KR20140021407A - Method for predicting water saving at instant warmwater softener - Google Patents

Abstract

A method for predicting water saving of an instantaneous warm water softener includes: a step of measuring a flow frequency (Fi) of a fluid which flows to an outlet path through a flow sensor which is installed in the outlet path of a water softener; a step of updating a water saving reference frequency (FB) with the measured flow frequency (Fi); a step of determining whether the measured flow frequency (Fi) decreases or not; a step of determining if the difference between the water saving reference frequency (FB) and the flow frequency (Fi) is greater than a preset water saving criterion (β) when the measured flow frequency (Fi) decreases; a step of stopping the operation of a heater and a pump which are installed within the softener if the difference is greater than the water saving criterion (β); a step of fixing the water saving reference frequency (FB) to the flow frequency (Fi) at the time the heater and pump stop; and a step of determining whether a flow frequency (Fi) measured after the stopping of the heater and pump is more than the water saving reference frequency (FB) or not. The present invention makes water saving of an instantaneous warm water softener possible by predicting a water saving action of locking a water stopper by measuring a flow change in an outlet stage in real time. [Reference numerals] (AA) Start; (BB,DD,FF,HH,JJ,LL) Yes; (CC,EE,GG,II,KK) No; (MM) End; (S10) Measuring a flow frequency (F_i) in a flow path; (S20) Flow frequency (F_i) is equal to or greater than the minimum flow frequency (α)?; (S22) Operate heater/pump; (S30) Flow frequency (F_i) decreases?; (S32) Fix the water saving reference frequency (FB); (S40) F_B - F_i >= β (water saving criterion); (S42) Stop heater/pump; (S50) Flow is detected?; (S70) Time is the same or more than a predetermined flow control reference time

Description

Method for predicting water saving at instant warmwater softener}

The present invention relates to a method for predicting the saving water of an instantaneous hot water softener, and more particularly, the instantaneous hot water by measuring the flow rate change of the fluid flowing through the heater and the pump to the outlet of the softener in real time to predict the opening of the water outlet. The present invention relates to a method for predicting water saving of a water softener.

Instantaneous hot water softener is generally used to heat the raw water flowing into the water softener using a hot water device and soften it to use the soft water and hot water functions integrally.

The instant hot water softener has to be installed separately in order to convert the hot water generated by the instant hot water heater into soft water, and to solve the problem of securing the installation space and economic loss due to the installation of the soft water heater. As a result, the usability can be increased by integrating one system.

On the other hand, the general structure of the instantaneous hot water softener used in the prior art forms a form in which the water obtained through the water tap is passed through the pump through the soft water tank, heated in the heater tank, passed through the flow sensor, and then discharged to the shower head.

In the above structure, the flow sensor is used to determine the presence of water in the water softener and to control the pump and the heater. In other words, the flow sensor determines whether water is flowing and operates the heater and the pump when it is determined that water is being introduced, and stops the heater and the pump when it is determined that there is no water.

On the other hand, the instantaneous hot water softener system in which the flow sensor is located in the outlet means determines that the flow sensor has water at the remaining flow rate inside the product even when the water outlet of the shower booth is blocked, and the heater and the pump operate until the flow sensor stops. Will be.

Referring to Figure 1 looks at the flow fluctuation process with time using a conventional instant hot water softener system. The time on the horizontal axis indicates a process of opening and closing the water outlet of the shower booth for a time t1. The flow rate on the vertical axis represents the amount of fluid detected by the flow sensor located in the outlet of the instantaneous hot water softener.

First, when the shower booth is opened, the flow rate continuously increases and reaches a maximum when the time t1 is reached (see section a). Thereafter, when the water outlet of the shower booth is closed, the flow rate gradually decreases so that there is no flow rate detected at t2.

In other words, section b from t1 to t2 is a state in which the user locks the shower booth and is not willing to use hot water, while the flow sensor detects the presence of fluid and continues to operate the heater and pump. Let's do it.

As described above, if the heater and the pump are continuously operated without additional inflow of raw water into the power outlet, the water temperature inside the heater tank may be rapidly increased, and if the user locks the water and immediately reuses it, It can be cause. In addition, the water outlet is shut off and the pump is operated for a few seconds, which causes noise and suspects product failure.

In order to solve the above problems, the flow rate of the fluid flowing through the heater and the pump to the water outlet of the water softener decreases to a predetermined value or less than the water-saving reference frequency to determine the water saving and stop the operation of the heater and the pump. When the flow rate frequency of the fluid is sensed more than a predetermined level after the heater and the pump is stopped by the water saving prediction, to provide a water saving prediction method of the instantaneous hot water softener to enable the re-operation of the heater and the pump.

Water saving prediction method of the instantaneous hot water softener according to the present invention provided to achieve the above object is (a) the flow frequency (F _i ) of the fluid flowing in the water flow passage through the flow sensor installed in the water flow passage of the water softener Measuring; (b) updating the water saving reference frequency F _B with the measured flow frequency F _i ; (c) determining whether the measured flow frequency F _i is decreased; (d) When the measured flow frequency F _i decreases, it is determined whether a difference value between the water saving reference frequency F _B and the flow frequency F _i is greater than or equal to a preset water saving determination reference value β. Making; (e) stopping the operation of the heater and the pump installed in the water softener when the difference value is equal to or greater than the water saving judgment reference value β; (f) fixing the water saving reference frequency (F _B ) to the flow frequency (F _i ) at the time when the operation of the heater and the pump is stopped; And (g) determining whether the flow frequency (F _i ) measured after the operation of the heater and the pump is stopped is greater than or equal to the water saving reference frequency (F _B ).

After the step (a), it may be preferable to further include (a1) determining whether or not the flow frequency is a predetermined minimum flow frequency (α) or more.

The step (b), it may be desirable to continuously updated with the same frequency the flow (F _i) the flow frequency (F _i) the measurement of the water saving the reference frequency (F _B) only if the measure.

In step (c), it may be preferable to repeat step (b) when the flow frequency is increased.

After the step (c), it may be preferable to further include (c1) fixing the water-saving reference frequency (F _B ).

In the step (b), when the flow frequency is greater than or equal to the predetermined minimum flow frequency in the step (b1), it may be preferable to start the operation of the heater and the pump.

In the step (e), when the measured flow frequency F _i decreases, it is determined that water saving is determined when the water saving judgment reference value β is accumulated two or more times in succession to determine that the heater and the pump It may be desirable to stop operation.

In the step (g), it may be preferable to repeat the step (b) when the flow frequency is greater than the water saving reference frequency.

After the step (g), (h) in the step (g), if the flow frequency is less than the water saving reference frequency, determining whether or not a predetermined flow rate control reference time has elapsed; It may be desirable.

When the preset flow rate adjustment time has elapsed, it may be preferable to repeat the step (b).

The water saving prediction method of the instantaneous hot water softener of the present invention described above enables the water saving of the instantaneous hot water softener by measuring the flow rate fluctuation of the water softener outlet in real time and predicting the water saving behavior of locking the electric power outlet in advance.

Specifically, when the flow frequency of the fluid flowing through the pump and the heater to the water outlet of the water softener decreases to a predetermined value or less than the water saving reference frequency, it is determined to be water saving and the operation of the heater and the pump is stopped. After the pump stops and the flow frequency of the fluid is detected at a level higher than the stop time, the heater and the pump can be reactivated.

As described above, the present invention can block the noise that may occur in the absence of additional inflow of raw water into the power outlet, while preventing the waste of power. This can improve the usability and the user's satisfaction of the hot water softener.

1 is a graph illustrating an operation process of a heater and a pump depending on whether a water heater is opened in a conventional instant hot water softener;
2 is a flow chart in which the process of predicting the water saving of the hot water softener according to the present invention is arranged in time series;
Figure 3 is a graph showing an embodiment of the flow rate changes over time in the flow sensor to show the process of predicting the water saving according to the present invention, and
Figure 4 is a graph showing another embodiment of the flow rate changes over time in the flow sensor to show the process of predicting the saving water according to the present invention.

The above objects, features and other advantages of the present invention will become more apparent by describing the preferred embodiments of the present invention in detail with reference to the accompanying drawings. Hereinafter, a water saving prediction method of an instant hot water softener according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Instant hot water softener  Explain how to save water

Referring to Figure 2, look at the saving water prediction method of the instantaneous hot water softener according to the present invention.

In the present invention, the flow frequency of the fluid directly measured by the flow sensor installed in the outlet of the instantaneous hot water softener is defined as F _i , and the water saving reference frequency for determining whether water is saved is defined as F _B.

First, the user opens the faucet of the hot water softener for the use of hot water.

Water received through the water outlet is passed through the pump and soft water tank and then passed through the flow sensor is measured the flow frequency of the fluid F _i (S10).

In the present invention, the pump and the heater can be set to operate only when a certain flow rate or more. To do this, set the minimum flow frequency to α and F _i It is determined whether is equal to or greater than α (S20).

F _{i in} step S20 If is equal to or greater than α, the heater and the pump are operated (S22). That is, by operating the heater and the pump only when it is confirmed that the predetermined flow rate or more passes through the flow sensor, it is possible to prevent noise caused by overheating or overoperation of the pump caused by unnecessary heater operation.

In the present invention, the lowest flow rate frequency α may be set to 13 Hz corresponding to the discharge basis 2.0 liters per minute (LPM). Here, once the flow rate is detected, it is possible to set a buffer zone to maintain the pump operation for a certain time. The buffer zone makes it possible to ensure a minimum flow rate withdrawn through the outlet of the instantaneous hot water softener. That is, in the low water pressure state, since the fluctuation of the discharge water flow rate occurs at the initial discharge, for example, a continuous operation of the pump is possible for a period of about 3 seconds after detecting the minimum flow frequency α.

In addition, when it is confirmed that a predetermined flow rate or more passes through the flow sensor, the water saving reference frequency is reset in real time to the flow frequency F _B to F _i (S24). That is, when the flow rate value sensed by the flow rate sensor continuously rises, the measured F _i value is updated and set to F _B.

After that, it is determined whether the flow frequency F _i is decreased (S30).

When it is determined in step S30 that F _i decreases, the maximum flow rate point in F _i is fixed to F _B (S32).

On the other hand, if it is determined in step S30 that F _i increases or maintains the current level, step S22 is continuously maintained.

After fixing F _B in step S32, it is determined whether a difference value between the water saving reference frequency F _B and the flow frequency F _i is equal to or larger than a water saving determination reference value β (S40). Here, β, which is the water saving determination reference value, may be variously set according to the water saving reference frequency F _B.

The water saving judgment reference value β indicates a decreasing measure of the flow rate set to stop the operation of the heater and the pump in operation. In the present invention, when the decrease degree of the flow rate measured by the flow sensor reaches the above β It is possible to stop the operation of the heater and the pump by determining that the water outlet is closed.

Table 1 below shows the corresponding relationship between the water saving judgment reference value β according to the water saving reference frequency F _B.

In the step S40, when it is determined that the value F _B -F _i is β or more, the control unit stops the operation of the heater and the pump (S42).

After the step S42, F _B , which is a water saving reference frequency, is fixed at the flow frequency when the operation of the heater and the pump is stopped (S44). That is, the value of F _i is substituted into F _B at the time of stopping the operation of the heater and the pump.

After the operation of the heater and the pump is stopped and a predetermined time has elapsed, the flow sensor detects the flow of fluid through the outlet of the hot water softener (S50).

In the step S50, if the flow rate is not sensed because there is no fluid flow flowing inside the instantaneous hot water softener, it ends without making any further water saving judgment.

In step S50, when the flow rate is detected, it is determined whether the flow frequency F _i is equal to or higher than the water saving reference frequency F _B (S60). This is to check whether the flow rate state is maintained or exceeded when the heater and the pump are stopped.

In step S60, when the flow frequency F _i is equal to or higher than the water saving reference frequency F _B, step S22 is repeated. That is, when the flow rate of the fluid through the outlet means is maintained above a constant F _B or in the ascending mode, the operation of the heater and the pump is started, and the water saving judgment process is repeated again.

In the step S60, if the flow frequency F _i is smaller than the water saving reference frequency F _B , the flow rate is still detected, but it means a state in which the flow amount of the fluid is reduced. Determine (S70).

In the step S70, if the flow rate is maintained over the reference time to repeat the step S22. That is, if the flow rate of the fluid through the outlet means is less than F _B at the time of stopping the heater, but the flow rate is steadily detected, the operation of the heater and the pump is started, and the water saving judgment process is repeated again.

In the step S70, if it is maintained below the flow rate adjustment time, it ends without performing the above water saving judgment.

Hereinafter, referring to the graph of FIG. 3, the water saving judgment process and the control process of the heater through flow rate detection are once again examined. In FIG. 3, the horizontal axis represents time, and the vertical axis represents the flow frequency value detected by the flow sensor of the outlet unit according to whether the water outlet is open.

In FIG. 3, time on the horizontal axis can be divided into regions c to f. Specifically, the region c is the lowest flow rate ensuring interval, and the flow frequency becomes α at t ₃ to reach the minimum flow frequency. That is, starting at t ₃ , the control unit causes the heater and the pump to be driven.

The area d is a flow rate increase section and the flow rate continuously increases up to t ₄ . In other words, the flow rate is continuously increased so that the flow rate peaks at t ₄ .

The region e is a flow rate reduction section, and the flow rate decreases continuously from t ₄ to t ₅ . That is, the decrease of the flow rate frequency reaches β, which is a water saving judgment reference value, so that the controller instructs to stop the driving of the heater and the pump.

The f region is a restart operation determination region, and it is determined whether or not driving may be performed again after stopping the driving of the heater and the pump. That is, for example, it may be determined whether the decrease in flow rate at the discharge means is due to the locking of the power outlet or the temporary hydraulic fluctuation. As another example, it may be determined whether the decrease in flow rate at the exit means is due to a long term locking of the power outlet or a temporary locking.

In the f field, the flow fluctuation process can be explained by dividing the flow fluctuation into A, B, and C diagrams.

The A line is expected to be due to a temporary hydraulic fluctuation or a temporary locking state of the power outlet as the case where the flow frequency F _i exceeds F _B , which is a water saving reference frequency in the state of making water saving judgment. When the characteristic of the A diagram is shown, the heater and the pump are restarted.

The B line is a case where the flow frequency F _{i maintains} a constant flow state after determining water saving. In this case, it can be regarded as adjusting the flow rate of water discharged by adjusting the opening angle of the power outlet. In the B diagram, as in the A diagram, the heater and the pump are restarted.

The C curve continuously decreases the flow rate until the time t ₆ is reached and no further flow rate is detected so that the control unit determines the stop state of the heater and the pump.

On the other hand, with reference to the graph of Figure 4 will be described with respect to another embodiment of the water-saving determination process and the control process of the heater by the flow rate detection. The embodiment shown in FIG. 4 is intended to prevent the water saving reference frequency from being updated as the flow rate is temporarily increased due to an instantaneous pressure fluctuation, or to prevent the water saving judgment as the flow rate is temporarily reduced.

The difference between the embodiment in FIG. 4 and FIG. 3 is in the process of resetting the water-saving reference frequency F _B to the flow frequency F _i and in the water-saving judgment process. Therefore, descriptions of the same parts will be omitted and only different parts will be described.

In the step S24, in the process of resetting the water-saving reference frequency F _B , when it is confirmed that more than a certain flow rate passes through the flow sensor, FIG. 3 resets the water-saving reference frequency F _B to the flow frequency F _i in real time, but FIG. In Fig. 4, the water-saving reference frequency F _B is reset only if it detects the same flow frequency more than once in succession.

That is, the primary detection in Fig. 4. Referring to t _4, and updates the water saving reference frequency F _B in the case of the second detected at t _{4 '.} Here, the interval between t _{4 '} and t ₄ is defined as a saving reference frequency update check interval.

On the other hand, in the step S40, when it is determined that the reduction width of the flow frequency accumulates two or more times in succession more than β, which is a water saving judgment reference value, it may be determined that the water saving is to stop the operation of the heater and the pump.

As described above, the water saving prediction method of the instantaneous hot water softener according to the present invention enables the water saving of the instantaneous hot water softener by measuring the flow rate fluctuation of the water softener outlet in real time to predict whether or not the water saving behavior of locking the water tap in advance. . Ultimately, the present invention can block the noise that may be caused by the operation of the pump and the heater while there is no additional inflow of raw water into the power outlet, while preventing waste of power.

Although the preferred embodiments of the present invention have been described, the present invention is not limited to the specific embodiments described above. It will be apparent to those skilled in the art that numerous modifications and variations can be made in the present invention without departing from the spirit or scope of the appended claims. And equivalents should also be considered to be within the scope of the present invention.

Claims (10)

(a) measuring a flow frequency (F _i ) of the fluid flowing into the water extraction channel through a flow sensor installed in the water supply channel of the water softener;
(b) updating the water saving reference frequency F _B with the measured flow frequency F _i ;
(c) determining whether the measured flow frequency F _i is decreased;
(d) When the measured flow frequency F _i decreases, it is determined whether a difference value between the water saving reference frequency F _B and the flow frequency F _i is greater than or equal to a preset water saving determination reference value β. Making;
(e) stopping the operation of the heater and the pump installed in the water softener when the difference value is equal to or greater than the water saving judgment reference value β;
(f) fixing the water saving reference frequency (F _B ) to the flow frequency (F _i ) at the time when the operation of the heater and the pump is stopped; And
(g) determining whether the flow frequency F _i measured after the heater and the pump are stopped is equal to or greater than the water saving reference frequency F _B ;
≪ / RTI >
Method for predicting water saving of instant hot water softener. The method of claim 1,
After step (a),
(a1) determining whether the flow frequency is greater than or equal to a predetermined minimum flow rate frequency (α).
Method for predicting water saving of instant hot water softener.
The method of claim 1,
The step (b)
To continuously updated with the same frequency the flow (F _i) the flow frequency (F _i) the measurement of the water saving the reference frequency (F _B) only if the measure which is characterized,
Method for predicting water saving of instant hot water softener.
3. The method of claim 2,
In the step (c), characterized in that repeating the step (b) when the flow frequency (F _i ) increases,
Method for predicting water saving of instant hot water softener. The method of claim 1,
After the step (c)
(c1) fixing the water saving reference frequency (F _B ); further comprising:
Method for predicting water saving of instant hot water softener.
3. The method of claim 2,
The step (b)
(b1) starting the operation of the heater and the pump when the flow frequency F _i is equal to or greater than the predetermined minimum flow rate frequency α in the step (a1),
Method for predicting water saving of instant hot water softener.
The method of claim 1,
The step (e)
When the measured flow frequency F _i decreases.
When it is determined that the water saving judgment reference value β is accumulated continuously two or more times, judging as water saving, the operation of the heater and the pump is stopped.
Method for predicting water saving of instant hot water softener.
The method of claim 1,
In the step (g)
When the flow frequency (F _i ) is equal to or greater than the water saving reference frequency (F _B ), characterized in that step (b) is repeated,
Method for predicting water saving of instant hot water softener.
The method of claim 1,
After step (g),
(h) in the step (g), when the flow frequency (F _i ) is less than the water saving reference frequency (F _B ), determining whether or not a predetermined flow rate adjustment reference time has elapsed; Made,
Method for predicting water saving of instant hot water softener.
The method of claim 9,
When the predetermined flow rate control reference time has passed, the step (b) is repeated,
Method for predicting water saving of instant hot water softener.

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