KR102612877B1 - Instant water heater - Google Patents

Abstract

The present invention relates to an instantaneous water heater.
The instantaneous water heater according to the present invention includes a flow path, a plurality of heaters for heating water passing through the flow path, a water intake temperature sensor that measures the temperature of water entering the flow path, an input unit through which the target temperature and target flow rate are input from the user, and the water water temperature. It may include a control unit that selectively drives the plurality of heaters based on the water temperature measured by a sensor, the target temperature, and the target flow rate.

Description

Instant water heater {INSTANT WATER HEATER}

The present invention relates to an instantaneous water heater.

Methods of providing hot water can be broadly divided into storage type and instantaneous hot water type. The storage type is a method of heating a relatively large amount of water and storing it in a tank before providing it, while the instantaneous hot water type is a method of instantaneously heating and providing the required amount of water as it passes through the flow path. To control the outlet water temperature in the instantaneous hot water system, a method of switching (PID control) a high-output (approximately 3,000 W) heater using TRIAC is commonly used. However, this method has the problem of causing harmonics/flicker phenomenon.

The purpose of the present invention is to provide an instantaneous water heater that can quickly and accurately control the outlet water temperature without the above-mentioned problems.

The instantaneous water heater according to the present invention includes a flow path, a plurality of heaters for heating water passing through the flow path, a water intake temperature sensor that measures the temperature of water entering the flow path, an input unit through which the target temperature and target flow rate are input from the user, and the water water temperature. It may include a control unit that selectively drives the plurality of heaters based on the water temperature measured by a sensor, the target temperature, and the target flow rate.

In addition, it includes a water outlet temperature sensor for measuring the temperature of water leaving the flow path and a flow valve for controlling the flow rate of water passing through the flow path, and the control unit is based on the water outlet temperature measured by the water outlet temperature sensor and the target temperature. Thus, the flow valve can be further controlled.

In addition, it includes a storage unit that stores output values that can be implemented using the plurality of heaters, and the control unit calculates the output value required to heat the water using the water temperature, the target temperature, and the target flow rate, and if the storage If any of the output values stored in the storage unit is the same as the calculated output value, the same output value is selected. If none of the output values stored in the storage unit is the same as the calculated output value, the output value closest to it is selected, and the selected output value is implemented. The plurality of heaters may be selectively driven so as to do so.

Additionally, when none of the output values stored in the storage unit is the same as the calculated output value, the controller may select the output value that is closest to the calculated output value among those less than the calculated output value.

Additionally, when none of the output values stored in the storage unit is the same as the calculated output value, the controller may select the output value that is closest to the output value among those that are less than the calculated output value plus an allowable value.

In addition, when there are two or more combinations of heaters that can implement the selected output value, the control unit selectively drives the plurality of heaters according to one combination once, and then selectively operates the plurality of heaters according to another combination. It can be driven.

In addition, it includes a flow valve for controlling the flow rate of water passing through the flow path, and the control unit can further control the flow valve based on the calculated output value and the selected output value.

The instantaneous water heater according to the present invention calculates the output value required to heat water and selectively drives a plurality of heaters according to the calculated output value, thereby preventing the harmonics/flicker phenomenon when switching (PID control) a high-output heater using a conventional TRIAC. The outlet temperature can be controlled without this problem.

Additionally, when there is a difference between the outlet water temperature and the target temperature, the outlet water temperature can be controlled more accurately by adjusting the flow rate of water passing through the flow path through the flow valve to compensate for the difference.

Figure 1 is a configuration diagram of an instantaneous water heater 10 according to an embodiment of the present invention.
Figure 2 is a flowchart of the operation of the control unit 19 of the instantaneous water heater 10 according to an embodiment of the present invention.

The instantaneous water heater 10 according to an embodiment of the present invention will be described in detail with reference to the drawings.

Figure 1 is a configuration diagram of an instantaneous water heater 10 according to an embodiment of the present invention.

Referring to Figure 1, the instantaneous water heater 10 includes a flow path 11, a heater 12, an inlet temperature sensor 13, an outlet temperature sensor 14, a flow sensor 15, a flow valve 16, and a storage unit. (17), including an input unit 18 and a control unit 19.

The heater 12 is installed on the flow path 11 and instantaneously heats the water passing through the flow path 11. A plurality of heaters 12 are provided and can be individually operated (ON/OFF). For example, when three heaters 12 are provided, each being A, B, and C, the number of operating cases is as follows (except for all OFF).

CASE heater ON/OFF
One A ON B OFF C OFF
2 A OFF B ON C OFF
3 A OFF B OFF C ON
4 A ON B ON C OFF
5 A ON B OFF C ON
6 A OFF B ON C ON
7 A ON B ON C ON

The water temperature sensor 13 is installed on the inlet side of the flow path 11 and measures the temperature of water entering the flow path 11 (water intake temperature).

The outlet water temperature sensor 14 is installed on the outlet side of the flow path 11 and measures the temperature of the water leaving the flow path 11 (outlet water temperature).

The flow sensor 15 measures the flow rate of water passing through the flow path 11. In Figure 1, the flow sensor 15 is shown to be disposed between the water temperature sensor 13 and the heater 12, but this is purely for convenience of illustration, and the flow rate of water passing through the flow path 11 (to the user) The flow sensor 15 may be placed in other locations as long as it can properly measure the flow rate of water to be provided.

The flow valve 16 serves to control the flow rate of water passing through the flow path 11. Likewise, in Figure 1, the flow valve 16 is shown to be disposed between the heater 12 and the outlet temperature sensor 14, but this is purely for convenience of illustration, and the flow rate of water passing through the flow path 11 is shown as If properly adjusted, the flow valve 16 may be placed in other positions.

The storage unit 17 stores output values that can be implemented using a plurality of heaters 12.

For example, if there are three heaters, each of 1,000 W (A, B, C), the output values that can be achieved using them are 1,000 W, 2,000 W, and 3,000 W as follows.

CASE heater ON/OFF full output
One A ON
1,000W B OFF C OFF
2 A OFF B ON C OFF
3 A OFF B OFF C ON
4 A ON
2,000W B ON C OFF
5 A ON B OFF C ON
6 A OFF B ON C ON
7 A ON
3,000W B ON C ON

As another example, when three heaters 12 are provided, each of 500 W (A), 1,000 W (B), and 1,000 W (C), the output values that can be realized using these are 500 W, 1,000 W, 1,500 W, 2,000 W and 2,500 W are as follows.

CASE heater ON/OFF full output
One A ON
500W B OFF C OFF
2 A OFF
1,000W B ON C OFF
3 A OFF B OFF C ON
4 A ON
1,500W B ON C OFF
5 A ON B OFF C ON
6 A OFF
2,000W B ON C ON
7 A ON
2,500W B ON C ON

As another example, when three heaters 12 are provided, each of which is 500 W (A), 1,000 W (B), and 1,500 W (C), the output values that can be realized using these are 500 W, 1,000 W, and 1,500 W. , 2,000 W, 2,500 W and 3,000 W as shown below.

CASE heater ON/OFF full output
One A ON
500W B OFF C OFF
2 A OFF
1,000W B ON C OFF
3 A OFF
1,500W B OFF C ON
4 A ON B ON C OFF
5 A ON
2,000W B OFF C ON
6 A OFF
2,500W B ON C ON
7 A ON
3,000W B ON C ON

Below, for convenience of understanding, the explanation is based on this example.

The input unit 18 receives target temperature (eg, 85°C) and target flow rate (eg, 120 ml) from the user.

The control unit 19 selectively drives the plurality of heaters 12 based on the water intake temperature, target temperature, and target flow rate.

More specifically, referring to FIG. 2, the control unit 19 calculates the output value required to heat water using the water intake temperature, target temperature, and target flow rate (S10).

Next, if any of the output values stored in the storage unit 17 is the same as the calculated output value, the control unit 19 selects the same output value (S21) and selects a plurality of heaters 12 to implement the selected output value. Run (S30). For example, if the calculated output value is 1,500 W, the control unit 19 selectively drives the plurality of heaters 12 according to CASE 3 or CASE 4 (see Table 4).

Meanwhile, if none of the output values stored in the storage unit 17 is the same as the calculated output value, the control unit 19 selects the output value closest to it (S22) and selectively operates a plurality of heaters 12 to implement the selected output value. Run (S30). For example, if the calculated output value was 1,750 W, the control unit 19 selects 1,500 W or 2,000 W that is closest to 1,750 W among 500 W, 1,000 W, 1,500 W, 2,000 W, 2,500 W, and 3,000 W, and CASE 3, a plurality of heaters 12 are selectively driven according to CASE 4 or CASE 5 (see Table 4).

Moreover, when none of the output values stored in the storage unit 17 is the same as the calculated output value, the control unit 19 selects one of the output values stored in the storage unit 17 to prevent product overheating and resulting damage or accidents. Among those that are less than the calculated output value, the output value that is closest to it can be selected. For example, if the calculated output value is 1,750 W, the control unit 19 selects 1,500 W that is closest to 1,750 W among 500 W, 1,000 W, and 1,500 W that are less than 1,750 W, and operates a plurality of heaters according to CASE 3 or CASE 4. (12) can be operated selectively. Additionally, the control unit 19 may select the output value that is closest to the output values stored in the storage unit 17 among those that are less than the calculated output value plus the allowable value. Here, the allowable value refers to a value set by the designer within a range that may not have a serious effect on product overheating even if the operating value is slightly higher than the output value calculated by the control unit 19. For example, if the calculated output value is 1,900 W and the allowable value is 200 W, the control unit 19 selects 2,000 W that is closest to 1,900 W among 500 W, 1,000 W, 1,500 W, and 2,000 W that are less than 2,100 W, According to CASE 5, a plurality of heaters 12 can be selectively driven. According to this, product overheating can be minimized and the outlet temperature can be quickly controlled.

Furthermore, in order to prevent a specific heater 12 from operating more frequently and aging the heater 12 more quickly, the control unit 19 operates if there are two or more cases (heater combinations) that can implement the selected output value, The cases can be operated alternately. For example, if the selected output value is 1,500 W, the control unit 19 selectively drives the plurality of heaters 12 according to CASE 3 once and selectively operates the plurality of heaters 12 according to CASE 4 the next time. It can be driven.

Next, the control unit 19 controls the flow valve 16 based on the outlet temperature and the target temperature. For example, if the calculated output value and the selected output value (output value to be actually implemented) are different, there may be a difference between the outlet temperature and the target temperature. For example, if the calculated output value was 1,750 W, but the selected output value was 1,500 W, the outlet temperature may be lower than the target temperature. On the other hand, if the calculated output value was 1,900 W and the selected output value was 2,000 W, the outlet temperature may be higher than the target temperature. In addition, even if the calculated output value and the selected output value are the same, there may be a difference between the outlet temperature and the target temperature due to errors in design or use. Correspondingly, the control unit 19 can control the outlet water temperature by adjusting the flow rate of water passing through the flow path 11 through the flow valve 16. More specifically, when the outlet water temperature is lower than the target temperature, the control unit 19 can increase the outlet water temperature by reducing the flow rate of water passing through the flow path 11 through the flow valve 16 (S41). On the other hand, if the outlet water temperature is higher than the target temperature, the control unit 19 can lower the outlet water temperature by increasing the flow rate of water passing through the flow path 11 through the flow valve 16 (S42).

Meanwhile, the control unit 19 may further control the flow valve 16 based on the calculated output value and the selected output value. For example, if the calculated output value was 1,750 W and the selected output value was 1,500 W, the control unit 19 predicted in advance that the outlet water temperature would be lower than the target temperature, and the water flowing through the flow path 11 through the flow valve 16 The water flow rate can be reduced preemptively. If the calculated output value was 1,600 W and the selected output value was 1,500 W, the control unit 19 reduces the flow rate of water passing through the flow path 11 through the flow valve 16, but in the above example (where the calculated output value was 1,750 W) case), the flow rate of water passing through the flow path 11 will be reduced relatively less. On the other hand, if the calculated output value was 1,900 W and the selected output value was 2,000 W, the control unit 19 predicted in advance that the outlet water temperature would be higher than the target temperature, and the flow rate of water passing through the flow path 11 through the flow valve 16 can be preemptively increased.

The instantaneous water heater 10 described above is only one of the instantaneous water heaters according to various embodiments of the present invention. The technical idea of the present invention is not limited to the above embodiments, and as described in the claims, includes all modifications that can be easily made by a person skilled in the art to which the present invention pertains.

Claims (7)

Euro,
A plurality of heaters, each controlled ON/OFF, for heating the water passing through the flow path,
An inlet temperature sensor that measures the temperature of water entering the flow path,
A flow valve for controlling the flow rate of water passing through the flow path,
A storage unit storing output values that can be implemented using the plurality of heaters,
An input unit where the target temperature and target flow rate are input from the user, and
A control unit that selectively drives the plurality of heaters based on the water temperature measured by the water temperature sensor, the target temperature, and the target flow rate,
The control unit calculates the output value required to heat water using the water intake temperature, the target temperature, and the target flow rate, and if any of the output values stored in the storage unit is the same as the calculated output value, the same output value is selected. , if none of the output values stored in the storage unit is the same as the calculated output value, the output value closest to it is selected, the plurality of heaters are selectively driven to implement the selected output value, and the calculated output value and the selected output value are selected. In this other case, an instantaneous water heater further controls the flow valve based on the calculated output value and the selected output value. According to paragraph 1,
A water outlet temperature sensor that measures the temperature of water leaving the flow path, and
It includes a flow valve for controlling the flow rate of water passing through the flow path,
The control unit is an instantaneous water heater that further controls the flow valve based on the target temperature and the outlet water temperature measured by the outlet water temperature sensor. delete According to paragraph 1,
The instantaneous water heater wherein when none of the output values stored in the storage unit is the same as the calculated output value, the control unit selects an output value that is closest to the calculated output value among those less than the calculated output value. According to paragraph 1,
When none of the output values stored in the storage unit is the same as the calculated output value, the control unit selects the output value most similar to the output value that is less than the calculated output value plus an allowable value. According to paragraph 1,
When there are two or more combinations of heaters that can implement the selected output value, the control unit selectively drives the plurality of heaters according to one combination once and selectively drives the plurality of heaters according to another combination the next time. Instant water heater. delete