KR20190095217A - Water purifier - Google Patents

Abstract

The present invention provides a water purifier, which comprises: a direct hot water tank having an inlet and an outlet and forming a flow path for generating hot water; an inlet pipe connected to the inlet to supply purified water to the direct hot water tank; an outlet pipe connected to the outlet for discharging hot water heated in the direct hot water tank; an induction heating device including a power device and heating the direct hot water tank using an induction current; and a water cooling type cooling tank installed in the inlet pipe and cooling the power device by the purified water supplied from the inlet pipe. According to the present invention, the limitation of the cooling performance of the power device of a conventional induction heating device can be overcome.

Description

Water Purifier {WATER PURIFIER}

The present invention relates to a water purifier that generates hot water using induction heating.

The water purifier may be divided into a water storage tank type and a direct water type according to whether the water purifier includes a water storage tank. The reservoir water purifier is configured to store the purified water in the reservoir and to provide the purified water stored in the reservoir when the user manipulates the outlet. In contrast, the direct type water purifier does not have a water tank, and when the user manipulates the water outlet, the raw water is immediately filtered to provide purified water to the user. Direct type water purifiers are more hygienic and water-saving than water tank type water purifiers. In recent years, users' preferences for direct type water purifiers have increased.

In addition to room temperature, water purifiers also provide hot and cold water. The water purifier for providing hot water and cold water has a heating device and a cooling device therein. The heating device is adapted to heat the purified water to produce hot water, and the cooling device is adapted to cool the purified water to produce cold water.

On the other hand, the induction heating device has a high energy efficiency and has the advantage that the rapid and uniform control of the heating object, the development for applying the induction heating device to the instantaneous hot water heating device to the direct type water purifier is actively made.

However, in the conventional induction heating apparatus, heat is generated from the power element of the inverter used to control the supply power, and an effort to efficiently release this heat is required.

To this end, there has been an attempt to apply a natural air cooling method in the prior art, but in the case of air cooling, there is a problem in that the hot water is continuously discharged or instantaneously heated due to the limitation of the cooling performance of the power device.

In addition, there is a problem that the development is limited in low input power conditions, such as Japan and the United States.

Accordingly, it is an object of the present invention to provide a water purifier capable of overcoming the limitation of cooling performance for power devices of existing induction heating apparatus.

In addition, an object of the present invention is to provide a water purifier that can improve the cooling performance of the power device to remove the restrictions on the development even under low input power source.

In order to achieve the object of the present invention, the water purifier according to the present invention includes a direct type hot water tank having an inlet and an outlet, and forming a flow path for generating hot water; An inlet pipe connected to the inlet to supply purified water to the direct hot water tank; A water outlet pipe connected to the outlet port for discharging hot water heated in the direct type hot water tank; An induction heating device including a power device and heating the direct hot water tank using an induction current; It is installed in the water supply pipe, and includes a water-cooled cooling tank for cooling the power device by the purified water supplied from the water supply pipe.

According to an example related to the present invention, the power device may be mounted inside or outside the water-cooled cooling tank.

According to an embodiment related to the present invention, the heat sink further comprises a heat sink in contact with the water-cooled cooling tank, wherein the power device is connected in contact with the heat sink, and heats the water-cooled cooling tank through the heat sink. Can emit.

According to an example related to the present invention, the water-cooled cooling tank may be connected in series with the direct type hot water tank.

According to an example related to the present invention, purified water heated in the water-cooled cooling tank may be supplied to the direct hot water tank.

According to an example related to the present invention, the induction heating apparatus includes a printed circuit board; An induction coil connected to the printed circuit board and forming a magnetic field to induce current in the direct hot water tank; The inverter may be mounted on the printed circuit board to control the induction coil.

According to an example related to the present disclosure, the power device may be disposed to be spaced apart from the inverter and electrically connected to the inverter.

According to an example related to the present invention, the power device may be mounted to the inverter and spaced apart from the water cooling cooling tank.

According to an example related to the present invention, the power device may be a bridge diode and an IGBT.

According to the present invention configured as described above, it has the following effects.

First, the water-cooled cooling tank serves as a water-cooled heat sink by utilizing the water flowing from the inlet pipe as cooling water, thereby efficiently cooling the heat generated from the power device.

Secondly, the water-cooled cooling tank is continuously supplied with new cooling water from the water source, so that the cooling performance can be continuously maintained even when the power device is cooled for a long time.

Third, since the purified water warmed through heat exchange with the power element is supplied to the direct type hot water tank, it is possible to preheat the purified water before flowing into the hot water tank, which not only shortens the heating time for generating hot water but also saves energy. have.

Fourth, the output of the induction heating apparatus for generating hot water instantaneously through maximizing the cooling performance and shortening the heating time of the power device, as well as it is possible to continue the continuous hot water discharge.

Fifth, as the preheating of the purified water supplied to the hot water tank is possible by utilizing the heat emitted from the power device, hot water at a desired temperature can be generated even when the induced current voltage for heating the hot water tank is low. It can be commercialized for export to low voltage countries.

1 is a conceptual diagram showing a power device cooling device of an induction heating inverter applied to a water purifier according to the present invention.
FIG. 2 is a circuit diagram illustrating a control configuration of an induction heating inverter in FIG. 1.
3 is a conceptual diagram illustrating a power device cooling apparatus of an induction heating inverter applied to a water purifier according to a second embodiment of the present invention.

EMBODIMENT OF THE INVENTION Hereinafter, the water purifier which concerns on this invention is demonstrated in detail with reference to drawings. Singular expressions include plural expressions unless the context clearly indicates otherwise.

The present invention relates to a power device 34 cooling device of the induction heating device 30 that can be applied to the water purifier.

The induction heating apparatus 30 of the present invention can be applied to a direct type water purifier.

1 is a conceptual diagram showing a power device 34 cooling apparatus of an induction heating inverter 33 applied to a water purifier according to a first embodiment of the present invention, Figure 2 is a control configuration of the induction heating inverter 33 in FIG. It is a circuit diagram showing.

The direct type water purifier includes a filter unit 10, a direct type hot water tank 20, and an induction heating device 30.

The filter unit 10 purifies the water supplied from the water supply source, and the user may drink the purified water purified by the filter unit 10.

The direct type hot water tank 20 may form a heating flow path therein. The heating flow path portion is configured to be heated while flowing without stagnation of water. The heating flow path part may have a long flow path length and a narrow flow path width.

The direct type hot water tank 20 is formed of a conductive material such as metal. The direct type hot water tank 20 may be formed in a rectangular parallelepiped shape having a wide width and length and low height.

Water inlets and outlets are formed on both sides of the direct type hot water tank 20, and purified water from the filter unit 10 flows into the hot water tank 20 through the inlet port, and heated hot water is supplied to the hot water tank through the outlet port. 20 may flow out of the. The inlets and outlets may be arranged to face each other or to be staggered on both sides. 1 shows an inlet and an outlet facing each other. In addition, the inlet may be formed on the bottom of the hot water tank 20 and the outlet may be formed on the upper surface of the hot water tank 20.

The induction heating device 30 includes a printed circuit board 36, an induction coil 31, an inverter 33, a power device 34, and an AC power supply 32. The direct type hot water tank 20 is instantaneously heated.

The induction coil 31 is formed of a coil made of a conductive material such as copper, and when a current is applied, a magnetic field may be formed in and around the coil. In particular, when an alternating current is applied, the direction of the magnetic field is changed by the frequency of the alternating current. The induction coil 31 may be electrically connected to the printed circuit board 36.

The direct type hot water tank 20 is configured to be located in an alternating magnetic field of the induction coil, and a voltage is induced to the direct type hot water tank 20 by Faraday's law. The induced voltage causes the flow of electrons in the hot water tank 20, and the current induced in the hot water tank 20 flows in the opposite direction to the current flowing in the coil. Accordingly, by controlling the frequency of the current flowing in the induction coil 31, the frequency of the current flowing in the hot water tank 20 can also be controlled.

When a current flows in the hot water tank 20, a resistance is generated to interrupt the flow of electrons, and heat is generated by this resistance.

The inverter 33 may control the current to be applied to the induction coil 31. The inverter 33 can adjust the amount of induction heating by varying the frequency of the current applied to the induction coil 31 and the like. As a result, the water may be heated to a temperature desired by the user by adjusting the induction heating amount, and the user may generate and drink hot water having a desired temperature.

The inverter 33 may include a power device 34, an inductor 331, a capacitor 332, a resonant capacitor 333, and the like to control power supplied to the induction coil 31.

The AC power supply 32 is connected to the bridge diode 341. The bridge diode 341 connects four diodes to rectify the AC current into the DC current.

The power device 34 includes a bridge diode 341 and an IGBT 342.

An inductor 331 and a capacitor 332 are disposed in a circuit between the bridge diode 341 and the induction coil 31, and the inductor 331 and the capacitor 332 serve to smooth the rectified DC current.

The IGBT 342 is a switching element connected to the control circuit unit 35 and turned on / off by the control of the control circuit unit 35 to control the power applied to the induction coil 31.

The resonant capacitor 333 is disposed between the inductor 331 and the control circuit unit 35, and is connected in parallel with the induction coil 31 to adjust the resonant frequency of the induction coil 31.

The AC power source 32 and the inverter 33 except for the power device 34 may be mounted on the printed circuit board 36.

Here, the present invention provides a water-cooled cooling tank 40 for cooling the power device 34.

The water-cooled cooling tank 40 has a storage space for temporarily storing the purified water moving along the inlet pipe 11, and may be formed in a rectangular parallelepiped shape. Inlet is formed on one side of the water-cooled cooling tank 40, the outlet may be formed on the other side of the cooling tank. The inlet of the cooling tank is connected in communication with the inlet pipe 11, the outlet of the cooling tank may be connected to the inlet of the direct hot water tank 20 by the connection pipe (12). The low temperature (room temperature) purified water supplied from the water inlet pipe 11 may be introduced into the water-cooled cooling tank 40 through the inlet, and may flow out of the water-cooled cooling tank 40 through the outlet. The water-cooled cooling tank 40 may be a metal material having high thermal conductivity. Flow control valve is installed in the inlet pipe 11 can control the flow rate of purified water through the filter unit.

The power device 34 may be mounted inside or outside the water-cooled cooling tank 40. 1 shows a state in which the power device 34 is mounted on an outer side of the water-cooled cooling tank 40. The bridge diode 341 and the IGBT 342 may be spaced apart from each other side by side, and may be installed to be in contact with the water-cooled cooling tank 40. When the power device 34 is mounted inside the water-cooled cooling tank 40, the power device 34 should be waterproofed by the sealing member. The bridge diode 341 and the IGBT 342 may be electrically connected to the inverter 33, respectively.

According to this configuration, the purified water flowing along the water inlet pipe 11 is low temperature water, and the low temperature purified water is supplied to the direct type hot water tank 20 along the connection pipe 12 via the water cooling cooling tank 40. The purified water may be discharged to the outside through the water discharge pipe 21 after being heated by the induction heating device 30 while flowing along the heating flow path of the direct hot water tank 20. The hot water discharged from the hot water tank 20 is discharged through the water outlet so that the user can drink hot water.

Here, heat is generated when the power elements 34 such as the bridge diode 341 and the IGBT 342 are used to control the current applied to the induction coil 31.

When the power device 34 is mounted outside the water cooling cooling tank 40, the power device 34 is in contact with the water cooling cooling tank 40 so that heat generated from the power device 34 flows into the water cooling cooling tank 40. As the heat is transferred to an integer, the power device 34 may be cooled. In addition, a portion of the power device 34 that is not in contact with the water-cooled cooling tank 40 may dissipate heat into the atmosphere through the surface in contact with the atmosphere.

When the power device 34 is mounted inside the water-cooled cooling tank 40 while being sealed by a heat sink (not shown), heat can be radiated in all directions through the heat sink, thereby improving heat transfer efficiency. .

Therefore, according to the present invention, the water-cooled cooling tank 40 serves as a water-cooled heat sink by utilizing water flowing from the water inlet pipe 11 as cooling water, thereby efficiently cooling the heat generated from the power device 34. .

In addition, since the water-cooled cooling tank 40 continuously receives new cooling water from the water supply source, the cooling performance can be continuously maintained even when the power device 34 is cooled for a long time.

In addition, since the purified water warmed through the heat exchange with the power device 34 is supplied to the direct type hot water tank 20, it is possible to preheat the purified water before flowing into the hot water tank 20, thereby shortening the heating time for generating hot water. But energy savings can be achieved.

In addition, by maximizing the cooling performance of the power device 34 and shortening the heating time, the output of the induction heating device 30 for instantaneously generating hot water can be improved, and continuous hot water can be discharged.

In addition, since the warm water supplied to the hot water tank 20 may be preheated by using the heat emitted from the power device 34, even when the induced current voltage for heating the hot water tank 20 is low, the hot water at a desired temperature. Since it can be produced, it is possible to commercialize for export to low-voltage countries such as 110V, 120V.

3 is a conceptual diagram illustrating a power device cooling apparatus of an induction heating inverter applied to a water purifier according to a second embodiment of the present invention.

The second embodiment differs from the first embodiment in that the power device 34 transfers heat to the water-cooled cooling tank 40 through the heat sink 50. That is, in the first embodiment, the power device 34 is in direct contact with the water-cooled cooling tank 40 to discharge heat directly to the water-cooled cooling tank 36, but the power device 34 of the second embodiment is a water-cooled cooling tank ( 40) can indirectly release heat. In the second embodiment, the power device 34 may be mounted to the inverter 33.

One side of the heat sink 50 may be connected to be in contact with the water-cooled cooling tank 40, and the other side thereof may be connected to be in contact with the power device 34. The heat sink 50 may be composed of first and second heat sinks 51 and 52 connecting the bridge diode 341 and the IGBT 342 to the water-cooled cooling tank 40, respectively. The first and second heat sinks 51 and 52 may be formed to be spaced apart from each other or integrally integrated with each other.

3 shows a state in which the first and second heat sinks 51 and 52 are spaced apart from each other. The first heat sink 51 connects the bridge diode 341 and the water cooling cooling tank 40 so that heat generated from the bridge diode 341 is transferred to the water cooling cooling tank 40 along the first heat sink 51. Can be delivered. The second heat sink 52 connects the IGBT 342 and the water cooling cooling tank 40 so that heat generated from the IGBT 342 is transferred to the water cooling cooling tank 40 along the second heat sink 52. Can be. The first and second heat sinks 51 and 52 may be exposed to the atmosphere to release heat.

In the case where the first and second heat sinks 51 and 52 are partially integrated, the first and second heat sinks 51 and 52 are connected to the water-cooled cooling tank 40 by integrating a part of each of the first and second heat sinks 51 and 52, respectively. Other portions of may be separated from each other and connected to the bridge diode 341 and the IGBT 342, respectively.

One heat sink 50 is connected between the water-cooled cooling tank 40 and the power device 34, the heat may be released from the power device 34 to the water-cooled cooling tank 40.

Here, the heat sink 50 is not limited to any form and material as long as it can transfer heat to the water-cooled cooling tank 40. Since other components are the same as or similar to the first embodiment, detailed description thereof will be omitted.

In the following description of the embodiments disclosed herein, if it is determined that the detailed description of the related known technology may obscure the gist of the embodiments disclosed herein, the detailed description thereof will be omitted.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains various modifications, changes, and substitutions without departing from the essential characteristics of the present invention. will be.

10 filter unit 11 water inlet pipe
12: connection piping 13: flow control valve
20: direct type hot water tank 21: outlet pipe
30: induction heating device 31: induction coil
32 AC power 33 Inverter
331: Inductor 332: Capacitor
333: resonant capacitor 34: power device
341 bridge diode 342 IGBT
35: control circuit unit 36: printed circuit board
40: water-cooled cooling tank 50: heat sink
51: first heat sink 52: second heat sink

Claims (9)

A direct type hot water tank having an inlet and an outlet and forming a flow path for generating hot water;
An inlet pipe connected to the inlet to supply purified water to the direct hot water tank;
A water outlet pipe connected to the outlet port for discharging hot water heated in the direct type hot water tank;
An induction heating device including a power device and heating the direct hot water tank using an induction current;
A water cooling cooling tank installed in the water inlet pipe and cooling the power device by a purified water supplied from the water inlet pipe; And
Further comprising a heat sink in contact with the water-cooled cooling tank,
The power device is connected to the heat sink in contact with the water purifier, characterized in that for discharging heat to the water-cooled cooling tank through the heat sink. The method of claim 1,
The power device is a water purifier, characterized in that mounted on the inside or outside of the water-cooled cooling tank. The method of claim 1,
The heat sink includes a first heat sink connecting a bridge diode and the water cooling cooling tank and a second heat sink connecting the IGBT and the water cooling cooling tank. The method of claim 1,
The water-cooled cooling tank is a water purifier, characterized in that connected in series with the direct type hot water tank. The method of claim 1,
The purified water heated in the water-cooled cooling tank is supplied to the direct type hot water tank. The method according to claim 2 or 3,
The induction heating device,
Printed circuit board;
An induction coil connected to the printed circuit board and forming a magnetic field to induce current in the direct hot water tank;
An inverter mounted on the printed circuit board to control the induction coil;
Water purifier comprising a. The method of claim 6,
The power device is disposed apart from the inverter, the water purifier, characterized in that electrically connected with the inverter. The method of claim 6,
The power device is mounted on the inverter, the water purifier, characterized in that spaced apart from the water-cooled cooling tank. The method of claim 1,
The power device is a water purifier, characterized in that the bridge diode and the IGBT.

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