KR101042676B1 - A jet vacuum system without power - Google Patents

Abstract

The present invention relates to a non-powered pump system for the initial start of the pump, and more particularly, in the conventional vacuum pump system, the electric motor to remove the air inside the pump and to form a vacuum to raise the water at the initial start of the pump Although the conventional vacuum pump system uses excessively high initial capital investment cost, the conventional vacuum pump system has a lot of difficulty in maintenance due to frequent failure of the vacuum pump due to the inflow of foreign matters. Since it was troublesome to have a constant power supply to start, the present invention therefore uses a jet nozzle that does not require a vacuum pump and does not require additional power to solve the above problems. Providing a pump system reduces initial installation and maintenance costs while providing stable It relates to a pump system that enables the vacuum pump system operation.

Description

A jet vacuum system without power}

The present invention relates to a pump system that can be started initially with no power, and more particularly, in order to solve the disadvantages such as frequent failure or replacement of the existing vacuum pump, the pressure change of the water passing through the water inlet of the jet nozzle The present invention relates to a pump system that sucks air into a nozzle into which air is introduced, thereby sucking air in a pump and a vacuum auxiliary tank, thereby enabling an initial start of a pump without additional power.

In the conventional vacuum pump system, it is common to start the pump by using a vacuum pump with an electric motor, for example, in order to build up a vacuum by removing air in the pump to draw up water at the initial start of the pump. It was.

As shown in FIG. 1, such a conventional vacuum pump system 10 generally includes a pump 11, a vacuum pump 12, a vacuum tank 13, and a plurality of pipes connecting them to each other.

In addition, the operation of the conventional vacuum pump system 10 first rotates a motor installed in the vacuum pump 12 to suck air in the vacuum tank 13, and then the pump 11 inside is filled with vacuum. When it becomes water, the pump 11 is driven and it is comprised so that the water which is lower than a pump can be raised and pumped.

As described above, in the conventional vacuum pump system 10 as described above, in order to start the pump 11, which actually serves to pull water up and down, the air inside the pump 11 is first removed to a full state. In order to maintain this initial startable state, a vacuum pump 12 is necessary.

That is, in order to actually pull up water and to pump water, in order to pull up water using the conventional vacuum pump system as described above, first, the vacuum pump 12 is driven to drive air inside the pump 11. The pump 11 could not be started until it was completely removed.

However, the vacuum pump 12 is abrasion due to the friction between the casing and the impeller of the vacuum pump 12, and due to the frequent failure due to foreign matters need to install a spare device to prepare for the failure, the investment cost is excessive. There was a problem such as to occur, and also, there was a problem to secure a separate power for driving it.

Therefore, although the conventional vacuum pump system as described above is necessary equipment for maintaining the pump 11 in the initial startable state, it is necessary to install a spare device in preparation for failure of the vacuum pump 12. Due to the relatively high investment cost and high probability of failure, it was difficult to follow up.

In addition, the conventional vacuum pump system as described above also has the problem that it is necessary to separately provide a power supply equipment of a predetermined size or more to drive each pump.

Therefore, in view of the above, it is desirable to provide a non-powered vacuum pump system using existing equipment to solve the problems of the conventional vacuum pump system described above, but a vacuum pump system that can satisfy all such requirements is still present. Not provided.

Therefore, the present invention was created to solve the problems of the conventional vacuum pump system as described above, by sucking the air into the nozzle into which air is introduced by the pressure change of the water flowing into the water inlet of the jet nozzle inside the pump By sucking air, it is to provide a pump system using a jet nozzle that enables the initial start of the pump without a separate power.

In addition, the present invention, in order to reduce the maintenance cost and operate a stable vacuum pump system, even when two or more pumps are installed, a non-powered pump system that does not require the use of additional power for the shift operation in place of the conventional vacuum pump It is to provide.

In addition, the water pump generally transfers fluid using pipes of small and several tens of meters to several tens of kilometers in length, and even in case of water leakage due to the stoppage of the water pump due to power failure and the pipe breakage. Another object of the present invention is to maintain a constant pressure in a waterway and a water supply line even in the event of a power failure, in view of the fact that all pipelines except a construction section are always filled with a fluid so as to prevent water shock due to a sudden change of state. By converting the residual pressure into the energy of the pump system, it is possible to solve the disadvantages of the failure of the vacuum pump and the motor in the existing vacuum pump system and to provide a separate power supply system. To provide.

In order to achieve the above object, according to the present invention, there is provided a pump for pumping a fluid; A jet nozzle for making the inside of the pump full by vacuum for the initial start of the pump; A vacuum tank is connected between the pump and the jet nozzle, and serves as a buffer tank to maintain a degree of vacuum above a reference level at which the pump can be started even if leakage occurs. The jet nozzle includes: It has two inlet pipe and one discharge pipe, one of the inlet pipe is connected to the vacuum tank through the pipe, the other is connected to the pipe connected to the rear end of the pump through the pipe, the discharge of the pump As the fluid flowing into the inlet pipe connected to the pipe connected to the rear end passes through the venturi tube formed inside the jet nozzle and is discharged to the discharge pipe, the pump is caused by the pressure difference generated by the change in the cross-sectional area of the venturi pipe. The air inside is discharged to the discharge pipe through the jet nozzle and removed through the vacuum tube, so that the pump A pump system, characterized in that is configured to make the inside to the full water state by the vacuum is provided.

In addition, according to the invention, the pump; A jet nozzle for making the inside of the pump into a full state by vacuum for the initial start of the pump, wherein the jet nozzle has two inlet pipes and one outlet pipe, one of the inlet pipes Is connected to the pump through a pipe, and the other is connected to a pipe connected to the rear end of the pump through the pipe, the fluid flowing into the inlet pipe connected to the pipe connected to the rear end of the pump is the jet The air inside the pump is discharged to the discharge pipe through the jet nozzle and removed by the pressure difference generated by the change in the cross-sectional area of the venturi pipe while passing through the venturi pipe formed in the nozzle to the discharge pipe. A pump system is provided, which is configured to bring it to a full state by vacuum.

According to the present invention, there is also provided a pump for pumping fluid; A jet nozzle for making the inside of the pump full by vacuum for the initial start of the pump; A vacuum tank connected between the pump and the jet nozzle, the buffer tank acting as a buffer to maintain a degree of vacuum above a reference level at which the pump can be started even if leakage occurs. The jet nozzle includes two inlet pipes. And one discharge pipe, one of the inlet pipes is connected to the vacuum tank via a pipe, and the other is connected to a pipe connected to a rear end of the pump through a pipe, and connected to a rear end of the pump. As the fluid flowing into the inlet pipe connected to the pipe passes through the venturi pipe formed inside the jet nozzle and is discharged to the discharge pipe, the pressure inside the pump causes the air inside the pump to be discharged by the change in the cross-sectional area of the venturi pipe. By passing through the jet nozzle to be discharged to the discharge pipe is removed, the interior of the pump by vacuum Doedoe configured to create a full water state, and the degree of vacuum detection device for detecting a degree of vacuum of the vacuum tank; A first electric valve for opening and closing an inlet pipe of the jet nozzle connected to the pump; A second electric valve for opening and closing the inlet pipe of the jet nozzle connected to the vacuum tank; When the vacuum degree detecting device transmits that the vacuum degree of the vacuum tank is decreased after the vacuum state is formed, the vacuum sensor of the vacuum tank is opened to receive the air and to remove the air inside the jet nozzle, and then the vacuum degree of the vacuum tank. The second electric valve is controlled so as to open the second electric valve, and when the vacuum sensor detects that the vacuum degree enough to start the pump is transmitted to the vacuum tank, the second electric valve is received. After the control, and then closes the first electric valve to control to maintain a constant vacuum in the entire system; a pump system is provided, characterized in that it further comprises.

Therefore, through the configuration as described above, by pumping the air inside the pump with the jet nozzle by the pressure change of the water to be made while passing through the jet nozzle to make the inside of the pump in a vacuum state, the pump system to enable the initial start of the pump This is provided.

In addition, when the vacuum degree of the vacuum tank decreases after the vacuum state is formed, the air flow inside the jet nozzle is removed by opening the first electric valve, and then the second electric valve is controlled to open, thereby replenishing the vacuum degree of the vacuum tank. A pump system is provided that controls to maintain a vacuum at all times in the system.

According to the description of the present invention, since there is provided a non-powered pump system using a jet nozzle that enables the initial start of the pump without a separate power, compared to the conventional vacuum pump system, the maintenance cost and stable operation of the vacuum pump system This becomes possible.

In addition, according to the present invention, in place of the conventional vacuum pump, it is possible to provide a pump system that does not require the use of additional power for the shift operation even when two or more pumps are installed.

In addition, according to the present invention, even when the pump is stopped due to water shock and power failure, it is possible to quickly recover by the residual pressure of the pipe, and to solve the disadvantages such as failure of the vacuum pump motor by the power in the conventional vacuum pump system In addition, it is possible to provide a pump system that can save energy.

Further, according to the present invention, it is also possible to provide a pump system that maintains the constant vacuum of the entire system by automatically replenishing the vacuum degree of the vacuum tank when the vacuum degree of the vacuum tank is reduced after the vacuum state is formed.

Therefore, according to the present invention, by providing a pump system can eliminate the burden of frequent failures and ongoing maintenance costs of the existing power vacuum pump, save the energy required for power supply of the vacuum pump, water shock and sudden Emergency recovery is possible even in the event of a power outage, making the system safer to use.

Hereinafter, a pump system according to the present invention will be described in detail with reference to the accompanying drawings.

2 shows a schematic configuration of a pump system 20 according to the present invention.

As shown in FIG. 2, the pump system 20 according to the present invention, like the conventional vacuum pump system 10 shown in FIG. 1, includes a pump 11 and a vacuum tank 13, while a vacuum pump is provided. Instead of (12), the point that the jet nozzle 21 is included is comprised.

Referring to the specific operation of the pump system 20 according to the present invention as described above, as follows.

First, a part of the water discharged into the discharge pipe B of the pump 11 flows into the inlet pipe C of the jet nozzle 21 branched from the discharge pipe B of the pump 11.
As is already well known to those skilled in the art, the discharge tube B extends long in the pump 11. In other words, the discharge pipe (B) is filled with a fluid, and the constant pressure is always maintained inside the discharge pipe due to the water head of such a fluid. Passed through C) to the jet nozzle 21.

Continuously, the water flowing into the inlet pipe (C) passes through the venturi tube (not shown) provided in the jet nozzle 21, wherein the change in the cross-sectional area of the venturi tube, specifically the narrow cross-sectional area By passing through a wider cross-sectional area at, the air and water of the pump (11) upper (D) is sucked into the jet nozzle through the pressure difference that will be caused by the flow rate of water, and the discharge pipe (F) through the inlet pipe (E) Is blown out.

Therefore, as described above, the air inside the pump 11 is removed through the jet nozzle 21 so that the inside of the pump 11 is in a full state by vacuum, so that a requirement for starting the pump 11 is provided. do.

That is, according to the pump system 20 of the present invention, by using the jet nozzle 21 instead of the vacuum pump 12 of the conventional vacuum pump system 10 to start the pump 11 without using a separate power You can.

3 shows a pump system 30 for driving a plurality of pumps 11 as another embodiment of the invention.

As shown in FIG. 3, in the pump system 30 of FIG. 3, the plurality of pumps 11 can be driven in a similar manner as in the pump system shown in FIG. 2.

Here, since the configuration and operation of the pump system 30 shown in FIG. 3 are the same as those of the pump system 20 except that the pump 11 is provided in plural, overlapping description is made for simplicity. Is omitted.

Therefore, as described above, according to the present invention, instead of the conventional vacuum pump 12, the jet nozzle 21 can be used to drive the plurality of pumps 11 without a force.

The embodiments of the present invention as described above have been described as an example of the present invention, but the present invention is not limited to the above embodiments, and various modifications may be made as necessary, such as a design requirement.

That is, the pump system 40 according to the present invention, when the vacuum tank 13 is not particularly necessary, that is, as shown in Fig. 4, the pump 11 without the vacuum tank 13 shown in Figs. ) And the jet nozzle 21 alone, and the like may be selected and changed as necessary.

Here, the operation of the pump system 40 shown in FIG. 4 is also shown in FIGS. 2 and 3 except that the pump 11 and the jet nozzle 21 are directly connected without the vacuum tank 13 in the middle. Since it is the same as the pump system 20 and 30, the detailed description is abbreviate | omitted.

FIG. 5 is a schematic view of a pump system 50 for maintaining a constant vacuum as another embodiment of the present invention.

As shown in FIG. 5, the pump system 50 for constant vacuum according to the present invention includes a pump 11; Jet nozzle 21; And a vacuum tank 13 connected between the pump 11 and the jet nozzle 21 to maintain a vacuum above a reference value capable of starting the pump 11 by acting as a buffer even when a slight leakage occurs. A vacuum degree detecting device 51 for detecting a change in the degree of vacuum in the vacuum tank 13; Electric valves 52 and 53 for automatically operating the jet nozzle 21 when the degree of vacuum in the vacuum tank 13 is reduced; And a control unit 54, which differs from the above-described embodiments.

The operation of this pump system 50 is described as follows.

That is, the pump system 50 maintains the vacuum constantly in the system after the vacuum is first formed in the entire vacuum system 50, that is, the pump and the pipe which is stopped, and the amount of the small amount reduced by minute leakage or the like. It is configured to supplement only the degree of vacuum. First, when a vacuum is formed in the system and the vacuum degree detecting device 51 detects a decrease in the degree of vacuum, the vacuum degree detecting device 51 transmits the contents to the controller 54.

Subsequently, the control unit 54 controls the pump system 50 to be started to open the first electric valve 52 to replenish the vacuum degree in the vacuum tank 13 to remove the air inside the jet nozzle 21. do.

Thereafter, the controller 54 controls the second electric valve 53 to be opened to replenish the degree of vacuum in the vacuum tank 13 as described in the above embodiments.

Then, when the vacuum degree enough to start the pump 11 in the vacuum tank 13 is formed, the vacuum sensor 51 detects it and transmits it to the control unit 54, the control unit 54 is the current vacuum In order to maintain the state, the second electric valve 53 is closed, and then the first electric valve 52 is closed to maintain the vacuum state.

Therefore, by repeating the above process, it is possible to always maintain the vacuum state in the whole system.

As described above, the present invention has been described by taking embodiments of the present invention as an example, but the present invention is not limited only to the contents described in the detailed description of the present invention, and the general knowledge in the technical field to which the present invention belongs. It will be obvious that various modifications, changes, and substitutions can be made by the person having a design without departing from the spirit and essence of the present invention.

1 is a view showing a schematic configuration of a conventional vacuum pump system.

2 is a view showing a schematic configuration of a pump system according to the present invention.

3 is a view showing a schematic configuration of another example of a pump system according to the present invention.

4 is a view showing a schematic configuration of another example of a pump system according to the present invention.

5 is a view showing a schematic configuration of a constant vacuum pump system according to the present invention.

[Description of the code]

10. Vacuum pump system 11. Pump

12. Vacuum pump 13. Vacuum tank

20. Pump system 21. Jet nozzle

30. Pump system 40. Pump system

50. Pump system 51. Vacuum degree sensor

52, 53. Electric valve 54. Control part

Claims (7)

delete delete A pump (11) which acts to pull up the fluid; A discharge pipe (B) connected to the pump (11) in a state filled with fluid so that a constant residual pressure is maintained therein even during a power failure; And Inlet pipe (C) branched from the discharge pipe (B), inlet pipe (E) extending from the pump 11, discharge pipe (F) for ejecting the air and water sucked from the pump 11 to the outside, And a jet nozzle 21 having a venturi tube therein; Water filled in the discharge pipe (B) is guided to the jet nozzle (21) along the inlet pipe (C) via the head pressure existing in the discharge pipe (B), and to the jet nozzle (21). Through the pressure difference generated by the change in the cross-sectional area of the venturi tube while passing through the provided venturi tube, the air inside the pump 11 is discharged through the inlet pipe (E) to the discharge pipe (F), the pump 11 A non-powered, initial startable pump system, characterized in that the interior of the pump (11) in full state by vacuum for the initial start of. The method of claim 3, A pump system, characterized in that configured by installing a plurality of the pump (11). The method of claim 3, Even if leakage occurs in the system, the vacuum tank 13 is added to the inlet pipe E of the pump 11 to act as a buffer so as to maintain the degree of vacuum above the reference value at which the pump 11 can be started. A pump system, characterized in that provided with. delete The method of claim 5, A vacuum degree detecting device (51) for detecting a degree of vacuum of the vacuum tank (13); A first electric valve 52 for opening and closing the inlet pipe C; A second electric valve 53 which opens and closes the inlet pipe E; And And a control unit (54) for controlling opening and closing of the first and second electric valves (52, 53) according to the information of the vacuum degree detecting device (51).

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