KR101201152B1 - Device and method for supplying warm water - Google Patents

Abstract

The present invention relates to a hot water supply device and a hot water supply method, specifically, the hot water supply device of the present invention is configured to have a first set capacity, the first heater for heating the introduced water; A second heater configured to have a second set capacity greater than the first set capacity and to heat the introduced water; And a controller configured to calculate a heater driving cycle of the first heater and the second heater according to a heating preset temperature of water, and to drive the first heater and the second heater according to the heater driving cycle. The heater driving cycle of the first heater is calculated using a control method, and the heater driving cycle of the second heater is calculated using a zero crossing control method.

Description

Hot water supply device and hot water supply method {Device and method for supplying warm water}

The present invention relates to a hot water supply device and a hot water supply method, and more particularly, to a hot water supply device and a hot water supply method for instantaneous hot water used in a domestic bidet.

The hot water supply device used for the domestic bidet is largely divided into a water tank type in which a heater is installed in a water tank and an instant hot water type in which water from a tap water is heated whenever necessary by using a heater.

The water tank type hot water supply device includes a heater disposed in the water tank for storing hot water, and maintains the temperature of the water in the water tank at a predetermined temperature regardless of whether a bidet is used. Accordingly, the water tank type hot water supply device consumes a lot of standby power and space.

In recent years, the instant hot water type hot water supply device is widely used. The instant hot water type hot water supply device requests a user to use a bidet, and heats the water discharged by the heater while the water is discharged into the outlet pipe to increase the temperature. Increase it.

The instant hot water type hot water supply device does not always flow water, and in order to ensure the stability of the operation, the heater must be operated only while the water is flowing.

However, the hot water supply device for instantaneous hot water having a heater as described above has a problem in that noise is frequently generated, causing problems such as burnout or overheating as well as deterioration in efficiency.

In particular, when harmonic components such as noise are generated, a temperature may increase in a transformer that supplies power to the hot water supply device, which may cause a fire. In addition, when the flicker occurs, the load on the power supply is suddenly changed, which may cause operation problems in other load-type devices connected to the power supply.

Hot water supply device and hot water supply method of the present invention for solving the above problems to reduce the occurrence of frequent noise to prevent burning or overheating, in particular to provide a hot water supply device and hot water supply method that can reduce harmonic components and flicker For the purpose of

One aspect of the present invention for solving the above problems is configured to have a first set capacity, the first heater for heating the introduced water; A second heater configured to have a second set capacity greater than the first set capacity and to heat the introduced water; And a controller configured to calculate a heater driving cycle of the first heater and the second heater according to a heating preset temperature of water, and to drive the first heater and the second heater according to the heater driving cycle. The heater driving cycle of the first heater is calculated using a control method, and the heater driving cycle of the second heater is calculated using a zero crossing control method.

The controller determines whether the temperature of the water introduced into the first heater and the second heater is smaller than the heating set temperature, and then calculates the heater driving cycle when the temperature of the water is smaller than the heating set temperature. Provide a device.

The first set capacity is greater than zero and less than 550W capacity, the second set capacity is more than 550W and provides a capacity of less than 1250W provides a hot water supply device.

Another aspect of the present invention for solving the above problems is the steps of preparing a first heater having a first set capacity and a second heater having a second set capacity larger than the first set capacity; Calculating a heater driving period of the first heater according to the heating set temperature of water using a phase control method, and calculating a heater driving cycle of the second heater according to the heating set temperature of water using a zero crossing control method; And driving the first heater and the second heater according to the heater driving cycle so that water flowing into the first heater and the second heater is heated and then discharged. to provide.

Determining whether the temperature of the water introduced into the first heater and the second heater is smaller than the heating set temperature, and calculating the heater driving cycle when the temperature of the water is smaller than the heating set temperature. It provides a hot water supply method characterized in that.

The first set capacity is greater than zero and less than 550W capacity, the second set capacity is more than 550W and provides a capacity of less than 1250W provides a hot water supply method.

Another aspect of the present invention for solving the above problems is the process of preparing a first heater having a first set capacity, and a second heater having a second set capacity larger than the first set capacity, heating set temperature and heating An operation setting process of receiving a set quantity of water, an operation preparation process of determining whether or not the heating is obtained according to the temperature of the obtained heating quantity, and calculating a required amount of heat for heating, and if heating is required, Selecting at least one of a first heater and a second heater as a heater to drive, calculating a heater driving cycle of the selected heater, and driving the selected heater according to the heater driving cycle, wherein the controlling process includes phase control The heater driving cycle of the first heater is calculated using a method, and the heater driving cycle of the second heater is counted using a zero crossing control method. It provides a hot water supply system characterized in that a.

In the control process, when the required amount of heat is less than the first set capacitance, the controller selects the first heater as a heater to drive, calculates a heater driving cycle of the first heater by using a phase control method, and drives the first heater. To provide a hot water supply method characterized in that it comprises a first control step.

When the required amount of heat is greater than or equal to the first set capacity and less than the second set capacity, the second heater is selected as a heater to be driven, and a heater driving cycle of the second heater is calculated using a zero crossing method, and the second Driving the heater provides a hot water supply method comprising a second control step.

When the required heat amount is greater than or equal to the second set capacity, the first heater and the second heater are selected as the heaters to be driven, and the heater driving cycle of the first heater is calculated by using a phase control method and the first heater is driven. And calculating a heater driving cycle of the second heater by using a zero crossing method and driving the second heater.

In the third control step, the second heater calculates a heating driving period such that the second heater is driven in accordance with the second set capacitance, and the first heater is driven so as to be driven in accordance with a capacity obtained by subtracting the second set capacitance from the required heat quantity. It provides a hot water supply method characterized by calculating the heating drive cycle.

The operation preparation step may include obtaining water over a preset heating amount, measuring a water temperature of the water, calculating the necessary heat amount for heating when the water temperature is less than the heating preset temperature, and the water temperature is a preset temperature. In case of abnormality, the process includes water exiting and waiting for operation. When the preset temperature is above the heating preset temperature and the water temperature is above the preset heating temperature and below the preset temperature, the process of measuring the water temperature is performed again. It provides a hot water supply method characterized in that.

The first set capacity is greater than 0 and less than 550W capacity, the second set capacity is more than 550W and provides a capacity of less than 1250W provides a hot water supply method.

According to the hot water supply apparatus and the hot water supply method of the present invention, by providing two heaters and providing a hot water supply apparatus and a hot water supply method to which the phase control method and the zero crossing control method are applied, respectively, it is more frequent than the case of using a single heater. By reducing the occurrence of noise, it is possible to prevent burnout or overheating of the hot water supply device and increase efficiency.

Further, according to the hot water supply device and the hot water supply method of the present invention, by adjusting the set capacity of the heater to reduce the harmonic components and flicker so as not to affect the operation of the power supply device and other load-type devices connected to the power supply device. can do.

1 is a block diagram of a hot water supply control system of the present invention.
2 is a graph showing a phase control method of the present invention.
3 is a graph illustrating a zero crossing control method of the present invention.
4 is a table showing the results of the harmonic test and flicker test according to the heater capacity of the present invention.
5 is a flow chart of the hot water supply method of the present invention. 5 will be described together with FIG. 1.
6 is a flowchart of a hot water supply method according to another embodiment of the present invention.
7 is a flow chart of the operation preparation step of the hot water supply method according to another embodiment of the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. However, the embodiments of the present invention may be modified into various other forms, and the scope of the present invention is not limited to the embodiments described below. The shape and the size of the elements in the drawings may be exaggerated for clarity and the same elements are denoted by the same reference numerals in the drawings.

1 is a block diagram of a hot water supply control system of the present invention. Referring to FIG. 1, the hot water supply control system largely includes a hot water supply device 100, a main control device 200, and a water supply valve 300.

The hot water supply device 100 may include a power control signal generator 10, a first heater 20a, a second heater 20b, a heater driving protector 30, a quantity sensor 40, and a temperature detector 50. ), The communication unit 60, and the control unit 70. Hereinafter, the detailed components of the hot water supply device 100 will be described in detail.

The first heater 20a and the second heater 20b heat the introduced water and discharge the same. The first heater 20a is configured to have a first set capacity (capacity greater than 0 and less than 550 W), and the second heater 20b is greater than or equal to the second set capacity (550 W and less than 1250 W) greater than the first set capacity. Capacity).

The quantity detecting unit 40 detects the quantity of water flowing into the first heater 20a and the second heater 20b and transmits information about the quantity to the heater driving protection unit 30.

The heater driving protection unit 30 determines whether the quantity of water flowing into the first heater 20a and the second heater 20b is greater than or equal to a preset value, and generates a heater driving enable signal if the quantity is greater than or equal to the predetermined value. Transfer to 70.

The power control signal generator 10 receives the AC power, obtains a cycle and zero points of the AC power, and transmits the same to the controller 70. The heater driving signal generated by the controller 70 is generated according to the heater driving cycle calculated based on the period and zero point of the AC power provided from the power control signal generator 10.

The temperature detector 50 detects the temperature of the water discharged from the first heater 20a and the second heater 20b. The temperature detector 50 detects the temperature of the water when the quantity of water flowing into the first heater 20a and the second heater 20b is greater than or equal to a preset value.

The controller 70 calculates a heater driving cycle of the first heater 20a and the second heater 20b according to the heating set temperature of the water, and the first heater 20a and the second heater 20b according to the heater driving cycle. Drive. The controller 70 determines whether the temperature of the water introduced into the first heater 20a and the second heater 20b is lower than the heating set temperature, and then, when the water temperature is smaller than the heating set temperature, the controller 70 determines from the quantity detecting unit 40. The heater driving cycle is calculated by receiving the information on the quantity of the notification, the information on the heating set temperature of the water provided from the main controller 200 and the information on the temperature of the water from the temperature sensor 50. At this time, the controller 70 uses a phase control method when calculating the heater driving period of the first heater 20a, and uses a zero crossing control method when calculating the heater driving period of the second heater 20b.

In addition, the controller 70 determines whether the heater drive enable signal is received from the heater drive protection unit 30, and if the heater drive enable signal is received, heats the incoming water. As such, the reason why the controller 70 receives the heater drive enable signal from the heater drive protection unit 30 is that the controller 70 does not have water flowing into the first heater 20a and the second heater 20b. ) Is to prevent the heater driving signal from being generated.

The communication unit 60 transmits the value of the heating set temperature received from the main control device 200 to the control unit 70, and outputs the quantity of water discharged from the control unit 70 and the water temperature at this time to the main control device 200. send. In addition, the power supply control signal generator 10, the first heater 20a, the second heater 20b, the heater driving protection unit 30, the quantity detection unit receives a DC power supply voltage from the main control device 200 40, the temperature sensing unit 50, the communication unit 60, and the control unit 70.

The main controller 200 detects this when a user requests a specific operation (cleaning, bidet, etc.), and conducts the water supply valve 300 so that water flows into the first heater 20a and the second heater 20b. do. In addition, the main controller 200 transmits a value of the heating set temperature to the control unit 70 of the hot water supply device 100 to enable the hot water supply device 100 to perform the heating operation according to the heating set temperature.

The water supply valve 300 controls the supply of water by turning on / off the valve in response to a request of the main controller 200.

The hot water supply device of the present invention as described above can be used as a representative of the bidet, it can be used in a variety of other devices using the same principle.

2 is a graph showing a phase control method of the present invention. Referring to FIG. 2, the upper graph shows the input power supply voltage V over time t, and the lower graph shows the phase control voltage V over time t. When the heater is driven by the phase control method to the input power supply voltage showing the upper graph, the phase control voltage as shown in the lower graph is output.

The phase control method is to cut off the power at zero voltage by applying a power supply voltage in a specific phase every half cycle to the heater. At this time, the phase angle to which the power voltage is applied is called a conduction angle.

Such a phase control method has a problem of generating noise due to harmonics, but when the heater capacity is more than 550W, the harmonic test of the CE certification test subject cannot be passed.

3 is a graph illustrating a zero crossing control method of the present invention. Referring to FIG. 3, the upper graph shows the input power supply voltage V over time t, and the lower graph shows the zero crossing control voltage V over time t. When the heater is driven by the zero crossing control method to the input power supply voltage indicating the upper graph, the zero crossing control voltage as shown in the lower graph is output.

The zero crossing control method is a method of applying only a positive power supply voltage when an AC power supply voltage is applied to the heater.

The zero crossing control method does not generate noise due to harmonics, and when the heater capacity is 550 W or more and less than 1250 W, the harmonic test of the CE certification test subject can be passed.

4 is a table showing the results of the harmonic test and flicker test according to the heater capacity of the present invention. Here, P denotes a pass and F denotes a fail.

Referring to Fig. 4, when the heater capacities are 450W and 500W, the harmonic test and the flicker test are passed using either the control method of the phase control method or the zero crossing control method.

However, when the heater capacity is 550 W, 650 W, 750 W, the harmonic test and the flicker test can be passed only when the zero crossing control method is used, and the flicker test can be passed when the phase control method is used, but the harmonic test can be passed. Can't.

In addition, when the heater capacity is 1250 W, the flicker test can be passed when the phase control method is used, but it cannot pass the harmonic test. When the zero crossing control method is used, it can pass the harmonic test but the flicker test can Can't.

The reference value of the harmonic test of the CE certification test subject is established with a margin at a threshold where harmonic noise generated by the hot water supply device does not affect the power supply connected to the hot water supply device.

Therefore, if the hot water supply device is designed to meet the criteria of the harmonic test of the CE certification test subject, it is possible to prevent the problem of the heat generation of the power supply device that supplies power to the hot water supply device due to the harmonics.

In addition, when the harmonic component increases, there is a problem that can excessively consume unnecessary power. This is because power consumption is proportional to the square of the frequency, so if the harmonic content increases, the power consumption is increased.

In addition, the reference value of the flicker test of the CE certification test subject is established with a margin at a threshold that prevents the operation of other load-type devices connected to the power supply by the flicker component generated by the hot water supply device. will be.

In particular, since devices such as lamps are sensitive to changes in supply current, generation of flicker components in a hot water supply device used at home may cause inconvenience to a user. In addition, the current supply may momentarily decrease or increase, causing damage to other loaded devices.

Therefore, when the hot water supply device is designed to meet the standard value of the flicker test of the CE certification test subject, it is possible to ensure stable operation of another load-type device connected to the power supply device.

As can be seen in Figure 4, when a heater is provided in the hot water supply apparatus, and the heater is driven using a phase control method, when the heater capacity is 550W or more, the CE certification test subjects cannot pass the harmonic test.

Therefore, in the present invention, two hot water heaters are provided to control the hot water supply. That is, when a heater capacity of 1250W is required, two heaters having a heater capacity of 500W and 750W are provided, respectively, the 500W heater drives the heater using a phase control method, and the 750W heater uses a zero crossing control method. To drive the heater.

As mentioned above, two heaters, 500W and 750W, are provided in the hot water supply device to pass the harmonic test and the flicker test. However, when the harmonic test cannot be passed and the zero crossing control method is used, the harmonic test can be passed, but the flicker test cannot be solved.

On the other hand, in relation to the configuration of the heater, in the case of configuring the capacity of 1250W with two heaters, the example is configured to 500W, 750W, but one heater to have the first set capacity and the other heater is set to the second If only the condition to have a capacity can be satisfied to have a variety of heater capacity. That is, when the capacity of 1250W is configured with two heaters, it is possible to configure 450W and 800W.

In addition, even when configured with three or more capacity of 1250W to drive the phase control method, the hot water supply device of the present invention can pass the harmonic test and flicker test. However, since the structure of the hot water supply device is complicated as compared with the case of two, the hot water supply device is preferably composed of two.

5 is a flow chart of the hot water supply method according to an embodiment of the present invention. 5 will be described together with FIG. 1.

First, a first heater 20a having a first set capacitance and a second heater 20b having a second set capacitance larger than the first set capacitance are prepared (S10).

After that, when the heating set temperature transmitted from the main controller 200 is input to the control unit 70 (S20), the water quantity detecting unit 40 flows into the first heater 20a and the second heater 20b. The amount of water is detected (S30) and it is determined whether the quantity is more than a predetermined value (S40).

Thereafter, if the quantity is more than the predetermined value, the temperature detector 50 detects the temperature of the water discharged from the first heater 20a and the second heater 20b (S50). However, if the quantity is not more than the predetermined value repeat the step S40.

After that, the controller 70 determines whether the temperature of the water introduced into the first heater 20a and the second heater 20b is smaller than the heating set temperature (S60). However, if the temperature of the water is not less than the heating set temperature, the feedback (feedback) to the step S50.

After that, when the temperature of the water is lower than the heating set temperature, the control unit 70 is informed about the quantity of water received from the quantity detecting unit 40, information about the heating set temperature of the water provided from the main control device 200, The temperature sensing unit 50 receives information about the temperature of the water and calculates driving cycles of the first heater 20a and the second heater 20b (S70). At this time, the controller 70 uses a phase control method when calculating the heater driving period of the first heater 20a, and uses a zero crossing control method when calculating the heater driving period of the second heater 20b.

Thereafter, the controller 70 determines whether the heater drive enable signal received from the heater drive protection unit 30 has been received (S80). At this time, in order to drive the first heater 20a and the second heater 20b, the control unit 20 must receive a heater drive enable signal from the heater drive protection unit 30. As such, the reason why the controller 70 receives the heater drive enable signal from the heater drive protection unit 30 is that the controller 70 does not have water flowing into the first heater 20a and the second heater 20b. ) Is to prevent the heater driving signal from being generated.

After that, when the heater drive enable signal is received, the controller 70 generates a heater drive signal according to the heater drive cycle calculated based on the cycle and zero point of the AC power supplied from the power control signal generator 10. (S90). However, if the control unit 70 does not receive the heater drive enable signal from the heater drive protection unit 30 in step S800, the first heater 20a and the second heater 20b cannot heat the water flowing therein. Feedback to step S400.

Thereafter, the first heater 20a and the second heater 20b heat the water flowing therein and then discharge the water (S100).

6 is a flowchart of a hot water supply method according to another embodiment of the present invention.

First, a first heater 20a having a first set capacitance and a second heater 20b having a second set capacitance larger than the first set capacitance are prepared.

Subsequently, in the operation setting step (S200), a heating set temperature, which is a target value of the temperature of the water to be discharged, and a heating set quantity that is a target value of the water or water pressure, may be input. In the operation setting step (S200), the heating set temperature and the heating set quantity may be directly input by a user or may be read by reading a pre-stored or stored usage pattern.

In the operation preparation step (S300), the water to be heated may be obtained at a heating set amount or more, and the heating may be determined according to the temperature of the obtained water, and the required amount of heat for heating may be calculated. By comparing the temperature of the obtained water and the heating set temperature, it is possible to determine whether the heating is required, and if it is determined that heating is necessary, the necessary heat amount for heating may be calculated in consideration of the quantity and the heating set temperature.

When the required heat amount is less than the first set capacity (S400), the first control step (S500) is performed. In the first control step S500, a heater driving period of the first heater may be calculated by using a phase control method and the first heater may be driven.

When the required heat amount is greater than or equal to the first set capacitance and less than the second set capacitance (S600), the second control step S700 is performed. In the second control step S700, a heater driving cycle of the second heater may be calculated by using a zero crossing method and the second heater may be driven.

When the amount of heat required is greater than or equal to the second set capacity (S600), a third control step (S800) is performed. In a third control step S800, a heater driving cycle of the first heater is calculated using a phase control method, the first heater is driven, and a heater driving cycle of the second heater is calculated using a zero crossing method. The second heater can be driven.

Although not shown, it is possible to check whether an operation error occurs and whether the operation time expires in the middle of performing the first to third control steps S500, S700, and S800.

When an error occurs in the first to third control steps (S500, S700, S800) or the operation time expires, the first to third control steps (S500, S700, S800) may be stopped and wait for operation.

In addition, when no error occurs in the first to third control steps (S500, S700, S800) and the operation time does not expire, the operation preparation step may be returned. Preferably, it is possible to perform only the determination of heating and calculation of the required calories for heating according to the temperature of the obtained water without additional acquisition.

In the third control step S800, the control method may vary depending on the priority of use of the first heater and the second heaters 20a and b.

For example, when the priority of the second heater 20b is high, in the third control step S800, the heating period is calculated so that the second heater is driven according to the second set capacity, and the first heater The heater may calculate the heating driving cycle to be driven according to the capacity obtained by subtracting the second set capacitance from the required heat amount.

When the priority of the first heater 20a is high, in the third control step S800, the heating driving period is calculated such that the first heater is driven according to the first set capacitance, and the second heater is required. The heating driving period may be calculated to be driven according to a capacity obtained by subtracting the first set capacitance from heat.

Preferably, the heater with less change in water temperature control ability according to the amount of heat required can be prioritized. In the case where the change in water temperature control ability is severe, water temperature control is not easy when the quantity to be heated changes. Therefore, it is desirable to make the quantity to be heated equal to the set capacity of the heater. If the heater is the same as the set capacity of the heater, because the number of the quantity to be heated is small because the width of the temperature change can improve the water temperature control ability.

Referring to FIG. 6, the hot water supply method of the present invention is a hot water supply method capable of efficiently using a heater and saving power by dividing and controlling the first and second heaters 20a and b. In addition, precise temperature control is possible through split control of the first and second heaters, thereby preventing unnecessary energy consumption, thereby minimizing power consumption.

7 is a flow chart of the operation preparation step of the hot water supply method according to another embodiment of the present invention.

First, while obtaining the water to be heated (S310), it is measured whether the quantity is the heating set capacity (S320) so that the quantity is more than the heating set capacity.

Then, by measuring the temperature of the water obtained (S330) and compares the water temperature and the heating set temperature (S340).

If the water temperature is less than the heating set temperature, since heating is necessary, the required heat amount required for heating the water obtained based on the heating set temperature and quantity is calculated (S350).

However, if the heating set temperature is low enough that water can be discharged without heating, water can be discharged immediately. However, if the heating set temperature is too low and the output temperature is low, it may cause inconvenience to the user. Setting the heating set temperature too low while using the hot water supply may be a setting by a user mistake, so that water can be discharged without heating only when the temperature is set at a predetermined level or more.

As an example of such an implementation, when the water temperature is higher than the preset heating temperature (S340) and less than the preset temperature (S360), the water temperature is measured again, and the water temperature is equal to or higher than the preset heating temperature (S360). In this case, it is possible to withdraw the water obtained and wait for operation.

The predetermined temperature is conditioned on being equal to or higher than the heating set temperature. An example of the preset temperature is 41 degrees Celsius. This is because the temperature is higher than the body temperature, so it does not cause inconvenience to the user even withdrawal without heating.

The present invention is not limited by the above-described embodiment and the accompanying drawings. It is intended that the scope of the invention be defined by the appended claims, and that various forms of substitution, modification, and alteration are possible without departing from the spirit of the invention as set forth in the claims. Will be self-explanatory.

10: power control signal generator 20a: first heater
20b: second heater 30: heater driving protection unit
40: quantity detector 50: temperature detector
60: communication unit 70: control unit
100: hot water supply device 200: main control device
300: water supply valve

Claims (13)

A first heater configured to have a first set capacity and heat the introduced water;
A second heater configured to have a second set capacity greater than the first set capacity and to heat the introduced water; And
A control unit configured to calculate a heater driving cycle of the first heater and the second heater according to a heating preset temperature of water, and to drive the first heater and the second heater according to the heater driving cycle,
The control unit calculates a heater driving cycle of the first heater by using a phase control scheme, and calculates a heater driving cycle of the second heater by using a zero crossing control scheme.
The apparatus of claim 1, wherein the control unit
And determining whether the temperature of the water flowing into the first heater and the second heater is smaller than the heating set temperature, and then calculating the heater driving cycle when the temperature of the water is smaller than the heating set temperature.
The method of claim 1,
The first set capacitance is greater than zero and less than 550 W,
The second set capacity is more than 550W and hot water supply, characterized in that less than 1250W capacity.
Preparing a first heater having a first set capacitance and a second heater having a second set capacitance greater than the first set capacitance;
Calculating a heater driving period of the first heater according to the heating set temperature of the water using a phase control method, and calculating a heater driving cycle of the second heater according to the heating set temperature of the water using a zero crossing control method; And
Driving the first heater and the second heater according to the heater driving cycle so that water flowing into the first heater and the second heater is heated and then discharged;
Hot water supply method comprising a.
5. The method of claim 4,
Determining whether a temperature of water introduced into the first heater and the second heater is smaller than the heating set temperature;
And calculating the heater driving cycle when the temperature of the water is smaller than the heating set temperature.
5. The method of claim 4,
The first set capacitance is greater than zero and less than 550 W,
The second set capacity is more than 550W and hot water supply method, characterized in that less than 1250W.
Preparing a first heater having a first set capacitance and a second heater having a second set capacitance greater than the first set capacitance;
An operation setting process of receiving a heating set temperature and a heating set quantity;
An operation preparation process of obtaining more than the heating set quantity and determining whether heating is required according to the temperature of the obtained water and calculating a required amount of heat for heating; And
If heating is required, the control unit selects one or more of the first heater and the second heater according to the required heat amount, calculates a heater driving cycle of the selected heater, and drives the selected heater according to the heater driving cycle. Process,
The control process includes calculating a heater driving cycle of the first heater using a phase control method, and calculating a heater driving cycle of the second heater using a zero crossing control method.
The method of claim 7, wherein the control process
When the required amount of heat is less than the first set capacitance, the first heater is selected as a heater to be driven, a heater driving cycle of the first heater is calculated by using a phase control method, and the first heater is driven. Hot water supply method comprising the step of controlling.
The method of claim 7, wherein the control process
When the required amount of heat is greater than or equal to the first set capacity and less than the second set capacity, the second heater is selected as a heater to be driven, and a heater driving cycle of the second heater is calculated using a zero crossing method, and the second And driving the heater comprises a second control step.
The method of claim 7, wherein the control process
When the required heat amount is greater than or equal to the second set capacity, the first heater and the second heater are selected as the heaters to be driven, and the heater driving cycle of the first heater is calculated by using a phase control method and the first heater is driven. And calculating a heater driving cycle of the second heater by using a zero crossing method and driving the second heater.
The method of claim 10, wherein the third control step
The second heater calculates a heating drive cycle to be driven according to the second set capacity,
And the first heater calculates the heating driving cycle to be driven according to the capacity obtained by subtracting the second set capacity from the required amount of heat.
The method of claim 7, wherein the operation preparation step
Obtaining more than the heating set quantity;
Measuring the water temperature of the water;
Calculating the amount of heat required for heating when the water temperature is less than the heating set temperature; And
If the water temperature is higher than the preset temperature includes the step of withdrawing water and waiting for operation,
The preset temperature is greater than the heating set temperature,
If the water temperature is above the heating set temperature and less than the predetermined temperature, the hot water supply method characterized in that for performing the process of measuring the water temperature again.
The method of claim 7, wherein
The first set capacitance is greater than zero and less than 550 W,
The second set capacity is more than 550W and hot water supply method, characterized in that less than 1250W.

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