KR20170034856A - Water dispensing apparatus - Google Patents

Abstract

The present invention relates to a water dispensing apparatus. According to one aspect of the present invention, the water dispensing apparatus comprises: a filter unit which purifies water supplied from the outside; a purified water path in which the purified water which has passed through the filter unit flows; a dispensing hole from which the purified water or warm water are dispensed; a second path which is connected between the purified water path and the dispensing hole; a first path which is branched from the purified water path; a heating path unit which is connected to the first path and is at least partially made of a magnetic material; a third path which supplies the water which has passed through the heating path unit to the second path; a coil unit which is disposed facing the heating path unit, is wound multiple times, and heats the heating path unit by induction; a flow rate sensor which is provided in the first path or the third path to sense the flow rate of the purified water introduced into the heating path unit, or the flow rate of the warm water dispensed from the heating path unit; a temperature sensor which senses the temperature of the purified water introduced into the heating path unit, or the temperature of the warm water discharged from the heating path unit; a valve which is provided in the first path or the third path to regulate the flow rate of the purified water supplied to the heating path unit, or the flow rate of the warm water discharged from the heating path unit; a temperature selection unit which selects a target temperature for the warm water to be dispensed from the dispensing hole; and a controller which controls the operation of the valve and an output value supplied to the coil unit in response to the target temperature selected by the temperature selection unit.

Description

Water dispensing apparatus

The present invention relates to a water discharge device.

Among household appliances, a water purifier is a device that filters incoming water and supplies it to a user.

A water purifier is introduced in the prior art Korean Utility Model Patent Publication No. 2011-000088 (public date January 27, 2011).

The water purifier includes a space portion, a storage container that can be placed in the space portion, and a heating source that can heat the water contained in the storage container.

However, according to the water purifier disclosed in the prior art, since the heating source can heat the water contained in the storage container, hot water can not be taken out through the connection pipe unless the user places the water in the storage container and places it in the space , The user has an uncomfortable problem.

An object of the present invention is to provide a water discharging device which can reduce the waiting time until hot water is taken out and allows the user to take hot water of a desired temperature.

The water discharge device according to one aspect of the present invention includes a filter portion for purifying water supplied from the outside, a purified water passage through which the purified water passes through the filter portion, an air outlet for taking out the purified water or hot water, A first flow path branched from the purified flow path, a heating flow path part connected to the first flow path, at least a part of which is made of a magnetic material, a third flow path for supplying water passing through the heating flow path part to the second flow path, A coil portion disposed facing the heating passage portion and wound around a plurality of times to induction-heat the heating passage portion, a flow rate of purified water flowing into the heating passage portion, or a flow rate of hot water discharged from the heating passage portion, A flow rate sensor provided in the first flow path or the third flow path, a temperature sensor for detecting the temperature of the purified water flowing into the heating flow path portion or the temperature of the hot water discharged from the heating flow path portion A temperature sensor, a valve provided on the first flow path or the third flow path to adjust a flow rate of purified water supplied to the heating flow path portion or a flow rate of hot water discharged from the heating flow path portion, And a controller for controlling an operation of the valve and an output value supplied to the coil part in correspondence with the target temperature selected by the temperature selection part.

In addition, the controller may receive the flow rate information sensed by the flow rate sensor and adjust the opening degree of the valve.

In addition, the controller may receive the flow rate information sensed by the flow rate sensor, and may control an output supplied to the coil part.

Further, the flow rate sensor may be disposed at a position adjacent to the heating flow path portion.

The temperature sensor may be provided in the first flow path or the second flow path.

Further, the temperature sensor may be disposed at a position adjacent to the heating flow path portion.

The control unit may further include a memory for storing information on a target flow amount corresponding to the target temperature selected by the temperature selection unit or an output value supplied to the coil unit.

In addition, the controller may adjust the degree of opening of the valve based on information stored in the memory.

The controller may adjust an output value supplied to the coil part based on information stored in the memory.

The heating passage portion may include a first guide having an inlet portion through which the water supplied into the first passage flows and a discharge portion connected with the third passage to discharge water, And a second guide provided to guide the second guide member.

According to the proposed invention, since the heating device can heat the water flowing through the heating flow path portion, standby power for storing hot water is not necessary.

In addition, since the heating flow path portion heats the water flowing through the heating flow path by induction heating, there is no loss of heat source and the water on the heating flow path can be heated quickly.

Further, since the user can set the target temperature of the hot water and acquire the hot water of the set target temperature, there is an advantage that it can meet the user's taste in various ways.

Further, in the case of this embodiment, when the preheating is required, preheating is performed, and after the preheating, the water is taken out so that the temperature of the extracted water can be equal to or close to the target temperature.

Further, in this embodiment, in the preheating process, as the preheating time is determined based on the target temperature and the present water temperature, the phenomenon that the temperature of the water to be taken out is remarkably higher or significantly lower than the target temperature can be prevented.

In this embodiment, when it is determined that the preheating is necessary, if the preheating is not required, for example, when the hot water takeout command is inputted immediately after the previous hot water outflow, water is taken out without performing the preheating, This has the advantage of reducing waiting time for hot water extraction.

Further, according to the flow rate control step of this embodiment, there is an advantage that the temperature of hot water to be taken out can be equal to or close to the target temperature.

According to the predictive control of this embodiment, there is an advantage that abrupt temperature fluctuation and output fluctuation are prevented, and thus the temperature of the hot water taken out is equal to or as close as possible to the target temperature.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view of a water discharge apparatus according to an embodiment of the present invention; FIG.
FIG. 2 illustrates an input unit according to an embodiment of the present invention. FIG.
3 is a block diagram of a water discharge apparatus according to an embodiment of the present invention.
4 is a flowchart illustrating a hot water taking-out process according to an embodiment of the present invention.
FIG. 5 is a view showing the output of the heating device, the temperature of the water, and the flow rate according to time after the hot water takeout command is inputted; FIG.

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. It should be noted that, in adding reference numerals to the constituent elements of the drawings, the same constituent elements are denoted by the same reference numerals even though they are shown in different drawings. In the following description of the embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the difference that the embodiments of the present invention are not conclusive.

In describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements. When a component is described as being "connected", "coupled", or "connected" to another component, the component may be directly connected or connected to the other component, Quot; may be "connected," "coupled," or "connected. &Quot;

The water discharge device referred to in the present specification includes a household appliance having a function of discharging water, such as a water purifier capable of discharging purified water or a refrigerator having a water discharge function.

In addition, the water purifier may be a direct water type water purifier for discharging water by water pressure of water supplied through a flow path, or may be a water tank type water purifier for discharging water by the water pressure of water stored in the water reservoir. There is no limitation.

FIG. 1 is a schematic view of a water discharge apparatus according to an embodiment of the present invention. FIG. 2 is a view illustrating an input unit according to an embodiment of the present invention. Fig.

1 shows a schematic view of a water purifier as an example.

1 to 3, the water discharging apparatus according to an embodiment of the present invention may include a housing 10 forming an external shape. The housing 10 may include a plurality of panels, and the housing 10 may be completed by combining the plurality of panels. For example, the housing 10 may include a front panel, two side panels, a top panel, a back panel and a bottom panel, but the number of the plurality of panels is not limited in the present embodiment.

The water discharge device may further include an input unit 15 for inputting an operation command. The input unit 15 may be disposed on the front panel of the housing 10, for example. When the water discharging device is a refrigerator, the input unit 15 may be disposed on a refrigerator door, for example.

The input unit 15 includes an integer selection unit 151 for selecting an integer to be extracted from the extraction port 35, a hot water selection unit 152 for selecting the hot water to be extracted from the extraction port 35, And temperature selection units 153 and 154 for selecting (or setting) the target temperature.

In FIG. 2, the temperature selectors 153 and 154 are shown as two buttons, for example. However, the number and selection of buttons for temperature selection are not limited in this embodiment.

Further, in the present embodiment, the user can select one of two or more target temperatures using the temperature selection units 153 and 154. [ Of course, the temperature selection units 153 and 154 may be omitted in this embodiment, and in this case, hot water can be taken out at a preset target temperature.

The water discharge device may further include an operation lever 16 for operating to take out purified water or hot water.

The water discharging device may further include a filter unit 20 for purifying water supplied from the outside and a purified water flow path 31 through which the water passing through the filter unit 20 flows. The filter unit 20 may include one or more filters.

If the filter unit 20 is omitted from the water discharge device, the purified water flow path 31 may be connected to a water tank containing pre-purified water.

That is, the raw water introduced from the outside is purified through the filter unit 20, and then flows into the purified water passage 31.

The purified water flow path 31 may be branched into a first flow path 32 and a second flow path 33.

First, the second flow path 33 connects between the purified water flow path 31 and the extraction water 35. Therefore, the purified water passing through the filter unit 20 can escape to the outlet 35 through the purified water passage 31 and the second flow path 33. The user can also take out the purified water from the outside of the water discharging device through the extracted water (35).

On the other hand, the purified flow path 31 and the heating path portion 60 described later are connected to the first flow path 32. Accordingly, the purified water passing through the filter unit 20 can be supplied to the heating channel unit 60 through the purified water channel 31 and the first channel 32.

That is, the water to be extracted as purified water flows to the second flow path 33, and water to be taken out as hot water flows to the first flow path 32 for heating and then supplied to the heating flow path portion 60.

The water discharge device may include an instantaneous hot water device (50). The instantaneous hot water supply device 50 includes a heating channel portion 60 forming a heating channel 66 for heating the water supplied from the first channel 32, And a heating device 70 for heating.

Further, the water discharge device may further include a controller 80 capable of controlling the heating device 70.

The heating passage portion 60 and the heating device 70 may be received in the housing 10.

When the water discharging device is a refrigerator, the heating device and the heating flow path may be disposed in the refrigerator door, though not limited thereto.

The heating device 70 may include a frame 710 and a coil part 730 seated on the frame 710. Although not shown in the figure, the frame 710 may include a ferrite.

The coil part 730 may be formed by winding a coil several times, and may be stacked in a plurality of layers. Further, the coil part 730 wound and / or laminated in multiple layers can be arranged to face the heating passage part 60. [

 If the coils constituting the coil part 730 are arranged in a single layer, the area occupied by the coil part 730 is increased. However, according to the present embodiment, as the coils are stacked in multiple layers, Can be reduced and the heating device 70 can be compact.

The coil part 730 may be formed in a circular shape or an elliptic ring shape as a whole. Of course, it is also possible that the coil part 730 is formed in a polygonal ring shape.

An electric wire connected to the coil part 730 may be connected to the controller 80.

The controller 80 may include an inverter 81. The inverter 81 controls the amount of induction heating by controlling the current applied to the coil part 730. That is, the output of the heating device 70 can be adjusted by the inverter 81. [

When the induction heating amount is controlled as described above, the user can heat the water to a desired temperature, and the hot water of the target temperature set by the user can be taken out from the air outlet 35.

The heating passage portion 60 includes a first guide 61 having an inlet portion 63 through which water is introduced and a discharge portion 64 through which heated water is discharged, And a second guide 62 forming the heating passage 66 together with the first guide 61.

The second guide 62 may be a magnetic body so that induction heating can be performed. The first guide 62 may be a non-magnetic body that does not undergo induction heating. Of course, both the first guide 61 and the second guide 62 may be magnetic.

When a current is applied to the coil portion 730, a magnetic field is generated in the coil portion 730, and a current is generated in the second guide 62 due to the magnetic field to heat the second guide 62.

Therefore, according to the present embodiment, the water in the heating flow path 66 formed by the second guide 62 can be heated by the second guide 62. [ At this time, the entire second guide 62 can be heated, and there is no loss of heat source, so that the water on the heating flow path 66 can be heated quickly.

Further, since the surface of the second guide 62 is heated, there is no temperature rise in the periphery of the heating channel portion 60, so that there is an advantage that heat insulation of the heating channel portion 60 is unnecessary.

In addition, since the water flowing through the heating channel 66 can be instantaneously heated, standby power for storing hot water is not required.

The discharge port 64 may be connected to the outlet port 35 by a third flow path 34.

For example, the discharge portion 64 may be connected to the second flow path 33 by a third flow path 34.

Therefore, the heated hot water passes through the heating flow path 66 and is discharged to the extracted water 35 via the discharge part 64, the third flow path 34 and the second flow path 33, 64, and the third flow path 34, and then can be taken out to the take-out water 35 immediately.

The first flow path 32 may be provided with a first valve 41 for opening and closing the flow of water supplied to the heating flow path unit 60 or adjusting the amount of water to be supplied.

A second valve 42 may be provided between the second flow path 33 and the third flow path 34 and between the second flow path 33 and the first flow path 32, have. Therefore, the second valve 42 can open or close the flow of the purified water passing through the second flow path 33 or adjust the amount of the purified water passing through the second flow path 33.

As another example, the first valve 41 may be provided in the third flow path 34 to open or close the flow of the water discharged from the heating flow path portion 60, or to adjust the amount of the discharged water.

As another example, when the first valve 41 is provided in the third flow path 34 and the second valve 42 is connected to the third flow path 34 in the second flow path 33 Or between the point and the air outlet 35.

The first valve 41 can continuously or stepwise regulate the flow rate (or flow rate) of water or heated water to be heated.

In the present embodiment, the first valve 41 may be referred to as a hot water valve, and the second valve 42 may be referred to as a purified water valve.

The water discharge device may further include a flow rate sensor 83 for sensing a flow rate of the water flowing into the heating flow passage 60. The flow sensor 83 may be provided in the first flow path 32.

As another example, the flow sensor 83 may sense the flow rate of water (outflow flow rate) discharged from the heating passage portion 60 or the flow rate of water (outflow flow rate) extracted from the air outlet 35. In this case, the flow sensor 83 is not limited but may be provided in the third flow path 34.

As another example, the flow rate sensor 83 may be installed in the first flow path 32 to measure the amount of water supplied to the heating flow path portion 60, or may be installed in the inlet portion 63, 60 or the third flow path 34 to measure the amount of water flowing out of the second flow path 60.

In this embodiment, it is assumed that the input flow rate and the outflow flow rate are the same.

In addition, the flow rate of intake or outflow can be adjusted by adjusting the first valve (41) and / or the second valve (42).

The water discharging device includes an inlet temperature sensor 91 for detecting a temperature of water to be introduced into the heating passage portion 60 and an outlet temperature sensor for detecting the temperature of the water (hot water) And may further include a sensor 92. In this specification, the temperature sensed by the intake temperature sensor 91 may be referred to as an intake temperature, and the temperature sensed by the outflow temperature sensor 92 may be referred to as an outflow temperature.

The intake temperature sensor 91 may be disposed in the first flow path 32 or the inflow part 63.

The outflow temperature sensor 92 may be disposed in the third flow path 34 or the discharge portion 64.

The temperature sensors 91 and 92 are disposed adjacent to the heating passage portion 60 to accurately measure the temperature of the purified water flowing into the heating passage portion 60 and the temperature of the hot water discharged from the heating passage portion 60 in real time Can be detected.

The water discharging device may further include an overheat sensing sensor 740 for sensing the temperature of the heating channel portion 60. The overheat sensor 740 may be in contact with the heating passage 60 or may be spaced apart from the heating passage 60.

The overheat sensor 740 may be positioned within an area formed by the coil part 730, although not limited thereto.

In order to prevent the heating passage portion 60 from being heated in a state where no water is present in the heating passage portion 60, the controller 80 controls the temperature of the heating passage portion 60 to be increased, The operation of the heating device 70 can be stopped when the reference temperature is exceeded. That is, the controller 80 may cut off the current applied to the coil part 730.

At this time, the overheat detection sensor 740 can indirectly detect the temperature of the water in the heating flow path 66 by sensing the surface temperature of the heating flow path portion 60 substantially. Accordingly, the overheat sensor 740 may be referred to as a surface temperature sensor.

The water discharge device may further include a memory 95 in which information for controlling the heating device 70 can be stored.

In this embodiment, the controller 80 can control the operation of the valve 41 and the output value supplied to the coil part 730 corresponding to the target temperature selected by the temperature selectors 153 and 154.

For example, when the target temperature selected by the temperature selectors 153 and 154 is high, the controller 80 can control the valve 41 to reduce the amount of water flowing through the heating channel portion 60. Further, when the target temperature selected by the temperature selectors 153 and 154 is high, the output supplied to the coil part 730 can be raised by adjusting the interverter 81.

On the other hand, when the target temperature selected by the temperature selecting units 153 and 154 is low, the controller 80 can adjust the valve 41 to increase the amount of water flowing through the heating flow path unit 60. In addition, when the target temperature selected by the temperature selecting units 153 and 154 is low, the output supplied to the coil part 730 can be lowered by adjusting the interverter 81.

The controller 80 receives the flow rate information sensed by the flow rate sensor 83 to adjust the on / off state of the valve 41 or the opening degree of the valve 41.

In the present embodiment, the controller 80 is connected to the memory 95 in which the information of the target flow amount corresponding to the target temperature selected by the temperature selecting units 153 and 154 and / or the output value supplied to the coil part 730 is stored .

In detail, when the target temperature is inputted from the user through the input unit 15, the controller 80 adjusts the valve 41 to adjust the flow rate passing through the heating channel unit 60 to the target flow rate.

At this time, the controller 80 may receive the information of the actual flow rate sensed by the flow rate sensor 83, compare it with the target flow rate, and then adjust the valve 41 such that the actual flow rate is equal to the target flow rate.

That is, when the target temperature is inputted from the user through the input unit 15, the controller 80 grasps the target flow amount corresponding to the target temperature based on the information stored in the memory 95, The opening degree of the valve 41 can be adjusted so that the flow rate passing through the valve 60 becomes equal to the target flow rate.

Alternatively, the controller 80 may receive the flow rate information sensed by the flow rate sensor 83 and control an output supplied to the coil portion 730.

Specifically, when the flow rate detected by the flow sensor 83 is large, the controller 80 raises the output of the coil portion 730. When the flow rate sensed by the flow rate sensor 83 is small, 730 may be lowered.

As another example, the controller 80 may adjust the output value supplied to the coil part 730 based on the information stored in the memory 95.

That is, when the target temperature is input from the user through the input unit 15, the controller 80 grasps a preset output value corresponding to the target temperature based on the information stored in the memory 95, 730 may be equal to the pre-stored output value.

According to the present invention, when the target temperature of the hot water extracted from the user is inputted through the input unit 15, the hot water of the target temperature can be momentarily generated and supplied to the user.

Specifically, when the target temperature of the hot water is inputted from the user through the input unit 15, the controller 80 controls the valve 41 in real time based on the information stored in the memory 95, And the hot water of the target temperature desired by the user can be instantaneously generated by adjusting the output supplied to the coil part 730 through the inverter 81 to a preset output value.

Further, since the flow rate passing through the heating passage portion 60 is sensed in real time and feedback is provided to the controller 80, the controller 80 can adjust the actual flow rate to the target flow rate, Lt; / RTI >

At this time, the higher the target temperature of the hot water desired by the user, the smaller the target flow rate through the heating passage portion 60, and the larger the output value supplied to the coil portion 730 becomes.

On the other hand, the lower the target temperature of the hot water desired by the user is, the larger the target flow rate can be and the smaller the output value supplied to the coil portion 730 becomes.

Hereinafter, the process of extracting the purified water and hot water from the water discharge device will be described.

First, the process of taking out the purified water will be described.

The first valve 41 is turned off and the second valve 42 is turned on when the operation lever 16 is operated by the user. on. The purified water purified by the filter unit 20 flows through the purified water flow path 31 and the second flow path 33, and then is discharged to the outside through the water outlet 35.

Next, an example of the hot water taking-out process using the water discharging device of the present invention will be described.

FIG. 4 is a flowchart illustrating a hot water taking-out process according to an embodiment of the present invention. FIG. 5 is a view showing an output of a heating device, a temperature of a water, and a flow rate according to time after a hot water takeout command is inputted.

1 to 5, a user can input a hot water take-out command to take out hot water (S1). The hot water takeout command can be input by selecting the hot water selector 152 and operating the operation lever 16 as an example, but it is to be noted that the method of inputting the hot water takeout command in this embodiment is not limited.

At this time, the target temperature of the hot water to be extracted through the input unit 15 may be inputted or selected before the hot water takeout command is input.

Hereinafter, the case where water is present in the heating passage 66 will be described.

When the hot water extraction command is input, the controller 80 determines whether the sensed water temperature is lower than the first reference temperature (step S2). In this embodiment, step S2 may be referred to as a step of determining whether the preheating process is necessary.

In this embodiment, the first reference temperature is a temperature lower than the target temperature.

In the present embodiment, when the elapsed time since the previous hot water outflow is equal to or less than the reference time, the temperature sensed by the outflow temperature sensor 92 is selected as the sensed water temperature. If the elapsed time exceeds the reference time, As the water temperature, the temperature sensed by the overheat sensor 740 may be selected.

This is because when the elapsed time after the previous hot water outflow is equal to or lower than the reference time, the actual water temperature of the heating flow path 66 is similar to the temperature sensed by the outflow temperature sensor 92, The actual temperature of the water in the heating flow path 66 is similar to the temperature sensed by the overheat sensing sensor 740.

The accuracy of the determined preheating time can be increased when selecting a temperature that is as close as possible to the actual temperature of water in the heating flow path 66. [

Of course, the controller 80 can also compare the temperature sensed by the outflow temperature sensor 92 or the overheat sensor 740 with the first reference temperature regardless of the elapsed time since the previous hot water outflow.

If it is determined in step S2 that the sensed water temperature is lower than the first reference temperature, that is, if it is determined that the preheating process is required, the controller 80 performs a preheating process before water is taken out (S3).

In the present specification, the first reference temperature is lower than the target temperature set by the user, and may vary according to the target temperature. However, the first reference temperature for each target temperature is stored in the memory 95 in advance.

In the present embodiment, the first valve 41 remains closed while the preheating process is being performed. Therefore, even if the hot water take-out command is inputted, no water is taken out from the blow-out port 35 while the preheating is being performed.

The controller (80) determines a preheating time until the sensed water temperature reaches a set target temperature. At this time, the controller 80 can determine the preheating time until the detected water temperature reaches the set target temperature when the heating device 70 operates at a predetermined output. The predetermined output may be the maximum output, although it is not limited.

As described above, since the preheating time is determined as the time until the sensed water temperature reaches the set target temperature, the accuracy of the preheating time can be increased as the sensed water temperature is similar to the actual water temperature .

Then, the controller 80 operates the heating device 70 to a predetermined output for a determined preheating time. In the present embodiment, the controller 80 may further include a timer for checking the elapsed time although not shown.

Referring to FIG. 5, for example, in the preheating process, the outflow rate is 0, and the output of the heating device 70 can be kept constant during the preheating time as the maximum output.

Accordingly, in the preheating process, the water in the heating channel portion 60 is heated in a state in which the water does not flow to raise the temperature of the water. When the preheating is completed, the water in the heating channel 66 rises to the target temperature .

When the preheating is completed, the controller 80 turns on the first valve 41 (hot water valve) and increases the flow rate until the outflow flow rate reaches the target flow rate at the initial flow rate (S4). In this embodiment, step S4 may be referred to as a flow control step.

That is, when the first valve 41 is turned on after completion of the preheating, the outflow rate at the time of turning on the first valve 41 is an initial flow rate lower than the target flow rate.

Then, the controller (80) can increase the outgoing flow rate with a constant flow rate gradient until the outflow flow rate reaches the target flow rate.

For example, the controller 80 may step-up the opening of the first valve 41 to increase the outflow rate. When the outflow flow rate reaches the target flow rate, the controller 80 can maintain the state (opening degree) of the first valve 41 at the current state (current opening degree) so that the outflow flow rate maintains the target flow rate .

In the present embodiment, the initial flow rate can be changed according to the target temperature set by the user, and the initial flow rate corresponding to the target temperature is stored in advance in the memory 95. [

In addition, the target flow rate can be changed according to the target temperature set by the user, and the target flow rate corresponding to the target temperature is stored in the memory 95 in advance.

The flow rate gradient has a constant value regardless of the target temperature.

Therefore, when the first target temperature is set, the first initial flow rate and the first target flow rate are determined, and when the second target temperature is set, the second initial flow rate and the second target flow rate are determined.

At this time, the time to reach the first target flow rate at the first initial flow rate may be the same as the time to reach the second target flow rate at the second initial flow rate.

The initial flow rate and the target flow rate may be set to be smaller than when the target temperature is low when the target temperature is high.

In addition, in the flow rate control step, the controller 80 determines the output of the heating device 70 based on the input temperature sensed by the intake temperature sensor 91 and the set target temperature, Thereby controlling the apparatus 70 to operate.

In this embodiment, the output of the heating device 70 may vary depending on the input temperature and the target temperature, but once the input temperature and the target temperature are determined, the output of the heating device 70 during the flow control step is It can be constant. The determined output may generally be less than the maximum output.

Referring to FIG. 5, in the flow rate control step, the outflow flow rate rises from the initial flow rate to the target flow rate. Since the first valve (41) is turned on at the start of the flow control step, hot water can be taken out from the outlet (35).

In the flow rate control step, the outflow temperature rises to a temperature higher than the target temperature (heating maximum temperature). In the flow rate control step, the determined output of the heating device 70 can be kept constant.

The controller 80 determines whether or not the current flow rate reaches the target flow rate, and if the current flow rate reaches the target flow rate, terminates the flow rate control step and performs the predictive control (S6).

In the predictive control step, the controller 80 determines the output of the heating device 70 on the basis of the input temperature sensed by the intake temperature sensor 91 and the set target temperature, and supplies the determined output to the heating device 70 to operate. The determined output may generally be less than the maximum output.

In the predictive control step, the output of the heating device 70 may vary depending on the input temperature and the target temperature, as in the flow control step. However, if the input temperature and the target temperature are once determined, (70) may be constant.

In the predictive control step, the outflow flow rate may be constant at the target flow rate.

Referring to FIG. 5, in the predictive control step, the outflow temperature is lowered.

The controller 80 determines whether the outflow temperature has reached the second reference temperature or lower (S7). Then, when the outflow temperature is equal to or lower than the second reference temperature, the controller 80 ends the predictive control step and performs feedback control (S8). At this time, the second reference temperature is higher than the target temperature.

In the feedback control step, the controller 80 can control the output of the heating device 70 so that the detected outgoing water temperature can maintain the target temperature.

According to the feedback control, the outflow temperature can converge to the target temperature. At this time, "convergence" means that the outgoing water temperature is kept at the same temperature as the target temperature, but also within a range equal to the predetermined temperature difference from the target temperature.

Therefore, the controller 80 keeps the output of the heating device 70 constant until the outflow temperature reaches the second reference temperature, and when the outflow temperature reaches the second reference temperature, the heating device 70 Can be varied.

In the feedback control step, proportional integral control or hysteresis control for controlling the output based on the outflow temperature may be performed. Since the proportional integral control or the hysteresis control can be implemented by a known technique, a detailed description will be omitted.

While the feedback control is being performed, the controller 80 can determine whether hot water extraction is completed (S9).

In the present embodiment, when hot water takeout is completed, the hot water takeout end command may be input, or the accumulated amount of the taken-out water may reach the reference amount. The hot water extraction end command may be a case in which the operation lever 16 is pushed while the hot water is being taken out and the method of inputting the hot water extraction end command in this embodiment is not limited.

If it is determined in step S9 that the hot water extraction is completed, the controller 80 closes the first valve 41 (hot water valve) (S13) and ends the hot water extraction.

On the other hand, if it is determined in step S2 that the sensed water temperature exceeds the first reference temperature, that is, if it is determined that the preheating process is unnecessary, the controller 80 does not perform the preheating process, 41 (hot water valve) is opened (S10). The heating device 70 is operated. At this time, the outflow flow rate when the first valve (41) is opened may be the target flow rate.

Then, the controller 80 can perform feedback control based on the outflow temperature (S11). The controller 80 can determine whether the hot water extraction is completed during the feedback control (S12). If the hot water extraction is completed, the controller 80 closes the first valve 41 (hot water valve) ), The hot water extraction is terminated.

According to the proposed invention, the following effects can be expected.

First, in the case of this embodiment, it is determined whether or not a preheating process is required, and a preheating process is performed when a preheating process is required.

If it is determined that the preheating process is not required and the water is taken out immediately after the hot water take-out command is input, if the temperature of the water initially taken out is low (for example, The temperature of the water taken out at the time of completion of taking out of the water is lower than the target temperature set by the user, which can cause the user's dissatisfaction.

However, in the case of this embodiment, when the preheating process is required, the preheating process is performed and the water is taken out after the preheating process, whereby the temperature of the taken-out water can be equal to or close to the target temperature .

Further, in this embodiment, in the preheating process, as the preheating time is determined based on the target temperature and the present water temperature, the phenomenon that the temperature of the water to be taken out is remarkably higher or significantly lower than the target temperature can be prevented.

That is, if the preheating time is constant regardless of the target temperature and the current water temperature, the temperature of the water after completion of the preheating may be significantly higher or lower than the target temperature depending on the target temperature or the current water temperature. However, according to this embodiment, as the preheating time is determined based on the target temperature and the current water temperature, the temperature of the water to be taken out may be the same or similar to the target temperature.

In the present embodiment, when it is determined that the preheating process is necessary, if the preheating is not required, for example, when the hot water take-out command is inputted immediately after the previous hot water outflow, The waiting time for hot water extraction is advantageously reduced.

In summary, according to the present embodiment, when the hot water is taken out for the first time, there is an advantage that the temperature of the hot water taken out by the preheating process can be equal to or close to the target temperature, Has the advantage of minimizing the hot water intake time.

Further, according to the flow rate control step of this embodiment, when the hot water take-out is completed, the temperature of the hot water taken out can be equal to or close to the target temperature.

The water in the heating passage 66 is heated to the target temperature but the water in the second passage 33 and the third passage 33 located between the outlet 35 and the heating passage 60, 34) is lower than the target temperature. After the preheating process, the temperature of the water can be lowered by the air around the flow path in the course of the flow of the water from the heating flow path 66 to the air outflow port 35. [

Therefore, when the flow rate control is not performed, not only the water lower than the target temperature is taken out from the air outlet 35 (the temperature lowering factor), and the temperature of the hot water is lowered (the temperature lowering factor) , There is a problem that the temperature of the hot water taken out upon completion of hot water extraction is lower than the target temperature.

However, according to this embodiment, as the initial flow rate is lower than the target flow rate and the outflow flow rate is increased until reaching the target flow rate by the flow rate control, the outflow temperature is higher than the target temperature It can be heated to a high temperature (maximum heating temperature).

Therefore, even if water lower than the target temperature is taken out and the temperature of the hot water is lowered in the take-out process of hot water, the value corresponding to the temperature difference between the target temperature and the maximum heating temperature is lowered The temperature of the hot water taken out at the time of finally completing the hot water take-out can be equal to or close to the target temperature.

According to the predictive control of this embodiment, there is an advantage that sudden fluctuation of the intake temperature and the output of the heating device is prevented, and thus the temperature of the hot water taken out is equal to or as close as possible to the target temperature.

If the feedback control is performed without performing the predictive control after the flow control is finished, the fluctuation width of the outflow temperature and the fluctuation width of the output of the heating apparatus become larger as shown by the one-dotted line in Fig.

That is, in the feedback control step, the output of the heating device is controlled so that the outflow temperature reaches the target temperature. At the end of the flow control step, since the outflow temperature is higher than the target temperature, the controller determines that the outflow temperature is high, If the outflow temperature drops to a temperature lower than the target temperature, the process of raising the output of the heating device again may be performed a plurality of times. Accordingly, there arises a problem that the outflow temperature is lowered until the outflow temperature converges to the target temperature.

However, according to the present embodiment, in the case of performing the predictive control after the completion of the flow rate control, since the output of the heating device is maintained until the outgoing water temperature reaches the second reference temperature, Can be minimized.

On the other hand, in the present embodiment, when the user presses the operation lever 16 again (which may be a hot water extraction cancel command) during the preheating process, the controller 80 performs preheating for the determined preheating time, can do. This is to allow the hot water to be quickly taken out when the user again presses the operation lever 16 (i.e., when the hot water take-out command is inputted again).

When the preheating is completed after the operation lever 16 is pressed again, the elapsed time from the end of the preheating until the operating lever 16 is pressed again (the elapsed time until the hot water take-out command is input again The controller 80 compares the water temperature sensed by the overheat sensing sensor 740 with the first reference temperature to determine whether preheating is necessary or not.

When the preheating is completed after the operation lever 16 is pressed again, the elapsed time from the end of the preheating until the operating lever 16 is pressed again (the elapsed time until the hot water take-out command is input again ) Is within the reference time, the controller 80 does not perform the preheating. In this case, the controller 80 may perform the process after step S4.

In this specification, in terms of the heating of water by the heating device, the flow control step and the predictive control step can be termed the first heating step since the output of the heating device is once determined, Since the output of the heating device varies depending on the temperature, it can be called a secondary heating step.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. That is, within the scope of the present invention, all of the components may be selectively coupled to one or more of them. Furthermore, the terms "comprises", "comprising", or "having" described above mean that a component can be implanted unless otherwise specifically stated, But should be construed as including other elements. All terms, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, unless otherwise defined. Commonly used terms, such as predefined terms, should be interpreted to be consistent with the contextual meanings of the related art, and are not to be construed as ideal or overly formal, unless expressly defined to the contrary.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

15: Input unit 16: Operation lever
20: filter part 31: purified water flow path
32: first flow path 33: second flow path
34: third flow path 41: first valve
42: second valve 50: instantaneous hot water device
60: heating channel part 70: heating device
80: controller 83: flow sensor
91: incoming water temperature sensor 92: outgoing water temperature sensor

Claims (10)

A filter unit for purifying water supplied from the outside;
A purified water passage through which the purified water passing through the filter section flows;
An outlet through which the purified water or hot water is taken out;
A second flow path connected between the purified water passage and the air outlet;
A first flow path branched from the purified flow path;
A heating flow path portion connected to the first flow path and at least a part of which is made of a magnetic material;
A third flow path for supplying water passing through the heating flow path portion to the second flow path;
A coil portion arranged to face the heating passage portion and wound around a plurality of times to induction-heat the heating passage portion;
A flow sensor provided in the first flow path or the third flow path to detect a flow rate of purified water flowing into the heating flow path portion or a flow rate of hot water discharged from the heating flow path portion;
A temperature sensor for sensing the temperature of the purified water flowing into the heating channel portion or the temperature of the hot water discharged from the heating channel portion;
A valve provided on the first flow path or the third flow path to adjust a flow rate of purified water supplied to the heating flow path portion or a flow rate of hot water discharged from the heating flow path portion;
A temperature selector for selecting a target temperature of hot water to be extracted from the air outlet;
And a controller for controlling an operation of the valve and an output value supplied to the coil part in correspondence with the target temperature selected by the temperature selection part.
The method according to claim 1,
Wherein the controller receives the flow rate information sensed by the flow rate sensor and adjusts the degree of opening of the valve.
The method according to claim 1,
Wherein the controller receives the flow rate information sensed by the flow rate sensor and controls an output supplied to the coil portion.
The method according to claim 1,
Wherein the flow rate sensor is disposed at a position adjacent to the heating flow path portion.
The method of claim 1,
Wherein the temperature sensor is provided in the first flow path or the second flow path.
6. The method of claim 5,
Wherein the temperature sensor is disposed at a position adjacent to the heating flow path portion.
The method according to claim 1,
And a memory for storing information of a target flow amount corresponding to the target temperature selected by the temperature selection unit or an output value supplied to the coil part.
8. The method of claim 7,
Wherein the controller adjusts the degree of opening of the valve based on information stored in the memory.
8. The method of claim 7,
Wherein the controller adjusts an output value supplied to the coil part based on information stored in the memory.
The method according to claim 1,
The heating flow path portion includes:
A first guide formed with an inlet through which the water supplied to the first flow path flows, and a discharge port connected with the third flow path and through which water is discharged;
And a second guide configured to form the first guide and the heating passage.

Images