KR102527692B1 - Warm water supply controlling apparatus - Google Patents

Abstract

The present invention is directed to a hot water supply control device capable of protecting a heater by controlling the output of a heater and/or the flow rate of purified water supplied to a heater tank by checking an abnormal temperature detection state of a temperature sensor for detecting the temperature of purified water in a heater tank. it's about
An apparatus for controlling hot water supply according to the present invention includes a heater tank having a heater to heat purified water and supplying hot water, a purified water supply passage having a first path for constantly supplying the purified water to the heater tank, and the hot water in the heater tank. A water outlet for dispensing water, a temperature sensor for detecting the temperature of the hot water in the heater tank or the hot water discharged from the heater tank, a water inlet valve for supplying and blocking the purified water to the purified water supply passage, and in the process of dispensing hot water A control unit for controlling the inlet valve to supply the purified water to the heater tank, operating the heater with a normal output, and then determining a temperature sensing state of the temperature sensing unit based on a change in temperature sensed by the temperature sensing unit. It consists of

Description

Hot water supply control device {WARM WATER SUPPLY CONTROLLING APPARATUS}

The present invention relates to an apparatus for controlling the supply of hot water, and more particularly, by controlling the output of a heater and/or the flow rate of purified water supplied to a heater tank by checking an abnormal temperature detection state of a temperature sensor for detecting the temperature of purified water in a heater tank to operate a heater. It relates to a hot water supply control device that can be protected.

Recently used hot water supply devices of water purifiers are classified into a water tank type in which a heater is installed in the water tank and an instantaneous hot water type in which supplied water is heated using a heater whenever necessary.

Since the water tank-type hot water supply device always maintains the temperature of water in the water tank at a set temperature regardless of whether hot water is used or not, standby power is wasted and a lot of space is occupied. Therefore, in recent years, an instantaneous hot water type hot water supply device for supplying hot water by instantaneously heating water according to a user's request for hot water supply has been widely used.

The applicant of the present invention has applied for Republic of Korea Patent Publication No. 10-2015-0007179 "instant hot water supply device" (hereinafter referred to as 'prior art'). The hot water tank described in this prior art is composed of a heating plate equipped with a heater and a case coupled to the heating plate to form a storage space in which water can be stored or flowed between the heating plate, and a connection pipe is provided on the upper side of the case. An inlet connected to the water inlet, an air outlet for discharging air in the storage space, an outlet connected to the connection pipe for discharging heated water, and a second temperature sensor leading to at least partially inserted into the storage space A fastening part to which the insertion hole and the fastening member for fixing the second temperature sensor are fastened is formed. In particular, the second temperature sensing unit is inserted into the first through hole of the connection part and inserted into the insertion hole, and is inserted into the storage space so that the water temperature inside the hot water tank can be sensed, so that the fastening member passes through the second through hole of the connection part. It is screwed into the fastening part and fixed to the hot water tank.

In the prior art described above, driving control of the heater is performed according to the temperature of the water sensed by the second temperature sensor. The second temperature sensing unit, for example, a single unit defect of the temperature sensing unit, a fixing failure of the temperature sensing unit (when at least a part of the temperature sensing unit is separated from the hot water tank and does not contact water in the storage space), a temperature sensing failure of the temperature sensing unit ( In the case of an abnormal temperature sensing condition, such as when an air layer exists inside the storage space due to a leak in the hot water tank or a lack of water supply to the hot water tank, the temperature sensing unit contacts the air layer and does not contact water), the second temperature sensing unit The temperature of the water in the storage space cannot be accurately sensed. If the second temperature sensor is in a temperature detection abnormal state, even if the heater is operated, the water temperature in the hot water tank is incorrectly recognized as lower than the water outlet target temperature, so that output is continuously applied to the heater, resulting in boiling or heater burnout. A problem arises. Even if a well-known bimetal is used for voltage blocking, it is not a fundamental solution because there is a possibility that the heater may already be burnt out before the bimetal operates.

Moreover, when the heater is burnt out, there is a high risk of electric shock and fire due to electric leakage. In addition, it is possible to solve the temperature sensing abnormal condition only by replacing or repairing the temperature sensing part, but since there is no way to check whether the temperature sensing is abnormal, the product itself must be replaced with a new product, so the AS cost is high. There are also growing problems.

Republic of Korea Patent Publication No. 10-2015-0007179 "instant hot water supply device"

The present invention provides a hot water supply control device capable of protecting a heater by checking an abnormal temperature detection state of a temperature sensor for detecting the temperature of purified water in a heater tank and controlling the output of a heater and the flow rate of purified water supplied to the heater tank. aims to

An apparatus for controlling hot water supply according to the present invention includes a heater tank having a heater to heat purified water and supplying hot water, a purified water supply passage having a first path for constantly supplying the purified water to the heater tank, and the hot water in the heater tank. A water outlet for dispensing water, a temperature sensor for detecting the temperature of the hot water in the heater tank or the hot water discharged from the heater tank, a water inlet valve for supplying and blocking the purified water to the purified water supply passage, and in the process of dispensing hot water A control unit for controlling the inlet valve to supply the purified water to the heater tank, operating the heater with a normal output, and then determining a temperature sensing state of the temperature sensing unit based on a change in temperature sensed by the temperature sensing unit. It consists of

Preferably, the control unit determines the temperature sensing state of the temperature sensing unit based on a temperature difference between a temperature sensed before the heating operation of the heater and a temperature sensed after the heating operation of the heater.

In addition, when the temperature sensing state of the temperature sensing unit is in an abnormal state, the control unit may set and store the temperature sensing state of the temperature sensing unit in an abnormal state, and perform a protective water extraction operation to protect the heater.

Preferably, the control unit performs a protective water dispensing operation of reducing the output of the heater to a protected output and dispensing hot water in the heater tank by controlling the water intake valve and the water outlet.

In addition, the purified water supply passage is provided with a flow rate control valve independent of the first route and controlled by the control unit to have a second path for blocking and supplying the purified water to the heater tank, and the control unit Controls the flow control valve to open state to increase the flow rate of purified water supplied to the heater tank through the first path and the second path, and controls the water intake valve and the water outlet to discharge hot water from the heater tank It is desirable to perform a protective water exit operation.

In addition, while performing the protective water extraction operation, the control unit compares a temperature difference between a temperature detected at the start of the hot water extraction operation and a temperature detected during the protective water extraction operation and a second temperature difference to determine a temperature sensing state of the temperature sensing unit. It is desirable to judge

In addition, when the temperature difference between the detected temperature at the start of the hot water extraction and the detected temperature during the protective water extraction operation is greater than the second temperature difference, the controller releases and stores the stored abnormal state, and detects the temperature. It is preferable to determine the negative temperature sensing state as a normal state and perform the normal water extraction operation according to the control operation of the protected water extraction operation.

In addition, when the temperature sensing state of the temperature sensing unit is in a normal state, the control unit may perform a normal water dispensing operation of dispensing hot water in the heater tank by controlling the water intake valve and the water outlet after the second reference time.

The present invention checks the temperature detection abnormal state of the temperature detection unit for detecting the temperature of the purified water in the heater tank, and controls the output of the heater and the flow rate of purified water supplied to the heater tank when the temperature detection abnormal state is detected to prevent burnout of the heater, There is an effect of preventing electric leakage problems due to burnout of heaters, electric shock accidents and fires due to electric leakage.

In addition, the present invention has the effect of solving the abnormal state of the temperature sensor only by replacing or repairing the temperature sensor without replacing the entire product through detection and display of the abnormal state of the temperature sensor.

1 is a configuration diagram of a hot water supply control device.
FIG. 2 is a control flow chart of the hot water supply control device of FIG. 1 .

Hereinafter, the present invention is explained in detail through examples and drawings.

1 is a configuration diagram of a hot water supply control device.

The hot water supply control device is an instantaneous hot water type hot water supply control device, and is composed of a flow path device for obtaining purified water and dispensing water as hot water, and a control device for controlling the flow path device. The hot water supply control device includes a filter device that purifies raw water and supplies the purified water to a flow path device. Such a filter device is only a technique widely known to those skilled in the art to which the present invention belongs, and the description thereof is not sufficient. It is omitted.

First, the flow path device includes a first pressure reducing valve 1 for reducing the pressure of purified water received to a first pressure, and a water intake valve 2 for supplying and blocking the purified water obtained from the first pressure reducing valve 1. and a flow sensor 3 for detecting the flow rate of purified water passing through the water inlet valve 2, and a second pressure reducing valve 4 for reducing the water inlet pressure of the purified water that has passed through the flow sensor 3 to a second pressure ), first and second paths P1 and P2 for supplying purified water passing through the second pressure reducing valve 4 to the heater tank 8, and heating the supplied purified water using a heater to supply hot water It is composed of a heater tank 8 and a water outlet valve 9 which is a water outlet that supplies and shuts off heated purified water (hot water). However, the first and second pressure reducing valves 1 and 4, the water inlet and outlet valves 2 and 9, the flow sensor 3, and the heater tank 8 are those skilled in the art. Since it is only a widely known technology to those who know it, its description is omitted.

The first path P1 is a flow path that constantly supplies purified water that has passed through the second pressure reducing valve 4 to the heater tank 8, and has a first orifice 5 that performs linear flow control on the flow path.

The second path P2 is a flow path for supplying the purified water that has passed through the second pressure reducing valve 4 independently of the first path P1 to the heater tank 8, and a control device (control unit 30) on the flow path ) and a flow control valve 6 (for example, a solenoid valve) turned on/off by a second orifice 7 for linear flow control. The flow control valve 6 is a device for controlling the flow rate when hot water is discharged, and supplies and blocks purified water through the second path P2.

In this specification, the first path P1 or the first path P1 and the second path P2 are referred to as purified water supply passages.

Next, the control device includes a first temperature sensor 11 that senses the temperature of purified water (purified water before being supplied to the heater tank 8, purified water in the first path P1), and input from the user. An input unit 13 for acquiring (hot water or purified water selection, water extraction selection, water extraction termination selection, hot water temperature setting, etc.) and a display unit for displaying information (hot water or purified water selection status, hot water temperature, water extraction status, etc.) 15), a second temperature sensor 17 for sensing the temperature of hot water in the heater tank 8 or hot water discharged from the heater tank 8, and a heater driver 19 for driving the heater in the heater tank 8 ), a power supply unit 21 for supplying power necessary for the hot water supply control device, and supplying hot water by controlling the above-described components, and detecting the second temperature based on the temperature detected by the second temperature sensor 17 The controller 30 is provided to protect the heater by checking the temperature detection abnormal state of the unit 17 and controlling the output of the heater and the flow rate of purified water supplied to the heater tank. However, the first and second temperature sensing units 11 and 17, the input unit 13, the display unit 15, the heater driving unit 19, and the power supply unit 21 are those skilled in the art. Since it is only a widely known technology to those who know it, its description is omitted.

The control unit 30 has a function of obtaining purified water and discharging hot water heated by the heater tank 8, a function of adjusting the flow rate of purified water supplied to the heater tank 8, and a heater of the heater tank 8 It performs the function of regulating the output. In particular, the control unit 30 determines the temperature sensing abnormal state of the second temperature sensor 17 before hot water is discharged, and when it is determined that the temperature detection abnormal state, performs a protective water extraction operation to protect the heater, If the temperature detection is in a normal state, normal water extraction operation is performed. In addition, while performing the protective water extraction operation, the control unit 30 continuously determines the temperature sensing abnormal state of the second temperature sensor 17, and performs the protective water extraction operation when the temperature detection abnormal state is determined, If the temperature detection is in a normal state, normal water extraction operation is performed.

In detail, in order to determine an abnormal temperature detection state of the second temperature sensor 17 before hot water is discharged, the control unit 30 determines the detected temperature T1 before the heating operation of the heater and the heater heating for the first reference time. The detected temperature (T2) after operation is compared. When the second temperature sensing unit 17 is in a temperature sensing abnormal state, the temperature rise (or change in temperature rise) of the sensed temperature T2 is little or small compared to the sensed temperature T1. In order to use this point, when the second temperature sensor 17 is in a temperature sensing normal state, the temperature difference (T2-T1) between the detected temperature T2 and the detected temperature T1 is caused by the heating operation of the heater according to the reference output. ) is at least greater than the first temperature difference is set as the first reference time, for example, set to 4 seconds. The first temperature difference is set as a minimum temperature difference between the detected temperature T2 and the detected temperature T1 at which the second temperature sensor 17 can be determined to be in an abnormal state by the heating operation of the heater according to the reference output. In addition, since the detected temperature T2 increases as the first reference time, which is the heating operation time of the heater, increases, the first reference time and the first temperature difference have a proportional relationship in that the first temperature difference must be set to a higher temperature. there is For example, when the first time period is 4 seconds, the first temperature difference is set to 3°C. The control unit 30 determines that the second temperature sensing unit 17 is in a normal temperature sensing state when the temperature difference (T2-T1) between the sensing temperature T2 and the sensing temperature T1 is greater than the first temperature difference, and otherwise, that is, If the temperature difference (T2-T1) is less than or equal to the first temperature difference, it is determined that the second temperature sensor 17 is in an abnormal temperature sensing state. Also, when it is determined that the second temperature sensing unit 17 is in an abnormal temperature sensing state, the controller 30 sets the temperature sensing state of the second temperature sensing unit 17 to an abnormal state and stores the temperature sensing state. In addition, when it is determined that the second temperature sensing unit 17 is in a normal temperature sensing state, the control unit 30 sets the temperature sensing state of the second temperature sensing unit 17 to a normal state and stores the temperature sensing state.

Also, the control unit 30 performs a protective water extraction operation to protect the heater. The controller 30 controls the heater to supply hot water and performs a heating operation with a reference output, but when the second temperature sensor 17 is in an abnormal temperature detection state, the output of the heater is changed from the reference output to protect the heater. A protective water extraction operation of dispensing hot water is performed while reducing the protective output by a predetermined ratio (eg, 10%) or by the size. In addition, during this protective water extraction operation, the control unit 30 controls the flow control valve 6 simultaneously with or independently of the decrease in heater output to increase the flow rate of purified water supplied to the heater tank 8. may be

In addition, the control unit 30 continuously determines an abnormal temperature sensing state of the second temperature sensing unit 17 while performing a protective water extraction operation.

In detail, the controller 30 compares the detected temperature T3 at the start of hot water dispensing with the detected temperature T4 during the hot water dispensing operation. When the second temperature sensor 17 is in an abnormal temperature sensing state, the temperature rise (or change in temperature rise) of the sensed temperature T4 is little or small compared to the sensed temperature T3. Using this point, the control unit 30 determines that the second temperature sensing unit 17 is in a temperature sensing normal state when the temperature difference (T4-T3) between the sensing temperature T4 and the sensing temperature T3 is greater than the second temperature difference. and, if not, it is determined that the second temperature sensing unit 17 is in an abnormal temperature sensing state. Here, the second temperature difference is the minimum temperature difference between the detected temperature T4 and the detected temperature T3 at which the second temperature sensor 17 can be determined to be in a temperature sensing normal state by the heating operation of the heater according to the protection output. is set During the protected water extraction operation, if the second temperature sensor 17 determines that the temperature is in a normal state, the control unit 30 performs a normal water extraction operation, and the second temperature sensor 17 maintains an abnormal temperature detection state. If it is determined to be true, the protective water extraction operation continues. In addition, when it is determined that the second temperature sensing unit 17 is in a normal temperature sensing state, the control unit 30 releases and stores the previously stored abnormal state of the second temperature sensing unit 17 .

When the abnormal state is released, the control unit 30 performs a normal water extraction operation of dispensing hot water at a target temperature or higher for the hot water extraction operation with the reference output of the heater instead of the previously performed protected water extraction operation. However, the control unit 30 performs a different normal water extraction operation according to the previously performed control operation of the protected water extraction operation in order to perform the normal water extraction operation. For example, when the heater output only decreases to the protected output in the protected water extraction operation, the controller 30 performs a normal water extraction operation accompanying heater output control including only a process of returning the heater output to the reference output. Alternatively, when only an increase in the flow rate of purified water supplied to the heater tank 8 is performed in the protective water extraction operation, the controller 30 compares the temperature detected by the second temperature sensor 17 with the target temperature of the hot water extraction operation. Therefore, if the detected temperature of the second temperature sensor 17 is higher than the target temperature of the hot water extraction operation, the current purified water flow rate (ie, the increased purified water flow rate) is maintained, otherwise, the increased purified water flow rate in the protected water extraction operation Perform a normal water extraction operation accompanied by an adjustment of the purified water flow rate to reduce the In addition, for example, when the heater output is reduced and the flow rate of purified water supplied to the heater tank 8 is increased in the protected water extraction operation, the control unit 30 performs the normal water extraction operation accompanied by the above-described heater output control and The normal water extraction operation accompanied by the regulation of the purified water flow rate is carried out sequentially or simultaneously and independently.

Also, as described above, when the temperature sensing state of the second temperature sensing unit 17 is an abnormal state, the controller 30 sets the temperature sensing state of the second temperature sensing unit 17 to an abnormal state and stores the temperature sensing state. . In addition, when the temperature sensing state of the second temperature sensor 17 is converted to a normal state, the control unit 30 releases the stored abnormal state, that is, stores it as a normal state.

In FIG. 2 below, the hot water supply control procedure by the control unit 30 is described in detail.

FIG. 2 is a control flow chart of the hot water supply control device of FIG. 1 .

In step S1, power is applied to the hot water supply control device, and the controller 30 performs a standby state after receiving power.

In step S3, the control unit 30 determines whether hot water extraction input has been obtained through the input unit 13 while performing the standby state. The hot water outlet input may be configured in various ways, such as a configuration in which a hot water selection input and a water outlet selection input are sequentially input, or a single hot water outlet input. If the hot water output input is obtained, the control unit 30 proceeds to step S5, and otherwise maintains the standby state of step S1.

In step S5, the controller 30 determines whether the pre-stored temperature detection state of the second temperature sensor 17 is an abnormal state. In step S5, the controller 30 reads the stored temperature sensing state of the second temperature sensor 17, and if the pre-stored temperature sensing state is normal, proceeds to step S7; otherwise, step ( S5) Since the previous temperature sensing state is an abnormal state, the process proceeds to step S17.

In step S7, the control unit 30 obtains the detected temperature T1 from the second temperature sensor 17, and controls the heater driving unit 19 for a first reference time to operate the heater with a reference output. A sensed temperature T2 is obtained from the second temperature sensor 17 . That is, while performing the heating operation of the heater, the control unit 30 acquires the detected temperature T1 before the heating operation and the detected temperature T2 after the heating operation for the first reference time. Then, the controller 30 performs step S9.

In step S9, the control unit 30 calculates the temperature difference (T2-T1) between the sensed temperature T2 and the sensed temperature T1 as described above, and compares it with the first temperature difference, so that the second temperature sensor 17 ) determines whether the temperature sensing state is abnormal. If the temperature difference (T2-T1) is greater than the first temperature difference, the temperature sensing state is a normal state, so step S11 is performed. Otherwise, step S15 is performed.

In step S11, since the temperature detection state of the second temperature sensor 17 is normal, the controller 30 controls the heater driver 19 so that the heater performs an additional heating operation for a second reference time with basic output. do. Here, when setting the second reference time, it should be considered that the heating operation is performed for the sum of the first and second reference times without hot water being discharged. That is, if heating is performed without dispensing hot water during the sum of the first and second reference times, a boiling phenomenon may occur in the heater tank 8, so the temperature of the hot water is increased while preventing such a boiling phenomenon. It should be considered that it should be possible to do this, and the second reference time is set to 2 seconds, for example.

In step S13, the control unit 30 controls the water inlet valve 2 and the water outlet valve 9 to open the heater tank 8 heated by the heating operation for the first reference time and the second reference time. By dispensing hot water inside, the normal water dispensing operation is performed.

The controller 30 operates the heater with basic output for a heating time corresponding to the sum of the first reference time and the second reference time, and then discharges hot water, thereby dispensing hot water at a sufficiently high temperature. In addition, the control unit 30 continuously obtains the sensed temperature from the second temperature sensor 17 while performing a normal water extraction operation of dispensing water while heating the heater with a basic output so that the current detected temperature is equal to or greater than the target temperature. If not, the flow control valve (6) is controlled to be open to discharge more hot water, and if the current detected temperature is less than the target temperature, the flow control valve (6) is controlled or maintained to be closed so that the temperature of the hot water reaches the target temperature. to reach the temperature. In step S13, the control unit 30 terminates hot water dispensing when receiving the hot water dispensing end input, and the normal water dispensing operation and its completion are well known to those skilled in the art. The description is omitted because it corresponds to the technology.

In step S15, the control unit 30 sets the temperature sensing state of the second temperature sensing unit 17 to an abnormal state and stores it. At this time, the control unit 30 may store the number of times (set number) of being set to the abnormal state in the normal state (release state of the abnormal state). Then, the controller 30 performs step S17.

In step S17, the controller 30 controls the heater driving unit 19 to operate the heater with a protective output to protect the heater, and the controller 30 opens the water intake valve 2 and the water outlet valve 9. state, a protective water extraction operation of dispensing hot water in the heater tank 8 heated by the heating operation for the first reference time is performed. In addition, the control unit 30 opens the flow control valve 6 to protect the heater when performing the protective water extraction operation, so that a larger flow rate of purified water is supplied to the heater tank ( 8) to be supplied. That is, the control unit 30 performs a protective water extraction operation to protect the heater by performing at least one of adjusting the output of the heater and increasing the flow rate of purified water into the heater tank 8 . Through the protection of the heater, burnout of the heater is prevented, and electric leakage problems due to burnout of the heater, electric shock accidents due to electric leakage, and fire can also be prevented. Also, when the protected water extraction operation starts, the controller 30 may visually and/or audibly display an alarm indicating the start of the protected water extraction operation through the display unit 15 . The controller 30 performs step S19 while performing the protected water extraction operation.

In step S19, the control unit 30 determines whether the temperature sensing state of the second temperature sensor 19 is an abnormal state while performing the protected water extraction operation. Among the above-described temperature sensing abnormal conditions, there is a possibility that the temperature sensing unit fixing failure or temperature sensing failure may be resolved during the water extraction process, so the control unit 30 controls the temperature detection state of the second temperature detection unit 19 during the protective water extraction operation. It is desirable to continuously judge. For this determination, the control unit 30 controls the temperature between the detected temperature T3 at the start of hot water dispensing and the detected temperature T4 during the hot water dispensing operation (ie, the detected temperature at the time of performing step S19) as described above. The temperature difference (T4-T3) and the second temperature difference are compared. If the temperature difference (T4-T3) is greater than the second temperature difference, the temperature sensing state has changed from the abnormal state to the normal state, and thus the process proceeds to step S23, otherwise it proceeds to step S21.

In step S21, the control unit 30 determines the end of water extraction based on whether it has obtained an input including the end of hot water extraction or the end of water extraction from the input unit 13 while performing the protected water extraction operation. If water extraction is complete, the controller 30 terminates the protected water extraction operation, and otherwise proceeds to step S17. Alternatively, the control unit 30 may end the protected water extraction operation and proceed to step S1. Since the control unit 30 maintains the stored abnormal state when the protected water dispensing operation is finished, when the controller 30 performs hot water dispensing later, the stored abnormal state can be read and used in step S5. In addition, the control unit 30 may visually and/or audibly display an alarm indicating the end of the protected water extraction operation through the display unit 15 when the protected water extraction operation ends.

In step S23, the controller 30 releases the previously stored abnormal state and changes the temperature sensing state of the second temperature sensor 17 to a normal state. Since the second temperature sensor 17 is in a normal temperature sensing state, the controller 30 proceeds to step S13 to perform a normal water extraction operation.

When step S23 proceeds to step S13, as described above, the control unit 30 performs the normal water extraction operation according to the control operation (heater output adjustment, purified water flow rate adjustment) of the protected water extraction operation, that is, the heater output adjustment. An accompanying normal water extraction operation and a normal water extraction operation with regulation of purified water flow rate are optionally performed or together.

In the above-described steps S15 to S21, the control unit 30 performs a protective water extraction operation capable of protecting the heater even in an abnormal temperature detection state of the second temperature sensor 17 until the end of hot water extraction or in the second temperature sensing unit 17. It is performed until the abnormal temperature sensing state of the temperature sensor is converted to a normal state.

Regarding the number of settings stored in step S15 described above, the control unit 30 detects the temperature of the second temperature sensor 17 through the display unit 15 when the number of settings exceeds the reference number for setting the abnormal state. An abnormal state may be visually and/or audibly notified to the user. Alternatively, the controller 30 may store and use the number of canceling the abnormal state in step S23 instead of setting the number of abnormal states. For example, if the number of release times exceeds the reference number of times for canceling the abnormal state, the control unit 20 may visually and/or audibly inform the user of the abnormal temperature detection state of the second temperature sensor 17 through the display unit 15. It can also be reported hostilely. The control unit 30 determines that the setting and/or release of the abnormal state of the second temperature sensor 17 occurs frequently from at least one of the number of times the abnormal state is set and the number of times the abnormal state is released, and detects the second temperature. The user is notified that repair or replacement of part 17 is required. For example, a user or a repairer may replace parts of the second temperature sensor 17 in the case of a single defect of the second temperature sensor 17, or simply repair in the case of a fixation defect, by notification of an abnormal temperature sensing condition. It is possible to solve the temperature sensing abnormal state problem only.

In addition, the control unit 30 may inform the user through the display unit 15 that the protected water extraction operation is being performed in step S17.

As described above, the present invention is not limited to the specific preferred embodiments described above, and anyone having ordinary knowledge in the technical field to which the present invention pertains can do various things without departing from the gist of the present invention claimed in the claims. Of course, variations are possible, and such variations are within the scope of the claims.

1: first pressure reducing valve 2: water intake valve
3: flow sensor 4: second pressure reducing valve
5: first orifice 6: flow control valve
7: second orifice 8: heater tank
9: water outlet valve 11: first temperature sensor
13: input unit 15: display unit
17: second temperature sensor 19: heater driving unit
21: power supply

Claims (15)

a heater tank provided with a heater to heat purified water and supply hot water;
a purified water supply passage having a first path for constantly supplying the purified water to the heater tank;
a water outlet for dispensing hot water in the heater tank;
a temperature sensor for sensing the temperature of the hot water in the heater tank or the hot water discharged from the heater tank;
a water intake valve for supplying and shutting off the purified water to the purified water supply passage;
In the process of dispensing hot water, the inlet valve is controlled to supply the purified water to the heater tank, and after the heater is operated to heat with normal output, the temperature sensing state of the temperature sensing unit is determined based on the change in the temperature sensed by the temperature sensing unit. It consists of a control unit that determines
The control unit determines a temperature sensing state of the temperature sensing unit as a normal state or an abnormal state,
When the temperature sensing state of the temperature sensing unit is an abnormal state, the control unit sets and stores the temperature sensing state of the temperature sensing unit to an abnormal state and performs a protective water extraction operation to protect the heater. Device. According to claim 1,
The control unit determines a temperature sensing state of the temperature sensing unit based on a temperature difference between a temperature sensed before the heating operation of the heater and a temperature sensed after the heating operation of the heater. According to claim 2,
The control unit determines a temperature sensing state of the temperature sensing unit using a temperature detected after heating the heater for a first reference time. According to claim 2,
The controller compares the temperature difference with a preset first temperature difference, determines a normal state when the temperature difference is greater than the first temperature difference, and determines an abnormal state when the temperature difference is less than or equal to the first temperature difference Hot water supply control device, characterized in that. delete delete According to claim 1,
The hot water supply control device according to claim 1 , wherein the control unit performs a protective discharge operation of reducing the output of the heater to a protection output and controlling the water intake valve and the water outlet to discharge hot water from the heater tank. According to claim 1,
The purified water supply passage is provided with a flow control valve independent of the first route and controlled by the control unit to have a second route for blocking and supplying the purified water to the heater tank,
The control unit controls the flow control valve to open to increase the flow rate of purified water supplied to the heater tank through the first and second paths, and controls the inlet valve and the water outlet to supply hot water in the heater tank. A hot water supply control device characterized in that it performs a protective water extraction operation. According to any one of claims 1 or 7 or 8,
While performing the protective water extraction operation, the control unit compares a temperature difference between a temperature detected at the start of the hot water extraction operation and a temperature detected during the protective water extraction operation and a second temperature difference to determine a temperature sensing state of the temperature sensing unit Hot water supply control device, characterized in that. According to claim 9,
If the temperature difference between the temperature sensed at the start of the hot water extraction and the temperature sensed during the protective water extraction operation is greater than the second temperature difference, the controller releases and stores the stored abnormal state, and the temperature sensor temperature The hot water supply control device characterized in that the normal water extraction operation is performed according to the control operation of the protected water extraction operation by determining the detected state as a normal state. According to claim 10,
The hot water supply control apparatus of claim 1 , wherein the control unit performs a normal water extraction operation for returning the output of the heater to a normal output when the protected water extraction operation in which the output of the heater is reduced is performed. According to claim 10,
When the protected water extraction operation in which the flow rate of purified water is increased is performed, the control unit compares the temperature sensed by the temperature sensor with the target temperature of the hot water extraction operation so that the temperature detected by the temperature sensor is equal to or greater than the target temperature of the hot water extraction operation. If it is, the increased flow rate of purified water is maintained, and if not, the hot water supply control device performs a normal water extraction operation of reducing the increased flow rate of purified water by controlling the flow control valve. According to claim 1,
Hot water supply, characterized in that, when the temperature sensing state of the temperature sensor is in a normal state, the control unit performs a normal water dispensing operation of dispensing hot water in the heater tank by controlling the water intake valve and the water outlet after a second reference time controller. According to claim 1,
The hot water supply control device has a display unit,
The control unit stores the number of times set to the abnormal state, compares the stored number of sets with a reference number, and when the stored number of sets exceeds the reference number, the temperature sensing unit displays an abnormal temperature sensing abnormal state visually or audibly through the display unit. Hot water supply control device, characterized in that to inform the enemy. According to claim 10,
The hot water supply control device has a display unit,
The control unit stores the number of release times of the abnormal state, compares the stored number of release times with a reference number, and when the stored number of release times exceeds the reference number, visually or audibly indicates an abnormal temperature detection state of the temperature sensor through the display unit. Hot water supply control device, characterized in that for notifying.

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