KR102278541B1 - Method for producing instant water heater - Google Patents

Abstract

The present invention relates to an initial setting method for manufacturing an instantaneous water heater.
The instantaneous water heater manufacturing method according to the present invention is an instantaneous water heater manufacturing method comprising a heater for heating water and a controller for controlling the operation of the heater, the operating step of operating the heater at a specific duty ratio of less than 100%, the heater A measurement step of measuring the applied voltage and its output, a calculation step of obtaining the maximum output of the heater by comparing the voltage and output measured in the measurement step with a predetermined lookup table, and the maximum output obtained in the calculation step to the controller By inputting the input, the control unit may include an input step for operating the heater with a duty ratio inversely proportional to the maximum output.

Description

Instantaneous water heater manufacturing method {METHOD FOR PRODUCING INSTANT WATER HEATER}

The present invention relates to a method for manufacturing an instantaneous water heater, and more particularly, to an initial setting method for manufacturing an instantaneous water heater.

Often, there are so-called hot water storage type and instantaneous heating type as a method for heating water in a water purifier or water heater. Recently, instantaneous heating is being used more and more for energy saving and hygiene. This instantaneous heating type is made in such a way that the water is instantaneously heated and discharged by allowing the user to pass through the heater when the amount of water desired by the user is discharged.

However, at this time, the maximum output of each heater to be installed in the water heater may be different from each other. Some heaters may have a relatively higher maximum output, and some heaters may have a relatively lower maximum output. In this case, if all heaters are operated at the same duty ratio, there is a problem that the temperature of the water heated in each water heater is different from each other.

To prevent this, the temperature of the water heated in the water heater is measured, and if the temperature is higher than the reference temperature, the duty ratio of the heater is lowered, and if the temperature is lower than the reference temperature, the duty ratio of the heater is raised. A solution has been proposed.

However, according to this, since the correction is performed once the water is heated, there is a limit in accurately controlling the temperature of the water in an instantaneous heating type water heater in which the water is instantaneously heated within a few seconds.

In order to solve the above problem, an object of the present invention is to provide a method for manufacturing an instantaneous water heater that can be set to accurately control the temperature of water during manufacturing.

In the instantaneous water heater manufacturing method according to the present invention, the instantaneous water heater manufacturing method comprising a heater for heating water and a controller for controlling the operation of the heater, an operation step of operating the heater with a specific duty ratio of less than 100%, the heater A measurement step of measuring the applied voltage and its output, a calculation step of obtaining the maximum output of the heater by comparing the voltage and output measured in the measurement step with a predetermined lookup table, and the maximum output obtained in the calculation step to the controller By inputting the input, the control unit may include an input step for operating the heater at a duty ratio inversely proportional to the maximum output.

Also, in the operation step, the heater may be disposed on a flow path through which water passes.

Also, in the operation step, the duty ratio may be set to a value that prevents water from boiling.

Also, in the operation step, at least one of a temperature and a flow rate of water flowing into the flow path may be constantly maintained.

Also, the measuring step may be performed after a predetermined time has elapsed from the start of the starting step.

Also, in the measuring step, measuring the voltage and the output a plurality of times, and calculating the average of the plurality of voltages and the output measured in the measuring step, respectively, further comprising the step of, in the calculating step, the voltage and the output The average can be compared to a predetermined lookup table.

In the instantaneous water heater manufacturing method according to the present invention, when the instantaneous water heater is manufactured, the maximum output of the heater is obtained and the controller operates the heater at a duty ratio inversely proportional to the maximum output, so that even if the maximum output of each heater is different, each instantaneous water heater It is possible to make all the heated water at the same temperature.

1 is a block diagram of an instantaneous water heater in a method for manufacturing an instantaneous water heater according to an embodiment of the present invention.
2 is a flowchart of a method for manufacturing an instantaneous water heater according to an embodiment of the present invention.

Hereinafter, a method for manufacturing an instantaneous water heater according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

First, the instantaneous water heater 10 will be briefly described.

1 is a block diagram of an instantaneous water heater 10 in a method for manufacturing an instantaneous water heater according to an embodiment of the present invention, and only some components are schematically shown. However, those skilled in the art will be able to clearly understand and easily reproduce the instantaneous water heater 10 as seen through the following description based on the known configuration of the instantaneous water heater.

Referring to FIG. 1 , the instantaneous water heater 10 includes a flow path 11 , a heater 12 , and a control unit 13 .

The flow path 11 is a path for water to pass. In general, one end of the flow path 11 is connected to a water source such as a water storage tank, and the other end is connected to the outside. Accordingly, the water from the water source is discharged to the outside through the flow path 11 and supplied to the user.

The temperature or flow rate of water flowing into the flow path 11 may vary according to individual design conditions or usage conditions of the instantaneous water heater 10 .

The heater 12 is installed on the flow path 11 to generate heat.

The heater 12 may generate heat by Joule heat according to electrical resistance. For example, the heater 12 may be a ceramic heater or the like.

Accordingly, when the heater 12 generates heat, the water from the water source is discharged to the outside through the flow path 11 and is instantaneously heated by the heater 12 .

In this case, in general, the higher the electrical resistance of the heater 12, the higher the water is heated by the heater 12 relatively high temperature. Conversely, the lower the electrical resistance of the heater 12 is, the lower the water is heated by the heater 12 to a relatively low temperature.

The control unit 13 serves to control the operation of the heater 12 . That is, the controller 13 may selectively operate or stop the heater 12 .

In addition, the control unit 13 may operate the heater 12 at a specific duty ratio so that the water is appropriately heated to a desired temperature.

In general, as the controller 13 operates the heater 12 at a larger duty ratio, the water is heated to a relatively higher temperature. Conversely, as the controller 13 operates the heater 12 at a smaller duty ratio, the water is heated to a relatively low temperature.

Meanwhile, when there are a plurality of heaters 12 , the electrical resistance of each heater 12 may be different from each other. Some heaters 12 may have a higher electrical resistance, and some heaters 12 may have a smaller electrical resistance.

Therefore, when manufacturing the instantaneous water heater 10, if the controller 13 is set to operate all the heaters 12 only with the same duty ratio, the temperature of the water heated in each instantaneous water heater 10 will be different from each other. That is, the temperature of the water heated in the instantaneous water heater 10 equipped with the heater 12 having a large electrical resistance will be higher, and the temperature of the water heated in the instantaneous water heater 10 equipped with the heater 12 having a small electric resistance is higher. will be low Accordingly, there is a problem that it is impossible to accurately control the temperature of water and the reliability of the product may be lowered.

In order to prevent this, in the instantaneous water heater manufacturing method according to the embodiment of the present invention, when the instantaneous water heater 10 is manufactured, the controller 13 obtains the maximum output of the heater 12 and controls the heater 13 at a duty ratio that is inversely proportional to the maximum output. 12) is activated.

More specifically, FIG. 2 is a flowchart of a method for manufacturing an instantaneous water heater according to an embodiment of the present invention.

Referring further to FIG. 2 , the instantaneous water heater manufacturing method includes a heater operation step S11 , a voltage and output measurement step S12 , a maximum output calculation step S13 , and a maximum output input step S14 .

First, in the heater operation step (S11), the heater 12 is placed on the flow path through which water passes and is operated.

Here, the flow path is a type of test device corresponding to the flow path 11 of the instantaneous water heater 10 described with reference to FIG. 1 above, and the temperature or flow rate of water flowing into the flow path is determined in the actual use condition of the instantaneous water heater 10. It is created in the same environment as the temperature or flow rate of water flowing into the flow path 11 . That is, if it is assumed that the temperature of the water flowing into the flow path 11 is about 20° C. and the flow rate is about 30 ml/s under the actual use conditions of the instantaneous water heater 10, the heater 12 in the heater operation step S11 is also about Water at 20° C. is placed on the flow passage through which it passes at about 30 ml/s.

In particular, at this time, the heater 12 is operated at a specific duty ratio of less than 100%. For example, the heater 12 may be operated at a duty ratio of about 50%.

As will be described later, when measuring the voltage and output in the voltage and output measuring step (S12), in order to further increase the accuracy of the measurement, the voltage and output measuring step (S12) is performed after the heater operation step (S11) starts and for some time After this elapses and the heater 12 reaches a steady state, it proceeds. However, if the heater 12 is operated at a duty ratio of 100%, water may boil before the heater 12 reaches a steady state. Then, since the accuracy of the measurement may be rather deteriorated, the heater 12 is operated at a duty ratio that can ensure that the water does not boil.

In the voltage and output measurement step S12 , the voltage applied to the heater 12 and its output are measured.

At this time, in order to further increase the accuracy of the measurement, it is preferable that the temperature or flow rate of water flowing into the flow path is kept constant.

Next, in the maximum output calculation step (S13), the voltage and output measured in the voltage and output measurement step (S12) are compared with a predetermined lookup table, and when the heater 12 is operated at a duty ratio of 100%, the heater 12 The output of , that is, the maximum output of the heater 12 is obtained.

The lookup table may be configured in the form shown in Table 1 below. However, since the value corresponding to each column may vary according to individual design conditions or usage conditions of the heater 12, it is not specifically shown.

is it
Voltage 2800W 2900W 3000W 3100W remark Ieast maximum Ieast maximum Ieast maximum Ieast maximum 215V 216V 217V 218V 219V 220V · ‥ … 1475W 1525W … ‥ 221V 222V 223V 224V 225V

Referring to the lookup table, for example, when the heater 12 is operated at a duty ratio of about 50%, the voltage applied to the heater 12 is measured to be about 220V, and the output is measured to be about 1475W to about 1525W , when the heater 12 is operated at a duty ratio of 100%, the output of the heater 12 is obtained as about 3000W.

Meanwhile, in order to more accurately obtain the maximum output of the heater 12 , the voltage and the output may each be measured a plurality of times in the voltage and output measurement step S12 . In this case, an average of a plurality of voltages and outputs may be calculated, and the average may be compared with the lookup table.

Next, in the maximum output input step S14 , the maximum output of the heater 12 obtained in the maximum output calculation step S13 is input to the controller 13 . Then, the controller 13 calculates an appropriate duty ratio that is inversely proportional to the maximum output of the heater 12 , and operates the heater 12 with the duty ratio.

For example, let's assume that the user wants water at about 90°C. Also, for example, it is assumed that the output of the heater 12 to be heated to about 90° C. while the water from the water source is discharged through the flow path 11 is about 2000W. At this time, if the maximum output of the heater 12 is obtained as about 3000W, the controller 13 will operate the heater 12 with a duty ratio of about 66.7% (2000/3000×100≒66.7). If the maximum output of the heater 12 is found to be about 2800W, the controller 13 will operate the heater 12 with a duty ratio of about 71.4% greater than that (2000/2800×100≒71.4).

Accordingly, the controller 13 can operate the heater 12 at different duty ratios according to the maximum output of the heater 12 . Therefore, when there are a plurality of heaters 12, even if the electrical resistance of each heater 12 is different from each other, the temperature of the water heated in each instantaneous water heater 10 can be made the same.

Of course, when only the maximum output of the heater 12 is input to the controller 13 as described above, the controller 13 may be designed to automatically calculate an appropriate duty ratio to operate the heater 12 with the duty ratio, and The duty ratio based on the maximum output may be separately calculated and the duty ratio may be directly input to the controller 13 .

Furthermore, by operating the assembled instantaneous water heater 10 again under actual use conditions, it is possible to test whether the output of the heater 12 is measured as a desired output or whether the water is heated to a desired temperature (S21). In the case of the above-mentioned example, it will be tested whether the output of the heater 12 is measured to be 2000W, or whether the water is heated to 90°C.

Accordingly, if the output of the heater 12 is measured as a desired output, or if the water is heated to a desired temperature, it may be finally determined that the instantaneous water heater 10 is a good product (S22).

Meanwhile, in order to perform this instantaneous water heater manufacturing method, a measuring instrument, PLC (Power Line Communication), and a computer may be provided to communicate with each other. In this case, when the voltage applied to the heater 12 and its output are measured with the measuring instrument and transmitted to the computer through the PLC, the maximum output of the heater 12 is obtained from the computer and input to the control unit 13. The steps described above can be automated.

The embodiments of the present invention described above and shown in the drawings do not limit the technical spirit of the present invention. The protection scope of the present invention is determined by the matters described in the claims. On the other hand, those skilled in the art will be able to variously improve or change the technical idea of the present invention. Such improvements or modifications fall within the protection scope of the present invention as long as it is apparent to those skilled in the art.

Claims (6)

In the instantaneous water heater manufacturing method comprising a heater for heating water and a controller for controlling the operation of the heater,
operation step of starting the heater of the instantaneous water heater;
A measuring step of measuring the voltage applied to the heater and its output;
a calculation step of comparing the voltage and output measured in the measuring step with a predetermined look-up table to obtain the maximum output of the corresponding heater; and
By inputting the maximum output obtained in the calculation step to the controller, the controller includes an input step for operating the heater with a duty ratio inversely proportional to the maximum output,
The starting step is to operate the heater at a specific duty ratio of less than 100%,
The calculation step is to calculate the maximum output of the heater by calculating the output measured under a specific duty ratio of less than 100% when a duty ratio of 100% is applied,
How to make an instantaneous water heater. According to claim 1,
In the starting step, the heater is an instantaneous water heater manufacturing method disposed on a flow path through which water passes. 3. The method of claim 2,
In the starting step, the duty ratio is determined to a value that prevents water from boiling. 3. The method of claim 2,
In the operation step, the instantaneous water heater manufacturing method in which at least one of a temperature or a flow rate of water flowing into the flow path is kept constant. According to claim 1,
The measuring step is an instantaneous water heater manufacturing method in which the starting step is started and a predetermined time has elapsed. According to claim 1,
In the measuring step, the voltage and the output are measured a plurality of times,
Further comprising the step of calculating the average of the plurality of voltages and outputs measured in the measuring step, respectively,
In the calculating step, the instantaneous water heater manufacturing method for comparing the average of the voltage and the output with a predetermined look-up table.

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