KR20190139177A - Water purifier including a heating passage heated by an induction heating apparatus - Google Patents

Abstract

According to an embodiment, the present invention relates to a water purifier which comprises: a working coil having a conducting wire wound in a ring shape; and a hot water tank placed to face the working coil at a position separated from the working coil in order to be induced and heated by the working coil. The hot water tank comprises: a first cover placed to face the working coil and having a flat magnetic plate shape; and a second cover coupled to the border of the first cover in order to provide a flowing and heating space for water together with the first cover, and made of a magnetic material. The second cover comprises: a base surface placed to face the first cover at a position separated from the first cover in order to form the flowing and heating space for water; a protruding surface protruding towards the first cover from the base surface; a circumference unit formed in the circumference of the protruding surface in order to mutually connect the base surface and the protruding surface; an inlet pipe coupled to one side of the second cover; and an outlet pipe coupled to the other side of the second cover. Therefore, the water purifier can regulate the temperature of released hot water.

Description

Water purifier including a heating passage heated by an induction heating apparatus

The present specification relates to a water purifier having a heating passage heated by an induction heating apparatus.

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

In the prior document, Korean Utility Model Publication No. 2011-000088 (published January 27, 2011) discloses a water purifier.

The water purifier includes a space part, a storage container which may be located in the space part, and a heating source capable of heating water contained in the storage container.

However, according to the water purifier disclosed in the prior document, since the heating source can heat the water contained in the storage container, hot water cannot be taken out through the connecting pipe unless the user puts the water in the storage container and locates it in the space. , The user has an uncomfortable problem.

An object of the present invention is to provide a water purifier having a heating flow path heated by an induction heating device which can adjust the temperature of hot water taken out and the compaction of the hot water device for producing hot water becomes compact.

It is an object of the present invention to provide a water purifier having a heating passage heated by an induction heating apparatus in which steam generation due to local overheating of water in the heating passage is prevented.

According to one aspect, a water purifying device includes a working coil having a conductive wire wound in an annular shape; And a hot water tank disposed to face the working coil at a position spaced apart from the working coil to be induction heated by the working coil, wherein the hot water tank is disposed to face the working coil and is formed of a magnetic plate-like material. 1 cover; And a second cover coupled to an edge of the first cover to provide water flow and heating space together with the first cover, and a magnetic cover, wherein the second cover is configured to form the flow and heating space of the water. A base surface disposed to face the first cover at a position spaced from the first cover; A protruding surface protruding from the base surface toward the first cover; A periphery formed around the protruding surface to connect the base surface and the protruding surface to each other; An inlet pipe coupled to one side of the second cover; And an outlet pipe coupled to the other side of the second cover.

The protruding surface may be disposed between the inlet pipe and the outlet pipe.

The protruding surface may be located on a straight line connecting the water inlet pipe and the water outlet pipe.

A plurality of protruding surfaces may be spaced apart from each other in the direction parallel to the flow direction of water between the water inlet pipe and the water outlet pipe.

A plurality of protruding surfaces may be spaced apart from each other in the direction crossing the flow direction of water between the water inlet pipe and the water outlet pipe.

The plurality of protruding surfaces may be spaced apart from each other in the direction parallel to the flow direction of water between the water inlet pipe and the water outlet pipe, and may also be spaced apart from each other in a direction crossing the water flow direction between the water inlet pipe and the water outlet pipe.

The protruding surface may be spaced apart from the first cover.

The working coil may further include a frame having a spacer such that the working coil may be spaced apart from the first cover at a predetermined interval.

According to the proposed embodiments, since the coil is stacked in multiple layers to form a coil part, the heating device is compact.

In addition, since the heating device heats the water flowing through the heating flow path, there is an advantage that standby power for storing hot water is unnecessary.

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

In addition, since the surface of the magnetic body of the heating flow path portion generates heat, there is no temperature rise around the heating flow path portion, there is an advantage that unnecessary heat insulation of the heating flow path portion.

In addition, since the flow passage guide is provided in the heating passage, water may flow in the entire cross section of the heating passage, and thus, the water may be quickly heated.

In addition, since the user can set the temperature of the hot water, and obtain the hot water of the set temperature, there is an advantage that can satisfy the user's preferences.

In addition, since the controller adjusts the currents of the heating device and the driving source so that the total current value of the home appliance does not exceed the limiting current value, abnormal operation of the home appliance and power cutoff may be prevented.

1 is a view schematically showing a water purifier according to a first embodiment.
2 is a perspective view of an instant hot water supply apparatus and a controller according to the first embodiment;
3 is a rear view of the instantaneous hot water device of FIG.
4 is an exploded perspective view of the instantaneous hot water device of FIG.
5 is a view showing a flow path guide according to a first embodiment;
6 is a block diagram of a water purifier according to the first embodiment.
7 is a view showing a change in current of the water purifier with time according to the first embodiment.
8 is a block diagram of a water purifier according to a second embodiment.
9 is a view showing an instant hot water device according to a third embodiment.
10 is a front view of the heating passage part according to the third embodiment;
11 is a cross-sectional view taken along the line AA of FIG. 10.
12 is a front view of a heating passage part according to the fourth embodiment;
13 is a front view of a heating passage part according to the fifth embodiment;
14 is a front view of the heating passage part according to the sixth embodiment;

In addition, 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 only for distinguishing the components from other components, and the nature, order or order of the components are not limited by the terms. If a component is described as being "connected", "coupled" or "connected" to another component, that component may be directly connected or connected to that other component, but between components It will be understood that may be "connected", "coupled" or "connected".

1 is a view schematically showing a water purifier according to a first embodiment, FIG. 2 is a perspective view of an instantaneous hot water device and a controller according to the first embodiment, FIG. 3 is a rear view of the instantaneous hot water device of FIG. 4 is an exploded perspective view of the instantaneous hot water apparatus of FIG. 2, and FIG. 5 is a view illustrating a flow path guide according to the first embodiment.

1 to 5, the water purifier 1 (hereinafter, referred to as the “water purifier 1” for convenience of description) having a heating passage heated by the induction heating apparatus according to the first embodiment has an external appearance. It comprises a housing 10 forming a. The housing 10 may include a plurality of panels, and the housing 10 may be completed by combining the plurality of panels. As an example, the housing 10 may include a front panel, two side panels, an upper panel, a rear panel, and a lower panel, but the number of the plurality of panels is not limited in the present invention.

In addition, the front panel of the housing 10 may be provided with an input unit 15 for inputting an operation command.

The input unit 15 may include an integer selection unit for selecting to extract the purified water, a hot water selection unit for selecting the hot water, and a temperature selection unit for selecting the temperature of the hot water to be extracted.

The water purifier 1 may further include an operation lever 16 for operating for taking out purified water or hot water.

The water purifier 1 may further include a filter unit 20 for purifying water supplied from the outside, and a purified water passage 31 through which water passed through the filter unit 20 flows. The filter unit 20 may include one or more filters.

The purified water flow passage 31 may be branched into the first flow passage 32 and the second flow passage 33.

The first flow passage 33 may be connected to the outlet 35 for allowing water to be drawn out of the water purifier 1. Water for heating may flow into the second flow path 33.

The water purifier 1 is a controller for controlling the instantaneous hot water device 50 and the instantaneous hot water device 50 to heat the water to change the hot water in the process of the water supplied from the first flow path 33 flows. 80 may further include.

The instantaneous hot water device 50 includes a heating flow path part 60 that forms a heating flow path 66 through which heated water flows, and is disposed on one side of the heating flow path part 60, and the heating flow path 66. May include a heating device 70 (also referred to as an "euro heating device") for heating the flowing water. The heating flow path part 60 may also be referred to as a hot water tank.

The heating device 70 may include a frame 710 and a coil part 730 seated on the frame 710.

The controller 80 may be disposed adjacent to the instantaneous hot water device 50, and the influence of the magnetic field of the coil unit 730 may be influenced by the controller 80 between the controller 80 and the instantaneous hot water device 50. 80 may be provided with a blocking plate 90 to prevent it from affecting 80.

The frame 710 may include a ferrite seating part 713 on which the ferrite 720 is seated. The ferrite seating part 713 may be formed by recessing a part of the frame 710. Alternatively, the ferrite seating portion 713 may be formed by a plurality of ribs formed in the frame 710. A hole 713 may be formed in the ferrite seating part 713.

An opening 711 may be formed in the central portion of the frame 710. In addition, a plurality of ferrite seating parts 713 may be disposed along the circumference of the opening 711.

An overheat sensor 740 may be located in the opening 711 to detect the temperature of the heating passage part 60. That is, the overheat sensor 740 may be located in an area formed by the coil. The overheat sensor 740 may be in contact with the heating flow path part 60 or spaced apart from the heating flow path part 60.

The controller 80, in order to prevent the heating flow path unit 60 from being heated in a state where water is not present in the heating flow path unit 60,

When the temperature detected by the overheat sensor 740 exceeds the reference temperature, the operation of the heating device 70 may be stopped.

The frame 710 may be provided with a plurality of contact ribs 714 contacting the circumference of the coil part 730 in order to prevent the position of the coil part 730 placed on the ferrite 720 from changing. have.

The coil unit 730 may be disposed by winding a coil (or wire) a plurality of times, and stacked in a plurality of layers. In one example the coil may be wound in an annular shape.

When the coils constituting the coil part 730 are arranged in one layer, the size of the frame for placing the coil part 730 is increased so that the overall size of the heating device is increased. According to the present invention, As the coils are stacked in a plurality of layers, the area occupied by the coil unit 730 may be reduced, thereby compacting the heating device 70. The coil unit 730 may also be referred to as a walking coil.

At this time, the height of the plurality of contact ribs 714 may be equal to or higher than the stack height of the coil unit 730.

The frame 710 may include one or more coupling ribs 715 for coupling with the heating flow path part 60. The one or more coupling ribs 715 may include a locking part 716 for catching the heating flow path part 60. Alternatively, the coupling rib 715 may be fastened to the heating flow path part 60 by a fastening member.

The coil part 730 may be formed in a circular ring or an elliptic ring shape as a whole. Of course, the coil unit 730 may be formed in a polygonal ring shape.

The coil unit 730 may include an input terminal 731 and an output terminal 732. At least one of the input terminal 731 and the output terminal 732 may pass through the opening 711. In FIG. 3, for example, the output terminal 732 passes through the opening 711.

The heating flow path part 60 includes a first guide 61 having an inlet part 63 for introducing heated water, a discharge part 64 for discharging the heated water (hot water), and the first guide 61. A second guide 62 for forming the heating passage 66 together with the guide 61 may be included. The first guide 61 has a shape such as a box having one surface opened, and the second guide 62 is formed in a flat plate shape and coupled to the opening surface of the first guide 61. An internal space formed by the first guide 61 and the second guide 62 becomes a heating flow path 66.

The inlet part 62 may be referred to as an inlet pipe, and the outlet part 64 may be referred to as an outlet pipe.

The second guide 62 may be a magnetic material to enable induction heating. The first guide 61 may be a nonmagnetic material that is not subjected to induction heating. Of course, both of the first guide 61 and the second guide 62 may be magnetic materials.

The second guide 62 may be referred to as a first cover, and the first guide 61 may be referred to as a second cover.

When a current is applied to the coil unit 730, a magnetic field is generated in the coil unit 730, and a current is generated in the second guide 62 by the magnetic field, thereby heating the second guide 62.

The coil part 730 may be spaced apart from the heating flow path part 62 by a predetermined interval. Spacers 717 may be provided in the frame so that the coil part 730 is spaced apart from the heating flow path part 62 by a predetermined interval. The spacer 717 may contact the second guide 62 in a state in which the heating device is coupled to the heating flow path part 60.

The heating flow path part 60 may be disposed in the water purifier 1 such that the discharge part 64 is positioned higher than the inlet part 63.

Therefore, since the water flowing into the heating channel 66 should rise from the inlet portion 63 side to the discharge portion 64 side, the water flowing through the heating channel 66 can be sufficiently heated.

According to the present embodiment, water flowing in the heating flow path 66 formed by the second guide 62 may be heated by the second guide 62. At this time, the entire second guide 62 may be heated, and since there is no loss of a heat source, the water on the heating passage 66 may be heated quickly.

In addition, since the surface of the second guide 62 generates heat, there is no temperature rise around the heating flow path part 60, so that heat insulation of the heating flow path part 60 is unnecessary.

In addition, since the water flowing in the heating flow path 66 is instantaneously heated, standby power for storing hot water is unnecessary.

In addition, the discharge part 64 may be connected to the second flow path 33 by a third flow path 34.

The heating flow path 66 may be provided with a flow path guide 65 for allowing water to flow evenly throughout the heating flow path 66.

The flow path guide 65 may be disposed in a direction crossing the flow direction of water in the heating flow path 66. In addition, the flow path guide 65 may be located closer to the discharge part 64 than the inlet part 63. The flow path guide 65 is located close to the discharge part 64 to prevent water from being stagnated at the corners of the heating flow path part 60 around the discharge part 64 to prevent the water from vaporizing. In addition, the flow of water in the heating passage 66 is slightly lowered so that the water is evenly mixed to prevent the water from being locally heated and reduce the generation of noise. However, in this embodiment, the position of the flow path guide 65 is not limited thereto.

The flow path guide 65 may include a plurality of holes 652, 653, and 654 through which water passes. The plurality of holes 652, 653, and 654 may be arranged in a direction crossing the flow direction of water in the heating passage 66. In addition, sizes of the plurality of holes 652, 653, and 654 may be different.

The plurality of holes 652, 653, and 654 may include a first hole 652 having a first size, a second hole 653 having a second size smaller than the first size, and the first hole. It may include one or more third holes 654 positioned between the hole 652 and the second hole 653. The one or more third holes 654 are the same as the size of any one of the first hole 652 and the second hole 653 or different from the sizes of the first hole 652 and the second hole 653. Can be. In the present embodiment, one or more third holes may be omitted from the flow path guide.

The first hole 652 may be located close to the end of the flow path guide 65, and the second hole 653 may be located close to the center portion of the flow path guide 65. In addition, the second hole 653 may be located closer to the discharge part 64 than the first hole 652.

Therefore, since the flow resistance of the second hole 653 having a smaller size in the heating passage 66 is greater than the flow resistance of the first hole 652, water flows only to the second hole 653 side. This can be prevented so that the heating flow path 66 water can flow uniformly.

When water flows uniformly in the heating passage 66, the contact time between the water and the second guide 62 is increased, and thus the heating time of the water may be reduced.

As another example, a flow path guide may be formed in at least one of the first guide 61 and the second guide 62. In this case, the flow path guide may extend in a direction crossing the flow direction of water at a position adjacent to the discharge part 64.

The first passage 32 may be provided with a first valve 41 for controlling the flow of water. A second valve 42 for controlling the flow of water may be provided between the point where the third passage 34 is connected to the second passage 33 and the point where the first passage 32 meets.

The water purifier 1 is provided in the first flow path 32 to obtain a temperature sensor 91 for sensing the temperature of the water to be introduced into the heating flow path unit 60, and the heating flow path unit provided in the third flow path It may further include a water extraction temperature sensor 92 for detecting the temperature of the water (hot water) discharged from (60).

6 is a block diagram of a water purifier according to the first embodiment.

Referring to FIG. 6, the water purifier 1 further includes a flow rate sensor 83 that detects a flow rate of water flowing into the heating flow path part 60, and a drive source 95 controlled by the controller 80. It may include.

The driving source 95 may include, but is not limited to, a compressor, a display unit, and the like, and may include all components operated by receiving a current other than the instantaneous hot water device from the water purifier 1.

The controller 80 may include an inverter 81 that adjusts a current applied to the coil unit 730.

The inverter 81 may adjust the amount of induction heating by varying the current applied to the coil unit 730. As such, when the induction heating amount is adjusted, water may be heated to a temperature desired by the user, and hot water of a desired temperature may be taken out of the outlet 35.

7 is a view showing a change in current of the water purifier with time according to the first embodiment.

Referring to FIG. 7, the controller 80 may adjust the current of the whole water purifier 1.

Specifically, the controller 80 may adjust the current of the driving source 95 according to whether the heating device 70 is operated. The controller 80 may control the total current value A2 of the water purifier 1 not to exceed the limit current value A1.

When the heating device 70 is operated while the driving source 95 is operating, a case in which the current of the water purifier 1 exceeds the limit current value A1 may occur, in which case the water purifier 1 is Abnormal operation or power of the water purifier 1 may be cut off.

Therefore, in the present invention, when the heating device 70 is operated, the controller 80 adjusts the current of the driving source 95 based on the current of the heating device 70, whereby the water purifier 1 has a total current. The value A2 becomes lower than the limit current value A1.

For example, the current of the heating device 70 may vary, and when the current of the heating device 70 increases, the controller 80 lowers the current of the driving source 95 and the heating device 70. When the current decreases, the current of the driving source 95 may be increased.

Hereinafter, with reference to FIGS. 1 to 6, the process of extracting purified water and hot water from the water purifier will be described.

First, the integer extraction process will be described.

When the constant selector is selected and the operation lever 16 is operated, the first valve 41 is turned off and the second valve 42 is turned on. Then, the purified water purified by the filter unit 20 flows through the purified water flow passage 31 and the second flow passage 33 and is discharged through the outlet 35.

Next, the hot water extraction process will be described.

When the hot water selector is selected and the operation lever 16 is operated, the first valve 41 is turned on, the second valve 42 is turned off, and the heating device 70 is operated.

The controller 80 may be applied to the coil unit 740 based on the flow rate detected by the flow rate sensor 83 and the temperature detected by the intake temperature sensor 91 at the initial stage of operation of the heating device 70. The current is determined, and the determined current is supplied to the coil unit 740.

Then, the purified water purified by the filter unit 20 flows into the heating channel 66 of the heating channel unit 60 through the inlet unit 63 after flowing the first channel 32. When the heating device 70 is operated, the second guide 62 is heated and the water flowing along the heating passage 66 is heated by the second guide 62 to be changed into hot water. The hot water flows into the third flow path 34 through the discharge part 64. Finally, hot water is discharged through the outlet 35.

The user may set the temperature of hot water to be taken out using the temperature selection unit. While the heating device 70 is operating, the water extraction temperature sensor 93 detects the temperature of the hot water, and the controller 80 supplies the coil unit 730 so that the detected temperature of the hot water is equal to the set temperature. Adjust the current.

Therefore, according to the present embodiment, since the user can set the temperature of the hot water and obtain the hot water of the set temperature, there is an advantage that can satisfy the user's preferences.

8 is a block diagram of a water purifier according to the second embodiment.

This embodiment is the same as the first embodiment in other parts, but it is characterized in that the flow rate of the water flowing to the heating device can be adjusted. Therefore, hereinafter, the characteristic parts of the embodiment will be described.

Referring to FIG. 8, the controller 80 determines a flow rate of water to flow to the heating flow path part 60 based on the temperature of the water sensed by the intake temperature sensor 91 at the beginning of operation of the heating device 70. The first valve 41 is controlled so that the water of the determined flow rate is supplied to the heating flow path part 60.

For example, when the temperature sensed by the intake temperature sensor 91 is high, the controller 80 may control the first valve 41 so that the flow rate of water flowing into the heating flow path unit 60 is high. On the other hand, when the temperature sensed by the intake temperature sensor 91 is high, the controller 80 may control the first valve 41 so that the flow rate of water flowing into the heating flow path part 60 is small.

Then, the water of the determined flow rate is heated in the process of flowing the heating flow path unit 60.

The user may set the temperature of hot water to be taken out using the temperature selection unit.

While the heating device 70 is operating, the water extraction temperature sensor 93 detects the temperature of the hot water, and the controller 80 is supplied to the coil unit 730 so that the detected temperature of the hot water is equal to the set temperature. Adjust the current

Meanwhile, in the present invention, steam may be generated in the heating flow path part 60 by adjusting the flow rate of water flowing through the heating flow path part 60 and the current applied to the coil part 730. The steam generated in the heating flow path part 60 may be discharged through the outlet 35, and in this process, the flow path from the heating flow path part 60 to the outlet 35 and the outlet 35 may be discharged. Sterilization is possible.

In the above two embodiments, the current supplied to the coil unit is determined based on the initial operation of the heating device, the temperature of the water detected by the inlet temperature sensor, and the flow rate detected by the flow sensor. It may be omitted, the current of the initial size of the operation of the heating device is supplied to the coil unit, the current supplied to the coil unit may be adjusted based on the temperature of the hot water detected by the water extraction temperature sensor.

In addition, in the above embodiments, it is described that the heating device is located on one side of the heating flow path part, but alternatively, the heating devices may be provided on both sides of the heating flow path part.

In addition, in the above embodiments, the instantaneous hot water device has been described that the water purifier is provided, in contrast, the idea of the present invention can be applied to household appliances having a water extraction function. For example, components such as the instantaneous hot water device, the filter unit, the above-described water flow path, a valve, a sensor, an input unit, and the like may also be provided in the refrigerator. In this case, the instant hot water device may be provided in a main body having a frame or a storage compartment of a refrigerator door, for example.

9 is a view showing the instantaneous hot water apparatus according to the third embodiment, FIG. 10 is a front view of the heating flow path part according to the third embodiment, and FIG. 11 is a cross-sectional view taken along the line A-A of FIG.

This embodiment is the same as the first embodiment in other parts, but there is a difference in the flow path guide in the heating flow path part. Therefore, hereinafter, only characteristic parts of the present embodiment will be described, and the same parts as the first embodiment will be described with reference to the first embodiment.

9 to 11, the instantaneous hot water device 71 according to the present embodiment may include a heating flow path part 60 through which water may flow.

The heating flow path part 60 includes a first guide 61 having an inlet part 63, a discharge part 64 through which heated water (hot water) is discharged, and the first guide 61 together with the first guide 61. It may include a second guide 62 for forming the heating passage (66).

The second guide 62 may be referred to as a first cover, and the first guide 61 may be referred to as a second cover.

The first guide 61 may include a flow path guide 612 for guiding the flow of water in the heating flow path 66.

The flow guide 612 may be formed by forming a portion of the first guide 61. For example, a portion of the first guide 61 may protrude toward the second guide 62 of the flow path guide 612.

For example, a surface facing the second guide 62 from the first guide 61 is called a base surface, and a surface protruding from the first guide 61 toward the second guide 62 is a protruding surface. The side or portion connecting the base surface and the protruding surface may be referred to as a circumference.

The flow guide 612 may serve as a flow resistance of water between the inlet 63 and the outlet 64.

That is, at least a portion of the water introduced through the inflow portion 63 may flow by bypassing the flow path guide 612 by the flow path guide 612.

The flow guide 612 may serve to prevent the water introduced through the inlet 63 from flowing directly to the outlet 64. To this end, at least a portion of the flow guide 612 may be disposed to face the inlet portion 63.

Therefore, at least a portion of the water introduced into the heating flow path 66 through the inflow portion 63 may be changed in flow direction by the flow path guide 612.

For example, at least a portion of the flow guide 612 may be disposed on a line connecting the inlet 63 and the outlet 64.

In this case, the flow guide 612 may extend from the first guide 61 toward the second guide 62 and may be spaced apart from the second guide 62. That is, the flow guide 612 may not be in contact with the second guide 62.

According to the present embodiment, as the flow path guide 612 is spaced apart from the second guide 62, heat generated by heating the second guide 62 by current flowing through the coil part 730 is generated. Heat loss due to transfer to the flow path guide 612 may be prevented.

That is, according to the present embodiment, part of the heat generated by the second guide 62 may be transferred to the first guide 61 in contact with the second guide 62, and the other part of the heat may be transferred to the first guide 61. It may be delivered to the water between the 61 and the second guide 62.

However, when the flow path guide 612 is in contact with the second guide 62, a portion of the heat of the second guide 62 is not transferred to the water, but is transferred directly to the flow path guide 612 to cause heat loss. According to the present exemplary embodiment, heat loss may be prevented as the flow guide 612 is spaced apart from the second guide 62.

In this case, the distance D2 between the flow path guide 612 and the second guide 62 may be smaller than 1/2 of the distance D1 between the first guide 61 and the second guide 62. have. According to such a structure, while the heat loss by the flow path guide 612 is prevented, the flow path guide 612 may serve as a flow path resistance.

The coil unit 730 may be formed in a ring shape as described above. In this case, the coil part 730 has an opening 732 in which no coil exists.

In addition, the coil part 730 and the heating flow path part 60 may face each other. That is, the heating flow path part 60 may include a first part 611a facing the coil part 730 and a second part 611b not facing the coil part 730.

In this case, the temperature of the second part 611b facing the opening 732 in the first guide 61 is lower than the temperature of the first part 611a facing the coil part 730.

Therefore, it is preferable that water introduced through the inflow portion 63 flows along the first portion 611a facing the coil portion 730.

To this end, the flow path guide 612 may be located between the second portion 611b and the inflow portion 63 in the first guide 61. In this case, the inflow portion 63, the flow guide 612, and the second portion 611b may be positioned in a straight line.

Therefore, the water introduced through the inflow portion 63 flows while being divided into both sides of the flow path guide 612 by the flow path guide 612, so that the water flows through the coil part 730. ) May rise along the first portion 611a which is a portion facing the.

Of course, water may also exist on the second portion 611b side, and there may be a flow of water, but may be affected by the flow of water flowing along the first portion 611a.

According to the proposed embodiment, as the water flowing into the inlet 63 by the flow guide 612 is prevented from flowing directly toward the outlet 64, the water is heated in the heating passage as a whole. There is an advantage that can be.

In addition, the water can flow uniformly in the heating channel, so that generation of steam due to local overheating at one point in the heating channel can be prevented.

12 is a front view of a heating flow path part according to a fourth embodiment.

This embodiment is the same as the third embodiment in other parts, but there is a difference in the flow path guide in the heating flow path part. Therefore, hereinafter, only characteristic parts of the present embodiment will be described, and the same parts as the third embodiment will be described with reference to the third embodiment.

Referring to FIG. 12, the first guide 61 of the present embodiment may include a plurality of flow path guides 612 and 615.

The plurality of flow path guides 612 may be spaced apart from each other in the direction parallel to the flow direction of water between the inflow portion 63 and the discharge portion 64.

The plurality of flow guides 612 and 615 may include a first flow guide 612 and a second flow guide 615 disposed between the first flow guide 612 and the discharge part 64. Can be.

Since it may be the same as the flow guide 612 described in the form and location of the first flow guide 612 of the third embodiment, a detailed description thereof will be omitted.

The second flow path guide 615 may guide the flow of water so that the water flows in the heating flow path 66 around the outlet 64.

At least a portion of the second flow guide 615 may be positioned on a line connecting the first flow guide 612 and the discharge unit 64, for example.

In addition, at least a portion of the second flow guide 615 may be disposed between the discharge portion 64 and the second portion 611b of the first guide 61.

In addition, the first channel guide 612 and the second channel guide 615 may face the coil unit 730.

According to the present exemplary embodiment, the first flow guide 612 may allow the water introduced through the inflow portion 63 to flow along the first portion 611a facing the coil portion 730. The flow can be guided.

The second channel guide 615 may prevent water flowing toward the outlet 64 from the heating channel 66 from being concentrated around the outlet 64 in the heating channel 66. have. That is, since water may flow to both side regions of the outlet 64 in the heating passage 66, local overheating at both sides of the outlet 64 may be reduced.

In the above embodiment, the first guide 61 has been described as including a first flow guide 612 and a second flow guide 615, but unlike this, the first guide 61 has a second flow guide ( It is also possible to include only 615.

13 is a front view of the heating flow path part according to the fifth embodiment.

This embodiment is the same as the fourth embodiment in other parts, but there is a difference in the flow path guide in the heating flow path part. Therefore, hereinafter, only the characteristic parts of the present embodiment will be described, and the same parts as the fourth embodiment will be described with reference to the fourth embodiment.

Referring to FIG. 13, the first guide 61 of the present exemplary embodiment may include a plurality of flow path guides 612 to 617.

The plurality of flow path guides 612 to 617 may include a plurality of first flow guides 612, 613, and 614, and an area between the plurality of first flow guides 612, 613, and 614 and the discharge part 64. The plurality of second flow guides 615, 616, and 617 may be disposed in the plurality of guides.

The plurality of first flow guides 612, 613, and 614 may be arranged in a direction crossing the flow direction of water between the inlet 63 and the outlet 64.

The plurality of second flow guides 615, 616, and 617 may be arranged in a direction crossing the flow direction of water between the inlet 63 and the outlet 64.

At least some of the plurality of first flow guides 612, 613, and 614 may be disposed on a line connecting the inlet 63 and the outlet 64.

In addition, at least some of the plurality of second flow guides 615, 616, and 617 may be disposed on a line connecting the inlet 63 and the outlet 64.

The plurality of first flow path guides 612, 613, and 614 may guide the flow of water so that water introduced through the inflow portion 63 may be distributed and flow in the heating flow path 66. .

 The plurality of first flow guides 612, 613, and 614 may guide the flow of water to flow along the first portion 611a facing the coil unit 730.

Each of the plurality of first flow guides 612, 613, and 614 may be spaced apart from the side portion 67 of the heating flow path part 60.

The first guide 61 may include a third part 611c in which the coil part 730 does not face the opening 732 of the second part 611b not facing the coil part 730. have. In this embodiment, the gap between two adjacent first flow path guides is a side part of the heating flow path part 60 so that water flowing through the inflow part 63 is minimized to flow to the third part 611c. It may be larger than the distance between the one flow path guides 613 and 614 adjacent to the 67 and the side portion 67 of the heating flow path part 60.

The plurality of second channel guides 615, 616, and 617 may prevent the water rising in the heating channel 66 from concentrating on the discharge unit 64.

Each of the plurality of second flow path guides 615, 616, and 617 may be spaced apart from the side portion 67 of the heating flow path part 60. The distance between two adjacent second flow path guides may be greater than the distance between the side face portion 67 of the heating flow path part 60 and the one flow path guides 616 and 617 adjacent to the side flow path part 60 of the heating flow path part 60. have.

14 is a front view of the heating flow path part according to the sixth embodiment.

This embodiment is the same as the fifth embodiment in other parts, but there is a difference in the flow path guide in the heating flow path part. Therefore, hereinafter, only characteristic parts of the present embodiment will be described, and description of the fifth embodiment will be used for the same parts as the fifth embodiment.

Referring to FIG. 14, the heating flow path part 60 of the present embodiment may further include rounded or inclined corner parts 61d and 61e.

The corner portions 61d and 61e may include a pair of first corner portions 61d arranged such that an area of the heating passage 66 increases from the inflow portion 63 toward the discharge portion 64 side. It may include.

The corner portions 61d and 61e may include a pair of second corner portions 61e arranged to reduce an area of the heating flow path 66 from the inflow portion 63 side toward the discharge portion 64 side. It may further include.

At this time, the heating flow path between the first corner portion 61d and the second corner portion 61e in the heating flow passage may be constant based on the flow direction of water, and may have a maximum width.

The inlet 63 may be disposed between the pair of first corner portions 61d, and the discharge portion 64 may be disposed between the pair of second corner portions 61e.

According to the present embodiment, the water introduced through the inlet portion 63 by the first corner portion 61d may be entirely distributed and flow to the discharge portion 64 side.

In addition, since the water does not stagnate in the second corner portion 61e by the second corner portion 61e, the water flows along the second corner portion 61e and flows toward the discharge portion 64 side. Local overheating of the water at the second corner portion 61e side can be prevented.

In the above embodiment, the heating flow path part 60 has been described as including a rounded or inclined first corner part and a second corner part. It is also possible to include only. In this case, the second corner portion may be arranged to reduce the area of the heating flow passage away from the inlet portion 63, and the discharge portion may be disposed between the pair of second corner portions.

35: outlet 50: instantaneous hot water device
60: heating flow path part 70: heating device
80: controller

Claims (8)

A working coil having a wire wound in an annular shape;
A hot water tank arranged to face the working coil at a position spaced from the working coil to be inductively heated by the working coil,
The hot water tank may be disposed to face the walking coil and include a first cover having a magnetic shape;
And a second cover coupled to an edge of the first cover to provide water flow and heating space together with the first cover, and a magnetic cover.
The second cover,
A base surface disposed to face the first cover at a position spaced apart from the first cover to form a flow and heating space of the water;
A protruding surface protruding from the base surface toward the first cover;
A periphery formed around the protruding surface to connect the base surface and the protruding surface to each other;
An inlet pipe coupled to one side of the second cover; And
Water purifying apparatus comprising an outlet pipe coupled to the other side of the second cover. The method of claim 1,
The protruding surface is disposed between the water inlet pipe and the water outlet pipe. The method of claim 2,
The protruding surface is a water purification device located on a straight line connecting the water inlet pipe and the water outlet pipe. The method of claim 1,
And a plurality of protruding surfaces are spaced apart from each other in the direction parallel to the flow direction of water between the water inlet pipe and the water outlet pipe. The method of claim 1,
And a plurality of protruding surfaces spaced apart from each other in the direction intersecting the flow direction of water between the water inlet pipe and the water outlet pipe. The method of claim 1,
And a plurality of protruding surfaces spaced apart from each other in the direction parallel to the flow direction of water between the water inlet pipe and the water outlet pipe, and spaced apart from each other in the direction crossing the water flow direction between the water inlet pipe and the water outlet pipe. The method of claim 1,
The protruding surface is a water purifying device spaced apart from the first cover. The method of claim 1,
And a frame having a spacer so that the working coil may be spaced apart from the first cover at a predetermined interval.

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