priming tank 100 flows into the upper space of the piston 210 in the replenishment tank 200 along the air discharge pipe 110. At this time, the non-return valve 112 installed in the air discharge pipe 110 prevents the reverse flow phenomenon that may occur in the process of flowing into the piston upper space.

On the other hand, when the replenishment water is sufficiently supplied to the priming tank 100 and the coolant level recovers the normal level, the buoy sensor 120 is inclined while floating on the coolant surface to stop the current supply and stop supplying the replenishment water to the pressure valve 310. Will be sent. In addition, when the display bar 321 of the pressure bar 320 is in contact with the lower limit switch 300a while the pressure bar is lowered (320), the supplementary water supply stops to the pressure valve 310 by the lower limit switch 300a. A signal can be input.

When the supplementary water supply stop signal is input to the pressure valve 310, the pressure valve 310 is closed and the lowering operation of the piston 210 is stopped, and the air discharge pipe 110 and the supplement water tank 200 of the priming tank 100 are closed. The solenoid valves 111 and 221 installed in the supplemental water discharge pipe 220 are closed. Accordingly, the inflow of air into the priming tank 100 and the replenishment water discharge to the priming tank 100 are stopped, while the air discharge pipe 230 and the replenishing milk of the replenishment tank 200 are stopped. The solenoid valves 231 and 241 installed at the inlet pipe 240 are opened.

As a result, the replenishment water flows into the replenishment tank 200 through the open replenishment water inlet 240 at a high pressure. The piston 210 and the pressure rod 320 are raised by the strong inflow pressure of the supplement water, and the supplement water tank until the indicator 321 attached to the pressure rod 320 contacts the upper limit switch 330b. Flows into 200. At this time, the internal air of the priming tank 100 introduced into the upper piston is discharged to the outside through the air discharge pipe 230 in the process of raising the piston.

Thereafter, the replenishment water is sufficiently introduced into the replenishment water tank 200 so that the indicator 321 of the pressure rod 320 is in contact with the upper limit switch 330b, or the level of the cooling water of the priming tank 100 is increased so that the buoy sensor 120 When the current is cut off, the solenoid valve 111 installed in the air discharge pipe 110 of the priming tank 100 is opened, and the air discharge pipe 230 and the refill water inlet pipe 240 and the refill water of the refill water tank 200 are opened. By closing the solenoid valves 231, 241, and 221 installed in the discharge pipe 220, the standby state is maintained until the next supplementary water supply signal is generated.

According to the priming tank replenishment water automatic supply device of the present invention configured as described above, the supply of the replenishment water as well as the supply time of the replenishment water is automatically checked by the buoy sensor installed in the priming tank at all times Therefore, the continuous replenishment water supply work is performed without any stoppage of the facility or the manager's separate action, so that external air flows into the pump can be prevented.

Claims (4)

A priming tank 100 in which a coolant inlet tube 101, a coolant discharge tube 102, and an air discharge tube 110 are formed at one side, and a buoy sensor 120 is installed to detect a level of the coolant inside; The supplementary water pressurized by the lowering of the piston 210 installed at the upper portion of the priming tank 100 and installed to move vertically along the inner wall is supplemented with the priming tank 100 along the supplemental water discharge pipe 220. When the water discharge is made, the internal air of the priming tank 100 is introduced into the upper space of the piston 210 along the air discharge pipe 110, when the supplement water is introduced by the opening of the supplement water inlet pipe 240 The piston 210 is raised and the supplementary water tank 200 is configured to be discharged to the outside through the air discharge pipe 230, the internal air of the priming tank 100 introduced into the upper space of the piston 210; And A pressure rod fixed to pressurize the upper portion of the piston 210 of the supplemental water tank 200 by being drawn out from the pressure valve 310 and the lower portion of the pressure valve 310 installed on the top of the supplemental water tank 200. Priming tank automatic water supply device comprising a pressurizer 300 having a (320). The method of claim 1, One end of the air discharge pipe 110 is installed on the top of the priming tank 100, the other end is installed on the top of the replenishment water tank 200, one end of the replenishment water discharge pipe 220 is the replenishment water tank Installed in the lower portion of the 200, the other end of the automatic priming tank replenishing water supply, characterized in that connected to the priming tank (100). According to claim 1, The buoy sensor 120, A hollow hermetic body 121 which is fixed to the inside of the priming tank 100 so that the inclination changes according to the level of cooling water; An inner cylinder 122 fixed inside the main body 121 so that the inclination changes as the main body 121 is inclined; An electrolyte solution 123 injected into the inner cylinder body 122; And A pair of electrode rods installed inside the inner cylinder 122 so as to be electrically connected to the pressure valve 310, and the contact with the electrolyte 123 is limited as the inner cylinder 122 is inclined. Priming tank replenishment automatic supply device characterized in that it has a (124,124). The method of claim 1, wherein the pressurizer 300, The moving range of the pressure bar 320 is attached to one side of the pressure bar 320 by detecting a contact between the display body 321 and the display body 321 indicating the state of movement of the pressure bar 320. Priming tank replenishing water automatic supply, characterized in that a pair of limit switches (330a, 330b) is further installed to limit the limit.

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