KR101609639B1 - Mehtod for controlling hybrid water supply system - Google Patents

Abstract

Disclosed is a method to control a hybrid water supply system. According to the present invention, water from a water pipe is normally supplied to a consumer. That is, water is normally able to be supplied to a consumer using water pressure of the water pipe, and energy to supply water to a consumer is able to be saved. Also, when a large amount of water is required to be supplied to the consumer, the water is able to be supplied to the consumer using a first pump and a second pump, thus the water being able to smoothly be supplied to the consumer. In case of a water outage, water stored in a water storage tank is able to be supplied to the consumer using the second pump, thus providing a convenience. Moreover, since the water stored in the water storage tank is periodically supplied to the consumer, water is prevented from being stored in the water storage tank for a long time so as not to be contaminated.

Description

[0001] METHOD FOR CONTROLLING HYBRID WATER SUPPLY SYSTEM [0002]

The present invention relates to a control method of a hybrid water supply system capable of selectively supplying water or tap water from a water supply pipe to a use site or supplying the same to a use site.

The water supply system that supplies water to the user uses direct water supply system that directly supplies the water flowing from the water supply pipe to the user and an indirect water supply system that stores the water of the water supply pipe in the water storage tank and supplies water stored in the water storage tank do.

The direct water supply system includes a direct water supply system that supplies water to the user through the water pressure of the water supply pipe, a direct water pressure supply system that connects the water supply pump directly to the water supply pipe and the water supply pressure of the water supply pipe by using the pressurized water supply pump, have.

The indirect water supply system includes an elevated water tank water supply system for pumping water from a reservoir tank into a high water tank and then supplying water to the user using gravity, a pressure tank water supply system for supplying water from the pressure water tank pressed by the pump, There is a pump direct feed water system that supplies the water from the water tank to the user using the pump.

However, there is a disadvantage in that water supply is not possible in the case of a direct water supply water supply system.

It is an object of the present invention to provide a control method of a hybrid water supply system capable of solving all the problems of the conventional art as described above.

Another object of the present invention is to provide a control method of a hybrid water supply system that not only can save energy but also can supply water to a use place even in the case of a short water.

It is another object of the present invention to provide a control method of a hybrid water supply system which can reduce costs and is easy to maintain.

According to an aspect of the present invention, there is provided a control method for a hybrid water supply system including a first pump for supplying water to a user of a water supply pipe, and a second pump for supplying water stored in the water storage to the user, A method for controlling a hybrid water supply system, the method comprising: waiting for the first pump and the second pump to drive; Detecting a pressure of the use-side pipeline and comparing the pressure to a first set pressure; Determining whether the use-side pipe pressure is equal to or higher than the first set pressure and continuously determining whether the use-side pipe pressure is lower than the first set pressure; Driving the second pump to supply the water of the water storage tank to the use place if the water supply is a single number, and comparing the pressure of the water supply pipe to the second set pressure if the number is not a single number; The first pump is driven to supply water from the water pipe to the use place when the water pressure of the water pipe is equal to or higher than the second set pressure, and when the pressure of the water pipe is below the second set pressure, The step of driving the pump may be performed.

In a control method of a hybrid water supply system according to an embodiment of the present invention, water of a water supply pipe is supplied to a user using a first pump in a normal case. That is, in the normal case, since the water can be supplied to the user using the water pressure of the water pipe, it is possible to save the energy for supplying the water to the user.

When a large amount of water is to be supplied to the user, the first pump and the second pump can be used to supply the water to the user, so that the water can be supplied smoothly to the user.

In the case of a single water supply, the water stored in the water storage tank can be supplied to the user using the second pump, so that a convenient effect can be obtained.

Since the water stored in the water tank is periodically supplied to the user, it is possible to prevent the water from being stored in the water tank for a long time and being contaminated.

1 is a schematic view of a hybrid water supply system according to an embodiment of the present invention;
2 to 4 are flowcharts showing a control method of a hybrid watering system according to an embodiment of the present invention.

It should be noted that, in the specification of the present invention, the same reference numerals as in the drawings denote the same elements, but they are numbered as much as possible even if they are shown in different drawings.

Meanwhile, the meaning of the terms described in the present specification should be understood as follows.

The word " first, "" second," and the like, used to distinguish one element from another, are to be understood to include plural representations unless the context clearly dictates otherwise. The scope of the right should not be limited by these terms.

It should be understood that the terms "comprises" or "having" does not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

It should be understood that the term "at least one" includes all possible combinations from one or more related items. For example, the meaning of "at least one of the first item, the second item and the third item" means not only the first item, the second item or the third item, but also the second item and the second item among the first item, Means any combination of items that can be presented from more than one.

The term "above" means not only when a configuration is formed directly on top of another configuration, but also when a third configuration is interposed between these configurations.

Hereinafter, a method of controlling a hybrid water supply system according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic view of a hybrid water supply system according to an embodiment of the present invention.

As shown, the hybrid feedwater pump system according to the present embodiment may include a control unit 110, a plurality of first pumps 121 controlled by the control unit 110, and a plurality of second pumps 125 . In FIG. 1, only one second pump 125 is shown for convenience of explanation.

The first pump 121 communicates with one side of the water pipe 51 to supply the water from the water pipe 51 to the user and the second pump 125 communicates with the water reservoir 55, Water can be supplied to the user.

A pipeline 131 may be installed between the first pump 121 and the faucet to be used and a pipeline 131 may be provided between the second pump 125 and the faucet to be used. A pipeline 133 may be installed between the first pump 121 and the water supply pipe 51 and a pipeline 135 may be provided between the second pump 125 and the water storage tank 55. Accordingly, the discharge pipe of the first pump 121 and the discharge pipe of the second pump 125 can communicate with the use-side pipe 131, respectively, and the inlet pipe of the first pump 121 and the outlet pipe of the second pump 125 Can communicate with the conduit 133 on the side of the water supply pipe 51 and the conduit 135 on the side of the water storage tank 55, respectively.

At least one valve 141 or 145 controlled by the control unit 110 may be installed on the use-side pipe 131, the water pipe 133 on the water supply pipe 51, and the pipe 135 on the water storage 55 side . A pressure sensor (not shown) for sensing the pressure may be installed in the use-side pipeline 131 and the pipeline 133 on the water supply pipe 51. The pipeline 133 on the side of the water pipe 51 And an electrode (not shown) for detecting the amount of electricity can be installed. The first pump 121 may be provided with a sensor for detecting the degree of the load applied to the first pump 121. The first pump 121 and the second pump 125 may be provided with a first A sensor for sensing the driving time of the pump 121 and the second pump 125 may be installed.

1, reference numeral 150 denotes a pressure tank.

The control method of the hybrid water supply system according to the present embodiment may be such that the water of the water pipe 51 is supplied to the user using the first pump 121 or the water of the water reservoir 55 is supplied to the user using the second pump 125 Or the water of the water supply pipe 51 and the water of the water storage tank 55 may be supplied to the user by using the first pump 121 and the second pump 125. [

A control method of the hybrid water supply system according to the present embodiment will be described with reference to Figs. 1 to 4. Fig. 2 to 4 are flowcharts illustrating a method of controlling a hybrid water supply system according to an embodiment of the present invention.

1 and 2, in step S110, power is supplied to the first pump 121 and the second pump 125 so that the first pump 121 and the second pump 125 are driven It is possible to wait for driving. In step S121, the pressure of the use-side pipe 131 may be sensed. In step S125, the pressure of the use-side pipe 131 may be compared with the first set pressure.

When the use faucet is opened, the water in the use-side duct 131 is discharged to the use place, so that the pressure of the use-side duct 131 can be reduced. That is, if the pressure of the use-side duct 131 is less than the first predetermined pressure, it means that the use-made faucet is opened, so that the next step S130 for supplying water to the use place can be performed, If the pipeline pressure is equal to or higher than the first set pressure, it means that the faucet of the place of use is locked and does not need to supply water to the use place, so that the step S110 of sensing the pressure of the use place side pipeline 131 can be continued.

In the case where the pressure of the use-side pipe 131 is lower than the first set pressure, in order to supply water to the place of use, Step S130 may be performed.

Whether the number is a single number can be judged by using the electrode. That is, the electrode rod may be installed in the pipe 133 on the side of the water pipe 51, and it may be determined whether the electrode rod is immersed in water or not.

Water is supplied to the water pipe 51 because the water is supplied to the water pipe 51 because the water is supplied to the water pipe 51 because the water is supplied to the water pipe 51. Therefore, 121) can not be used to supply water.

Therefore, if it is not the shortest, the step S141 of sensing the pressure of the pipeline 133 on the water pipe 51 side is performed and then the pressure of the pipeline 133 on the side of the water pipe 51 is compared with the second set pressure Step S145 may be performed. The reason for sensing the pressure of the pipeline 133 on the water pipe 51 side is that the pressure of the water supplied from the water source to the water pipe 51 is not constant.
If the pressure of the channel 133 on the water pipe 51 side is equal to or higher than the second set pressure, the first pump 121 may be driven (S150) so that the water in the water pipe 51 may be supplied to the user . After the first pump 121 is driven (S150), it is possible to perform a step S160 of sensing the load of the first pump 121 and determining whether the first pump 121 takes the maximum load have.

If the maximum load is applied to the first pump 121, it means that the water to be supplied to the place of use is insufficient through the first pump 121, so that the step of driving the second pump 125 (S170) The water of the water storage tank 55 can be supplied to the user.

If the maximum load is not applied to the first pump 121, step S181 of comparing the drive time of the first pump 121 with the first set time after detecting the drive time of the first pump 121 So as to determine whether the first pump 121 or the second pump 125 is driven.

That is, if the driving time of the first pump 121 is less than the first set time, the first pump 121 may be continuously driven (S150). If the driving time of the first pump 121 is equal to or longer than the first predetermined time, the first pump 121 may be stopped (S185), and the second pump 125 may be driven (S170) . This is to prevent the water in the water storage tank 55 from being stored for a long period of time by supplying water from the water storage tank 55 to the user using only the second pump 125. [

After the second pump 125 is driven (S170), the load of the first pump 121 may be sensed again to determine whether the load of the first pump 121 is full load (S191). Thus, if the first pump 121 continues to operate at the maximum load, it means that water is continuously used at the place of use, so that the second pump 125 can be driven continuously (S170).

If the first pump 121 does not operate at the maximum load, the first pump 121 is stopped (S185) to prevent the water from being stored in the water reservoir 55 for a long time, and the second pump 125 The driving of the second pump 125 can be determined according to the driving time of the second pump 125. [

That is, after sensing the driving time of the second pump 125, it is possible to perform a step S193 of comparing the second set time with the second set time. When the driving time of the second pump 125 is less than the second predetermined time, the second pump 125 is continuously driven (S170). When the driving time of the second pump 125 is longer than the second predetermined time It means that the bottom water stored in the water storage tank 55 by the second pump 125 is supplied to the use place, so that the step of stopping the second pump 125 (S195) can be performed. Then, it is possible to perform the step S121 of sensing the pressure of the use-side pipe 131.

Next, when the pressure of the pipeline 133 on the water supply pipe 51 side is lower than the second set pressure when the pressure of the pipeline 133 on the water supply pipe 51 side is compared with the second predetermined pressure (S145) Will be described with reference to Figs. 1 and 3. Fig.

As shown in the figure, when the pressure of the channel 133 on the water pipe 51 side is lower than the second predetermined pressure, a step S210 of generating an alarm and then driving the first pump 121 S220). Due to the occurrence of the alarm, the user can recognize that the pressure of the channel 133 on the side of the water supply pipe 51 is lower than the second set pressure.

It is possible to perform the step S231 of sensing the load of the first pump 121 after the first pump 121 is driven S220 and if the first pump 121 does not operate at the maximum load, It means that sufficient water is supplied to the place of use by the pump 121, so that the first pump 121 can be driven continuously (S220). If the first pump 121 is operated at the maximum load, it is possible to determine whether the second pump 125 is driven by performing a step S235 of comparing the pressure of the use-side pipe 131 with the third set pressure .

That is, when the first pump 121 operates at the maximum load and the pressure of the use-side duct 131 is lower than the third set pressure, it means that the water supplied to the use destination by the first pump 121 is insufficient , And driving the second pump 125 (S250).

When the first pump 121 operates at the maximum load and the pressure of the use-side duct 131 is equal to or higher than the third set pressure, the first pump 121 or the second pump 121, Whether or not the pump 125 is driven can be determined. In order to determine whether the first pump 121 or the second pump 125 is driven in accordance with the driving time of the first pump 121, the driving time of the first pump 121, Time can be compared.

When the first pump 121 operates at the maximum load and the pressure of the use-side duct 131 is equal to or higher than the third set pressure and the drive time of the first pump 121 is equal to or higher than the third set time, It means that the faucet is locked, so that the first pump 121 can be driven standby (S110).

When the first pump 121 operates at the maximum load, the pressure of the use-side duct 131 is equal to or higher than the third set pressure, and the drive time of the first pump 121 is less than the third set time, After the step S245 of stopping the pump 121 is performed, the second pump 125 may be driven (S250). This is to prevent the water in the water storage tank 55 from being stored for a long period of time by supplying water from the water storage tank 55 to the user using only the second pump 125. [

After the second pump 125 is driven (S250), the load of the first pump 121 may be sensed again to determine whether the load of the first pump 121 is full load (S261). Thus, if the first pump 121 continues to operate at the maximum load, it means that water is continuously used in the place of use, so that the second pump 125 can be continuously driven (S250).

If the first pump 121 does not operate at the maximum load, the first pump 121 is stopped (S245) to prevent the water from being stored in the water reservoir 55 for a long time, and the second pump 125 (S250), it is possible to determine whether the second pump 125 is driven according to the driving time of the second pump 125. [

To this end, the driving time of the second pump 125 may be sensed, and then the driving time of the second pump 125 may be compared with the fourth predetermined time (S265). Thus, if the driving time of the second pump 125 is less than the fourth predetermined time, the second pump 125 is continuously driven (S250). If the driving time of the second pump 125 is equal to or longer than the fourth predetermined time It means that the bottom water stored in the water storage tank 55 by the second pump 125 is supplied to the place of use so that after the step S270 of stopping the second pump 125 is performed, (Step S121).

Next, a case in which the pressure of the use-side pipeline 131 is less than the first set pressure but is a single step will be described with reference to Figs. 1 and 4. Fig.

As shown in the figure, if the water supply is not a single water supply, the water from the water source is not supplied to the water pipe 51. Therefore, after the step S310 of generating the alarm is performed, the step S320 of stopping the first pump 121 is performed can do. Then, the step of driving the second pump 125 (S340) may be performed.

At this time, between step S320 of stopping the first pump 121 and step S340 of driving the second pump 125, a step S330 of comparing the level of the water storage tank 55 with the set value is performed . Therefore, if the water level of the water tank 55 is higher than the set value, it means that water is sufficiently stored in the water tank 55, so that the second pump 125 can be driven (S340). When the water level in the water level tank 55 is lower than the set value, it means that there is almost no water in the water level tank 55, so that the first pump 121 can be stopped (S320).

After the driving of the second pump 125 (S340), a step S350 of comparing the pressure of the use-side pipe 131 with the first set pressure may be performed. Thus, when the pressure of the use-side conduit 131 is equal to or higher than the first set pressure, the second pump 121 is maintained in the drive standby (S110) state, and the pressure of the use- The second pump 125 can be continuously driven (S340).

In the control method of the hybrid water supply system according to the present embodiment, in the normal case, the water of the water supply pipe 51 is supplied to the user using the first pump 121. That is, in a normal case, since the water can be supplied to the user using the water pressure of the water pipe 51, the energy for supplying water to the user can be saved.

When a large amount of water is to be supplied to the user, water can be supplied to the user using the first pump 121 and the second pump 125, so that water can be smoothly supplied to the user.

In the case of a single water supply, the water stored in the water storage tank 55 can be supplied to the user using the second pump 125, which is convenient.

Since the water stored in the water storage tank 55 is periodically supplied to the use place, the water is stored in the water storage tank 55 for a long period of time and is prevented from being contaminated.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Will be clear to those who have knowledge of. Therefore, the scope of the present invention is defined by the appended claims, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be interpreted as being included in the scope of the present invention.

51: Water supply pipe
55: Water tank
121: first pump
125: Second pump

Claims (13)

A control method for a hybrid water supply system including a first pump for supplying water from a water pipe to a user and a second pump for supplying water stored in the water storage tank to the user,
Waiting the first pump and the second pump for driving;
Detecting a pressure of the use-side pipeline and comparing the pressure to a first set pressure;
Determining whether the use-side pipe pressure is lower than the first set pressure, and determining whether the water supply pipe is short-circuited if the use-side pipe pressure is lower than the first set pressure; ;
If the number of observations of the water surface is a single number, driving the second pump to supply water of the water reservoir to a user; comparing the pressure of the water pipe to the second set pressure if the water is not a single number;
The first pump is driven to supply water from the water pipe to the use place when the water pressure of the water pipe is equal to or higher than the second set pressure, and when the pressure of the water pipe is below the second set pressure, Performing a step of driving the pump,
When the first pump is driven after an alarm occurs due to the pressure of the water pipe being lower than the second set pressure,
The method further comprises the step of determining the load of the first pump and continuously driving the first pump if the first pump does not operate at the maximum load, and if the first pump is operated at the maximum load, Wherein the controller determines whether to drive the second pump by comparing the third set pressure. delete The method according to claim 1,
When the driving time of the first pump is less than the first set time, the first pump is continuously driven,
Wherein the controller stops the first pump and drives the second pump when the driving time of the first pump is equal to or longer than the first predetermined time. The method according to claim 1 or 3,
After the driving of the second pump,
The second pump is continuously driven when the first pump operates at the maximum load,
Wherein the controller determines whether the second pump is driven according to the driving time of the second pump when the first pump does not operate at the maximum load. 5. The method of claim 4,
The second pump is continuously driven when the driving time of the second pump is less than the second set time,
And stops the second pump when the driving time of the second pump is equal to or longer than the second predetermined time. The method according to claim 1,
Wherein the control unit determines the load of the first pump when the first pump is driven after an alarm occurs due to the pressure of the water pipe being lower than the second set pressure,
Performing the step of continuously driving the first pump when the first pump does not operate at the maximum load,
Wherein the control unit determines whether the second pump is driven by comparing the pressure of the use-side pipe with the third set pressure when the first pump operates at a maximum load. The method according to claim 6,
Wherein the first pump operates at a maximum load and the second pump is driven when the use-side pipe pressure is equal to or higher than the third set pressure. The method according to claim 6,
Determining whether the first pump or the second pump is driven according to the driving time of the first pump when the first pump operates at a maximum load and the pressure of the pipe at the use site is less than the third set pressure Wherein the hybrid water supply system is a hybrid water supply system. 9. The method of claim 8,
Wherein when the driving time of the first pump is equal to or longer than a third predetermined time,
And stopping the first pump and driving the second pump when the driving time of the first pump is less than the third predetermined time. 10. The method according to claim 7 or 9,
After the driving of the second pump,
The second pump is continuously driven when the first pump operates at the maximum load,
Wherein the controller determines whether the second pump is driven according to the driving time of the second pump when the first pump does not operate at the maximum load. 11. The method of claim 10,
When the driving time of the second pump is less than the fourth set time, the second pump is continuously driven,
And when the driving time of the second pump is equal to or longer than the fourth predetermined time, the second pump is stopped and held in a standby state. The method according to claim 1,
Stopping the first pump after the alarm if the use-side duct pressure is less than the first set pressure and the water supply observation is a single stage,
After the water level of the water storage tank is compared with the set value,
And driving the second pump when the water level of the water storage tank is higher than the set value, and stopping the first pump when the water level of the water storage tank is lower than the set value. 13. The method of claim 12,
After the driving of the second pump,
Wherein the second pump is maintained in a standby state when the use-side conduit pressure is equal to or higher than the first set pressure, and the second pump is continuously driven when the use-side conduit pressure is lower than the first set pressure. Control method of water supply system.

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