KR102502949B1 - Instantaneous water cooling and heating apparatus and water treatment apparatus having the same - Google Patents

Abstract

Disclosed is an instantaneous hot/cold water dispenser and a water treatment device including the same.
The instantaneous cold/hot water dispenser according to an embodiment of the present invention includes an instantaneous cold/hot water unit in which a first flow space through which water flows is formed; a thermoelectric module that is connected to the instantaneous cold and hot water unit and transfers heat from one side to the other side when a voltage is applied; a heat dissipation cooling unit connected to the thermoelectric module to cool the thermoelectric module or to be cooled by the thermoelectric module; and a controller that applies a positive voltage or a reverse voltage to the thermoelectric module so that the water flowing in the first flow space is instantaneously cooled or heated by the thermoelectric module to become cold water or hot water. can include

Description

Instant water heater and water treatment device including the same

The present invention relates to an instantaneous cold or hot water dispenser that instantaneously cools or heats water to produce cold or hot water, and a water treatment device including the same.

A water treatment device such as a water purifier is a device that filters and treats water and supplies it to users.

In such a water treatment device, the treated water is cooled to become cold water and supplied to the user, or the treated water is heated to become hot water and supplied to the user.

To this end, the water treatment device includes a water cooler for cooling the treated water or a water heater for heating the treated water.

In order to cool the treated water, the water cooler includes a cold water tank into which the treated water is introduced and stored, and an evaporator through which a refrigerant flows to cool the water stored in the cold water tank.

In addition, in order to heat the treated water, the water heater includes a hot water tank into which the treated water is introduced and stored, and a heater that heats the water stored in the hot water tank.

However, the water cooler or water heater of this configuration is relatively complex and large, and cannot quickly produce cold or hot water.

Accordingly, in the case of a water cooler, a thermoelectric module in which heat is transferred from one side to the other side when voltage is applied is used to make cold water relatively quickly with a simple configuration without a cold water tank.

In addition, in the case of a water heater, a surface heating heater is used to make hot water relatively quickly with a relatively simple configuration without a hot water tank.

However, even in this case, in order to supply cold water and hot water to the user, there is a limit to miniaturization and energy saving because the water cooler and the water heater must be separately provided and separately operated.

The present invention has been made in recognition of at least one of the above-mentioned needs or problems occurring in the prior art.

One aspect of the object of the present invention is to enable miniaturization and energy saving of the device.

Another aspect of the object of the present invention is to instantaneously create cold water or hot water with one thermoelectric module and supply it to a user.

An instantaneous hot/cold water dispenser and a water treatment device including the same according to an embodiment for realizing at least one of the above tasks may include the following features.

The instantaneous cold/hot water dispenser according to one embodiment of the present invention includes an instantaneous cold/hot water unit in which a first flow space through which water flows is formed; a thermoelectric module that is connected to the instantaneous cold and hot water unit and transfers heat from one side to the other side when a voltage is applied; a heat dissipation cooling unit connected to the thermoelectric module to cool the thermoelectric module or to be cooled by the thermoelectric module; and a controller that applies a positive voltage or a reverse voltage to the thermoelectric module so that the water flowing in the first flow space is instantaneously cooled or heated by the thermoelectric module to become cold water or hot water. can include

In this case, the cooling side of the thermoelectric module that is cooled when the constant voltage is applied may be connected to the instantaneous cold/hot water unit, and the heat dissipation cooling unit may be connected to the heating side of the thermoelectric module that is heated when the constant voltage is applied.

In addition, water may flow through the heat dissipation cooling unit to cool the heating side when a positive voltage is applied to the thermoelectric module, or it may be cooled by the heating side when a reverse voltage is applied to the thermoelectric module.

In addition, a second flow space through which water flows may be formed in the heat dissipation cooling unit.

In addition, the instantaneous cold and hot water unit is connected to a cold and hot water intake line connected to one side of the first flow space and a cold and hot water outlet line connected to the other side of the first flow space, and to the heat dissipation cooling unit, heat dissipation connected to one side of the second flow space. A cooling water line and a heat dissipation cooling drain line connected to the other side of the second flow space may be connected.

In addition, a water outlet drain line connected to a radiation cooling drain line may be connected to the cold/hot outlet line.

In addition, a first flow rate sensor, a first supply valve, a flow control valve, and an inlet temperature sensor are provided in the cold and hot water inlet line, and a second flow rate sensor and a second supply valve are provided in the heat radiation and cooling inlet line, and the cold and hot outlet water line A water outlet temperature sensor and a flow path conversion valve to which the outlet drain line is connected may be provided, and a drain temperature sensor may be provided in the heat dissipation and cooling drain line.

In addition, a malfunction prevention unit including a temperature sensor or a bimetal may be provided in at least one of the instantaneous cold and hot water unit and the heat dissipation cooling unit to prevent malfunction.

In addition, a sterilization unit for sterilizing at least one of the first and second flow spaces, cold and hot water intake lines, cold and hot water outlet lines, radiating cooling water intake lines, radiating cooling drain lines, and water outlet drain lines may be further included.

In addition, the sterilization unit can sterilize by making sterilizing water.

In addition, when a cold water mode in which cold water is instantaneously produced or a hot water mode in which hot water is produced is input to the input unit included in the controller, the controller first supplies and flows water into the second flow space, and then thermoelectrically A voltage may be applied to the module, and water may be supplied and flowed in the first flow space.

The controller may apply a positive voltage to the thermoelectric module in the cold water mode and apply a reverse voltage to the thermoelectric module in the hot water mode.

In addition, when one of the cold water mode and the hot water mode is input to the input unit for the first time, the controller may supply and flow a predetermined amount of water to the first flow space before applying a voltage to the thermoelectric module.

The control unit may apply a voltage to the thermoelectric module only when water is supplied to the second flow space and flows, and may not apply a voltage to the thermoelectric module when water is supplied to the second flow space and does not flow. .

In addition, when the temperature of the water flowing through the radiating cooling drain line after flowing in the second flow space becomes higher than the predetermined ideal heating temperature in the cold water mode or lower than the predetermined abnormal cooling temperature in the hot water mode, the controller cuts off the power It can stop the entire operation.

When water is supplied to flow in the first flow space and the temperature difference between the water in the cold and hot water intake line and the water in the cold and hot water outlet line is greater than or equal to a predetermined temperature difference, the control unit determines the temperature difference between the water in the cold and hot water intake line and the water in the cold and hot water outlet line. Water remaining in the first flow space may be drained through the water outlet drain line until the temperature difference is less than the difference.

In addition, only after the water supplied to the first flow space is cooled or heated by the thermoelectric module to become cold water or hot water at a predetermined preliminary temperature, the control unit continues to supply water to the first flow space through the cold/hot water outlet line. Cold or hot water can be discharged.

The control unit may adjust the flow rate of water flowing into the first flow space through the cold/hot water inlet line so that the temperature of the cold or hot water discharged through the cold/hot water outlet line is within a predetermined target temperature range.

In addition, the control unit may allow the cold or hot water of the cold and hot water outlet line to drain through the water outlet drain line until the temperature of the cold or hot water of the cold and hot water outlet line is within a predetermined target temperature range.

The control unit may adjust the flow rate of water supplied to the first flow space through the cold/hot water inlet line to adjust the temperature of cold or hot water cooled or heated by the thermoelectric module and discharged through the cold/hot water outlet line.

In addition, the control unit drains cold or hot water flowing through the cold or hot water outlet line, which is cooled or heated by the thermoelectric module while flowing in the first flow space, through the water outlet drain line, and controls the temperature of the cold water or hot water discharged through the cold or hot water outlet line. can be adjusted

Further, if the temperature of the cold or hot water flowing through the cold/hot water outlet line being cooled or heated by the thermoelectric module while flowing in the first flow space is below a predetermined minimum temperature or above a predetermined maximum temperature, the controller controls the thermoelectric module for a predetermined period of time. Voltage may not be applied.

Also, if the hot water mode is not re-inputted to the input unit for a predetermined time after the hot water mode is terminated, the controller may switch to the cold water mode.

After switching to the cold water mode, the controller may supply and flow water to the first flow space for a predetermined time so that the hot water remaining in the first flow space is drained through the water outlet drain line.

In addition, when the hot water mode is input to the input unit within a predetermined time after the end of the cold water mode, the control unit allows water to be supplied and flowed in the first flow space for a predetermined time so that the cold water remaining in the first flow space is drained through the water outlet drain line. can do.

A water treatment device according to an embodiment of the present invention includes a filtering unit including a water filter for filtering inflow water; and the aforementioned instantaneous hot/cold water dispenser connected to the filtering unit; can include

In this case, one side of the filtering unit is connected to a raw water supply line to which a radiating cooling water supply line connected to one side of the second flow space formed in the radiating cooling unit is connected, and the other side of the filtering unit is connected to the first flow space formed in the instantaneous cold and hot water unit. It may be connected to the cold and hot water intake line and the purified water line connected to one side.

In addition, the hot/cold water outlet line and the purified water line connected to the other side of the first flow space may be connected to the water outlet member.

As described above, according to an embodiment of the present invention, cold water or hot water can be instantaneously made and supplied to a user with one thermoelectric module.

In addition, miniaturization and energy saving of the device may be possible.

Also, according to an embodiment of the present invention, malfunction of the thermoelectric module can be minimized.

1 is a view showing a first embodiment of an instantaneous hot/cold water dispenser and a water treatment device including the same according to the present invention.
2 to 8 are views showing the operation of the first embodiment of the instantaneous hot/cold water dispenser and the water treatment device including the same according to the present invention.
9 is a view showing a second embodiment of an instantaneous hot/cold water dispenser and a water treatment device including the same according to the present invention.
10 is a view showing a third embodiment of an instantaneous hot/cold water dispenser and a water treatment device including the same according to the present invention.

In order to help the understanding of the features of the present invention as described above, an instant hot/cold water dispenser and a water treatment device including the instant hot/cold water dispenser related to an embodiment of the present invention will be described in more detail.

The embodiments described below will be described based on the most suitable embodiments for understanding the technical characteristics of the present invention, and the technical characteristics of the present invention are not limited by the described embodiments, but the following It is to illustrate that the present invention can be implemented like the embodiments. Therefore, the present invention can be implemented with various modifications within the technical scope of the present invention through the embodiments described below, and these modified embodiments will be said to fall within the technical scope of the present invention. In addition, in the reference numerals described in the accompanying drawings to help understanding of the embodiments described below, among components that perform the same action in each embodiment, related components are indicated by the same or extended numbers.

[First Embodiment of Instantaneous Water Cooler and Heater and Water Treatment Device]

Hereinafter, with reference to FIGS. 1 to 8, a first embodiment of an instantaneous hot/cold water dispenser and a water treatment device including the same according to the present invention will be described.

1 is a view showing a first embodiment of an instantaneous hot and cold water dispenser and a water treatment device including the same according to the present invention, and FIGS. It is a drawing that represents

instantaneous water heater

As shown in FIG. 1, the first embodiment of the instantaneous water heater 100 according to the present invention includes an instantaneous hot/cold water unit 200, a thermoelectric module 300, a radiation cooling unit 400, and a control unit 500. can

As shown in FIG. 1 , a first flow space S1 through which water flows may be formed in the instantaneous cold and hot water unit 200 . The shape and configuration of the first flow space S1 are not particularly limited, and any shape or configuration, such as a tubular or zigzag flow path, is possible as long as the shape and configuration allow water to flow.

As shown in FIG. 1, the instantaneous cold and hot water unit 200 includes a cold/hot water intake line LI1 connected to one side of the first flow space S1 and a cold/hot outlet water line LO connected to the other side of the first flow space S2. ) can be connected.

A filtering unit 20 included in the first embodiment of the water treatment device 10 according to the present invention, which will be described later, may be connected to the hot and cold water intake line LI1. In addition, a water outlet member 600 such as a cock or a faucet may be connected to the cold/hot water outlet line LO. In addition, a water outlet drain line LD2 connected to a radiant cooling drain line LD1 connected to the other side of a second flow space S2 formed in the radiating cooling unit 400 and connected to the other side is connected to the hot/cold water outlet line LO. can

As shown in FIG. 1, a first flow rate sensor SF1, a first supply valve VF1, a flow control valve VC, and an inlet temperature sensor T1 may be provided in the cold/hot water intake line LI1.

The first flow sensor SF1 is not directly provided in the hot and cold water intake line LI1, but is connected to the connection line LC connected to the hot and cold water intake line LI1 as shown in FIG. may be available

The first supply valve VF1, the flow control valve VC, and the water temperature sensor T1 may be integrally formed. However, it is not particularly limited and may be made separately. In addition, the configuration in which the first supply valve VF1, the flow control valve VC, and the water temperature sensor T1 are integrally formed is not particularly limited, and any well-known configuration is possible as long as they are integrally formed.

As shown in FIG. 1, the cold/hot water outlet line LO may include a water outlet temperature sensor T2 and a flow path switching valve VS to which the aforementioned water outlet drain line LD2 is connected.

The above-described first flow sensor (SF1), first supply valve (VF1), flow control valve (VC), inlet temperature sensor (T1), outlet temperature sensor (T2), and flow path switching valve (VS) control unit ( 500) can be electrically connected.

Accordingly, when the first supply valve VF1 and the flow control valve VC are opened by the control unit 500, for example, water filtered by the filtering unit 20, that is, purified water flows through the cold and hot water intake line LI1, and instantly It is supplied to the first flow space (S1) of the cold and hot water unit 200 and may flow in the first flow space (S1).

At this time, the flow rate of the water flowing through the hot and cold water intake line LI1 is measured by the first flow rate sensor SF1, and the temperature of the water flowing through the hot and cold water intake line LI1 is measured by the water temperature sensor T1, and the controller (500).

In addition, the control unit 500 may adjust the flow rate of water flowing through the hot/cold intake line LI1 through the first flow sensor SF1 and the flow control valve VC.

The water flowing in the first flow space S1 of the instantaneous cold/hot water unit 200 may be cooled or heated by the thermoelectric module 300 to become cold water or hot water.

The cold water or hot water produced in this way flows through the cold and hot water outlet line LO by operating the flow path switching valve VS by the control unit 500, and is discharged to the outside through the water outlet member 600 to be supplied to the user.

In addition, water that is not cooled or heated by the thermoelectric module 300 while flowing in the first flow space S1 of the instantaneous cold/hot water unit 200, or cold water or hot water produced by being cooled or heated by the thermoelectric module 300 , It can flow into the water outlet drain line LD2 through the cold and hot water outlet line LO by operating the flow path switching valve VS by the control unit 500.

In this way, the water, cold water, or hot water that has not been cooled or heated by the thermoelectric module 300 introduced into the water outlet drain line LD2 is discharged to the outside through the water outlet drain line LD2 and the radiating cooling drain line LD1. can be drained

At this time, the temperature of cooled or unheated water or cold water or hot water flowing through the cold/hot water outlet line LO by the outlet temperature sensor T2 may be measured by the thermoelectric module 300 and transmitted to the control unit 500. there is.

As shown in FIG. 1 , the thermoelectric module 300 may be connected to the instantaneous cold/hot water unit 200 . In addition, when a voltage is applied to the thermoelectric module 300, heat can be transferred from one side to the other side.

The configuration of the thermoelectric module 300 is not particularly limited, and any well-known configuration is possible as long as it is a configuration in which heat is transferred from one side to the other side when a voltage is applied.

The thermoelectric module 300 is electrically connected to the controller 500, and a voltage, for example, a positive voltage or a reverse voltage, may be applied by the controller 500.

The cooling side CS of the thermoelectric module 300, which is cooled when a constant voltage is applied, may be connected to the instantaneous cold/hot water unit 200, and the heat radiation cooling unit 400 may be connected to the heating side HS, which is heated when a constant voltage is applied.

Accordingly, when a positive voltage is applied to the thermoelectric module 300, the water flowing in the first flow space S1 of the cold/hot water unit 200 is cooled to become cold water, and when a reverse voltage is applied to the thermoelectric module 300, the water flowing in the first flow space S1 of the hot/cold water unit 200 is instantly cooled. Water flowing in the first flow space S1 of the cold/hot water unit 200 may be heated to become hot water.

However, it is not particularly limited, and the heating side (HS) of the thermoelectric module 300, which is heated when a constant voltage is applied, is connected to the instantaneous cold and hot water unit 200 and is connected to the cooling side (CS) of the thermoelectric module 300, which is cooled when a constant voltage is applied. A heat dissipation cooling unit 400 may be connected.

In this case, when a positive voltage is applied to the thermoelectric module 300, the water flowing in the first flow space S1 of the hot and cold water unit 200 is instantly heated to become hot water, and when a reverse voltage is applied to the thermoelectric module 300, Water flowing in the first flow space S1 of the instantaneous cold and hot water unit 200 may be cooled to become cold water.

Meanwhile, the configuration in which the thermoelectric module 300 is connected to the instantaneous cold/hot water unit 200 so that the water flowing in the first flow space S1 is cooled or heated according to the voltage applied to the thermoelectric module 300 is not particularly limited. don't

In this configuration, for example, the cooling side (CS) or heating side (HS) of the thermoelectric module 300 directly contacts water flowing in the first flow space (S1) or through another heat transfer member (not shown). Any well-known configuration such as indirect contact with water flowing in the flow space (S1) is possible.

As shown in FIG. 1 , the heat dissipation cooling unit 400 may be connected to the thermoelectric module 300 to cool the thermoelectric module 300 or be cooled by the thermoelectric module 300 .

Water may flow through the heat dissipation cooling unit 400 to cool the thermoelectric module 300 or may be cooled by the thermoelectric module 300 .

For example, the heat dissipation cooling unit 400 cools the heating side HS of the thermoelectric module 300 when a positive voltage is applied to the thermoelectric module 300 by the flow of water or the heating side when a reverse voltage is applied to the thermoelectric module 300 . (HS).

In this case, the cooling side (CS) of the thermoelectric module 300, which is cooled when a constant voltage is applied, is connected to the instantaneous cold/hot water unit 200, and the heating side (HS) of the thermoelectric module 300, which is heated when a constant voltage is applied, has a radiating cooling unit ( 400) is connected.

However, as described above, the heating side (HS) of the thermoelectric module 300, which is heated when a constant voltage is applied, is connected to the instantaneous cold and hot water unit 200, and heat is radiated to the cooling side (CS) of the thermoelectric module 300, which is cooled when a constant voltage is applied. A cooling unit 400 may be connected.

In this case, the heat dissipation cooling unit 400 is cooled by the cooling side CS of the thermoelectric module 300 when the positive voltage is applied to the thermoelectric module 300 by the flow of water, or when the reverse voltage is applied to the thermoelectric module 300. The cooling side CS of the thermoelectric module 300 may be cooled.

In addition, the heat dissipation cooling unit 400 may cool the thermoelectric module 300 by air flow or be cooled by the thermoelectric module 300 .

As shown in FIG. 1 , a second flow space S2 through which water flows may be formed in the heat dissipation cooling unit 400 . The shape and configuration of the second flow space S2 is not particularly limited, and any shape such as a tubular or zigzag flow path is possible as long as the shape and configuration allow water to flow.

As shown in FIG. 1, the radiating cooling unit 400 has a radiating cooling intake line LI2 connected to one side of the second flow space S2 and a radiating cooling drain line connected to the other side of the second flow space S2. (LD1) may be connected.

The heat dissipation cooling acquisition line (LI2) may be connected to a raw water supply line (LS) connected to a raw water supply source (not shown) such as tap water.

As shown in FIG. 1, a second flow rate sensor SF2 and a second supply valve VF2 may be provided in the heat dissipation cooling water supply line LI2. The second flow sensor SF2 and the second supply valve VF2 may be integrally formed.

However, it is not particularly limited and may be made separately. In addition, the configuration in which the second flow sensor SF2 and the second supply valve VF2 are integrally formed is not particularly limited, and any well-known configuration is possible as long as they are integrally formed.

The second supply valve VF2 may be configured to open and close the passage by moving or rotating the opening and closing plate. Accordingly, it is possible to supply water by controlling the flow rate more precisely than in a configuration in which the flow path is opened and closed by movement of a plunger (not shown).

As shown in FIG. 1 , a drain temperature sensor T3 may be provided on the heat dissipation cooling drain line LD1.

The aforementioned second flow sensor SF2, second supply valve VF2, and drain temperature sensor T3 may be electrically connected to the controller 500.

Accordingly, when the second supply valve (VF2) is opened by the control unit 500, the water of the raw water supply source, that is, the raw water flows through the radiant cooling acquisition line (LI2) through the raw water supply line (LS), thereby cooling the radiant cooling unit (400). is introduced into the second flow space (S2) of and can flow through the second flow space (S2).

At this time, the flow rate of the water flowing through the heat dissipation cooling acquisition line LI2 may be measured by the second flow rate sensor SF2 and transmitted to the control unit 500 .

The water flowing in the second flow space S2 of the radiating cooling unit 400 may cool the thermoelectric module 300 or be cooled by the thermoelectric module 300 and drained to the outside through the radiating cooling drain line LD1. there is.

At this time, the temperature of the water flowing through the heat dissipation cooling drain line LD1 may be measured by the drain temperature sensor T3 and transmitted to the control unit 500 .

As described above, the water outlet drain line LD2 is connected to the radiating cooling drain line LD1, and water, cold water, or hot water that is not cooled or heated by the thermoelectric module 300 flows into the water outlet drain line LD2. It can flow and drain to the outside.

On the other hand, the radiating cooling unit 400, for example, the radiating cooling unit 400 so that water flows in the second flow space S2 of the radiating cooling unit 400 to heat the thermoelectric module 300 or to be cooled by the thermoelectric module 300 ( 400) connected to the thermoelectric module 300 is not particularly limited.

In this configuration, water flowing in the second flow space S2 of the heat dissipation cooling unit 400 is in direct contact with, for example, the heating side HS or the cooling side CS of the thermoelectric module 300 or other heat transfer members ( Any well-known configuration such as indirect contact with the heating side (HS) or cooling side (CS) of the thermoelectric module 300 through (not shown) is possible.

The control unit 500 applies a positive voltage or a reverse voltage to the thermoelectric module 300 so that water flowing in the first flow space S1 of the instantaneous cold and hot water unit 200 is instantaneously cooled or heated by the thermoelectric module 300. It can be either cold or hot water.

Therefore, cold water or hot water can be instantaneously made with one thermoelectric module 300 . Accordingly, the instantaneous water heater 100 and the water treatment device 10 including the same can be miniaturized, and energy used to produce cold water and hot water can be reduced.

The controller 500 may include an input unit 510 . Through the input unit 510 of the control unit 500, the user can select and input a cold water mode in which cold water is produced or a hot water mode in which hot water is produced in the instantaneous cold and hot water unit 200.

When the cold water mode or the hot water mode is input to the input unit 510, the controller 500 may first supply and flow water into the second flow space S2 of the radiating cooling unit 400 as shown in FIG. there is.

For example, the control unit 500 may open the second supply valve VF2 of the heat dissipation cooling water supply line LI2 when the cold water mode or the hot water mode is input to the input unit 510 .

By this, for example, the water of the raw water supply source, that is, the raw water is introduced into the second flow space S2 of the radiant cooling unit 400 through the raw water supply line LS and the radiant cooling inlet line LI2, and the second flow space ( S2) may be drained to the outside through the heat dissipation cooling drain line LD1.

The flow of water in the second flow space S2 of the radiating cooling unit 400 may continue until the cold water mode or the hot water mode ends.

In this way, since water is first allowed to flow in the second flow space S2 of the heat dissipation cooling unit 400, the thermoelectric module 300 can be easily maintained within the operating temperature range, so that the thermoelectric module 300 Malfunctions can be minimized.

After allowing water to flow in the second flow space S2 of the heat dissipation cooling unit 400 , the controller 500 may apply a voltage to the thermoelectric module 300 .

For example, the controller 500 may apply a positive voltage to the thermoelectric module 300 in the cold water mode and apply a reverse voltage to the thermoelectric module 300 in the hot water mode.

In this case, the cooling side (CS) of the thermoelectric module 300, which is cooled when a constant voltage is applied, is connected to the instantaneous cold and hot water unit 200, and the heating side (HS) of the thermoelectric module 300, which is heated when a constant voltage is applied, is a radiating cooling unit ( 400) is connected.

In addition, as described above, the heating side (HS) of the thermoelectric module 300, which is heated when a constant voltage is applied, is connected to the instantaneous cold and hot water unit 200, and heat is radiated to the cooling side (CS) of the thermoelectric module 300, which is cooled when a constant voltage is applied. A cooling unit 400 may be connected.

Also, in this case, the controller 500 may apply a reverse voltage to the thermoelectric module 300 in the cold water mode, and may apply a positive voltage to the thermoelectric module 300 in the hot water mode.

Along with or after applying the voltage to the thermoelectric module 300, the control unit 500 supplies water to the first flow space S1 of the hot/cold water unit 200 as shown in FIG. can make it

For example, the control unit 500 opens the first supply valve VF1 and the flow control valve VC of the cold and hot water intake line LI1, so that the water filtered in the filtering unit 20, that is, purified water, is supplied to the cold and hot water intake line LI1. ) is supplied to the first flow space S1 of the instantaneous cold and hot water unit 200 so as to flow in the first flow space S1.

In this way, while flowing in the first flow space S1 of the instantaneous cold and hot water unit 200, the water may be cooled or heated by the thermoelectric module 300 to become cold water or hot water.

And, as shown in FIG. 3, the control unit 500 operates the flow path switching valve VS so that cold or hot water flows through the cold and hot water outlet line LO and is discharged to the outside through the water outlet member 600 to be supplied to the user. can be made

Meanwhile, when one of the cold water mode and the hot water mode is input to the input unit 510 of the controller 500 for the first time, the controller 500, before applying a voltage to the thermoelectric module 300, as shown in FIG. Likewise, a predetermined amount of water may be supplied and flowed not only to the second flow space S2 of the heat dissipation cooling unit 400 but also to the first flow space S1 of the instantaneous cold and hot water unit 200 .

For example, when one of the cold water mode and the hot water mode is input for the first time, the control unit 500 controls the first supply valve VF1 of the cold/hot water intake line LI1 together with the second supply valve VF2 of the heat radiation/cooling water intake line LI2. ) and the flow control valve (VC) can be opened.

Accordingly, water may be supplied and flowed not only in the second flow space S2 of the radiating cooling unit 400 but also in the first flow space S1 of the instantaneous cold and hot water unit 200 .

As such, the water flowing in the first flow space S1 of the instantaneous cold and hot water unit 200 flows through the cold and hot water outlet line LO as shown in FIG. The excess water may be discharged to the outside through the water extraction member 600, or may be drained to the outside through the hot and cold water extraction line LO, the water extraction drain line LD2, and the heat dissipation cooling drain line LD1.

When a predetermined amount of water, for example, about 150 ml of water is supplied to the first flow space S1 of the instantaneous cold and hot water unit 200 by the first flow sensor SF1, and the flow is measured and transmitted to the control unit 500, The control unit 500 may close the first supply valve VF1 and the flow control valve VC of the cold/hot water intake line LI1.

Accordingly, water continues to flow in the second flow space S2 of the radiating cooling unit 400, and only a predetermined amount of water flows in the first flow space S1 of the instantaneous cold and hot water unit 200 so as to contain water. do.

Accordingly, even when one of the cold water mode and the hot water mode is input to the input unit 510 of the control unit 500 for the first time, the first space ( S1) is not empty and may contain water.

Accordingly, it is possible to easily keep the thermoelectric module 300 within an operating temperature range, thereby minimizing malfunction of the thermoelectric module 300 .

Meanwhile, the control unit 500 applies a voltage to the thermoelectric module 300 only when water is supplied and flows in the second flow space S2 of the heating/cooling unit 400, and the water flows in the second flow space S2. When it is supplied and does not flow, voltage may not be applied to the thermoelectric module 300 .

For example, the control unit 500 applies a voltage to the thermoelectric module 300 only when the flow rate of water flowing through the heat dissipation cooling water supply line LI2 is measured and transmitted by the second flow rate sensor SF2, and otherwise, The controller 500 may not apply voltage to the thermoelectric module 300 .

This is not only before the cold water mode or hot water mode is input to the input unit 510 and the voltage is applied to the thermoelectric module 300, but also after the voltage is applied to the thermoelectric module 300 and the first flow space of the cold/hot water unit 200 instantaneously. It can also be applied to the case where water flows in (S1) and is cooled or heated by the thermoelectric module 300.

Accordingly, it is possible to easily keep the thermoelectric module 300 within the operating temperature range, thereby minimizing malfunction of the thermoelectric module 300 .

On the other hand, the temperature of the water flowing through the radiant cooling drain line LD1 after flowing in the second flow space S2 of the radiative cooling unit 400 is equal to or higher than a predetermined abnormal heating temperature in the cold water mode or a predetermined abnormal temperature in the hot water mode. When the temperature is lower than the cooling temperature, the controller 500 may cut off power and stop the entire operation.

For example, the temperature of the water flowing through the radiating cooling drain line LD1 measured by the drain temperature sensor T3 is a predetermined abnormal heating temperature in the cold water mode, for example, 45 ° C. or higher, or a predetermined abnormal cooling temperature in the hot water mode, for example When the temperature is below 5° C., the control unit 500 may cut off power and stop the entire operation.

After flowing in the second flow space S2 of the radiating cooling unit 400, the temperature of the water flowing through the radiating cooling drain line LD1 reaches a predetermined ideal heating temperature in the cold water mode or a predetermined abnormal cooling temperature in the hot water mode. The following may mean that the thermoelectric module 300 is malfunctioning.

Therefore, the controller 500 cuts off the power of the water dispenser 100 and stops the entire operation, thereby protecting the water dispenser 100 including the thermoelectric module 300 from malfunction.

In addition, after examining whether the thermoelectric module 300 is malfunctioning, if it is malfunctioning, the thermoelectric module 300 may be repaired or replaced.

On the other hand, when water is supplied to and flowing in the first flow space S1 of the instantaneous cold and hot water unit 200, the temperature difference between the water in the cold and hot water intake line LI1 and the water in the cold and hot water outlet line LO may be greater than or equal to a predetermined temperature difference.

In this case, hot water or cold water remains in the first flow space S1 of the instantaneous cold/hot water unit 200 immediately after switching from the hot water mode to the cold water mode or from the cold water mode to the hot water mode.

In this state, it is not easy to cool or heat the water flowing in the first flow space S1 of the instantaneous cold/hot water unit 200 by the thermoelectric module 300 to make cold water or hot water at a predetermined target temperature. A lot of energy is consumed in the thermoelectric module 300 .

In this case, as shown in FIG. 5, the control unit 500 remains in the first flow space S1 until the temperature difference between the water in the cold and hot water intake line LI1 and the water in the cold and hot water outlet line LO becomes less than a predetermined temperature difference. Existing water, for example hot water or cold water, may be drained through the water outlet drain line LD2.

As a result, cold water or hot water at a predetermined target temperature can be made relatively easily and quickly, and relatively little energy can be consumed in the thermoelectric module 300 .

For example, when water is supplied to and flowing in the first flow space S1 of the instantaneous cold and hot water unit 200, the water in the cold and hot water intake line LI1 measured by the inlet temperature sensor T1 and the water outlet temperature sensor T2 The temperature difference between the water in the cold and hot water outlet line LO, measured by , may be, for example, 5°C or more.

In this case, the control unit 500 operates the flow path switching valve VS until the temperature difference between the water in the cold and hot water intake line LI1 and the water in the cold and hot water outlet line LO, for example, is less than 5 ° C. 200), the water remaining in the first flow space S1 may be drained through the water outlet drain line LD2.

On the other hand, the control unit 500 controls the control unit 500 only after the water supplied to the first flow space S1 of the instantaneous cold/hot water unit 200 is cooled or heated by the thermoelectric module 300 to become cold water or hot water at a predetermined preliminary temperature. While water is continuously supplied to the first flow space S1, cold water or hot water can be discharged through the cold/hot water outlet line LO.

For example, in the cold water mode, the controller ( 500) may continuously supply water to the first flow space S1.

In addition, the control unit 500 may operate the flow path switching valve VS so that the cold water is discharged to the outside through the cold and hot water outlet line LO and the water outlet valve 600 and is supplied to the user.

In addition, in the hot water mode, the controller ( 500) may continuously supply water to the first flow space S1.

In addition, the control unit 500 may operate the flow path switching valve VS to allow hot water to be discharged to the outside through the hot and cold water outlet line LO and the water outlet valve 600 and supplied to the user.

The temperature of the cold or hot water supplied to the first flow space S1 of the instantaneous cold and hot water unit 200 and cooled or heated by the thermoelectric module 300 is measured by the inlet temperature sensor T1 in the cold and hot water intake line LI1 It can be estimated from at least one of the temperature of and the temperature of the hot and cold water outlet line LO measured by the outlet temperature sensor T2.

However, the temperature of the cold or hot water produced by the instantaneous cold and hot water unit 200 may be directly measured by a separate temperature sensor (not shown) connected to the first flow space S1 of the instantaneous cold and hot water unit 200.

The control unit 500 adjusts the flow rate of water flowing into the first flow space S1 of the instantaneous cold and hot water unit 200 through the cold and hot water intake line LI1 and discharges it through the cold and hot water outlet line LO and the water outlet valve 600. The temperature of the cold water or hot water may be within a desired target temperature range.

For example, the control unit 500 controls the flow rate of water introduced into the first flow space S1 of the instantaneous cold and hot water unit 200 through the cold and hot water intake line LI1 by the first flow sensor SF1 and the flow control valve VC. can be adjusted.

In addition, the temperature of cold or hot water discharged through the cold/hot water outlet line LO and the water outlet valve 600, measured by the outlet temperature sensor T2, is within a desired target temperature range, for example, 5°C to 8°C or It may be within 75°C to 80°C.

In addition, as shown in FIG. 6, the control unit 500 controls the cold water or hot water of the cold and hot water outlet line LO to the outlet drain line until the temperature of the cold or hot water of the cold and hot water outlet line LO is within the predetermined target temperature range. It can be drained through (LD2).

For example, if the temperature of cold or hot water in the cold and hot water outlet line LO measured by the outlet temperature sensor T2 is not within the desired target temperature range of 5°C to 8°C or 75°C to 80°C, the control unit 500 ) may operate the passage switching valve VS to drain cold or hot water from the cold/hot water outlet line LO through the outlet drain line LD2 and the radiating/cooling drain line LD1.

And, if the temperature of the cold or hot water in the cold/hot water outlet line LO is within the desired target temperature range of 5°C to 8°C or 75°C to 80°C, the control unit 500 operates the flow path switching valve VS to Cold water or hot water from the cold/hot water outlet line LO may be discharged to the outside through the water outlet member 600 and supplied to the user.

On the other hand, the controller 500 adjusts the flow rate of water supplied to the first flow space S1 of the instantaneous cold and hot water unit 200 through the cold and hot water intake line LI1 to cool or heat the water by the thermoelectric module 300, thereby dispensing cold and hot water. The temperature of the cold water or hot water discharged through the line LO can be adjusted.

For example, in the cold water mode, the user may select and input a target temperature of 5°C, 8°C, or 11°C of cold water through the input unit 510 of the controller 500.

Further, the control unit 500 controls the flow rate of water supplied to the first flow space S1 through the cold and hot water intake line LI1 by the first flow sensor SF1 and the flow control valve VC to be 0.4LPM (Liter Per Per Minute) or 0.45LPM or 0.55LPM.

Accordingly, the temperature of the cold water discharged through the cold and hot water outlet line LO and the water outlet member 600 and supplied to the user can be adjusted to the target temperature input through the input unit 510 .

In this case, power applied to the thermoelectric module 300 by the controller 500 may be constant, for example, 1 kW.

Also, in the hot water mode, a target temperature of 60° C., 70° C., or 80° C. may be selected and inputted to the user through the input unit 510 of the controller 500.

In addition, the control unit 500 controls the flow rate of water supplied to the first flow space S1 through the cold and hot water intake line LI1 by the first flow sensor SF1 and the flow control valve VC to be 0.65 LPM (Liter Per Per Minute) or 0.6LPM or 0.55LPM.

Accordingly, the temperature of hot water discharged through the cold/hot water outlet line LO and the water outlet member 600 and supplied to the user may be adjusted to a target temperature input through the input unit 510 .

In this case, power applied to the thermoelectric module 300 by the control unit 500 may be constant, for example, 2.2 kW.

In addition, the controller 500 discharges cold or hot water cooled or heated by the thermoelectric module 300 and flowing through the cold/hot water outlet line LO while flowing in the first flow space S1 of the instantaneous cold/hot water unit 200. It is possible to adjust the temperature of cold or hot water drained through the line LD2 and discharged through the cold/hot water outlet line LO.

For example, the controller 500 operates the flow path switching valve VS until the temperature of cold or hot water in the cold/hot water outlet line LO measured by the outlet temperature sensor T2 reaches the target temperature input to the input unit 510. Thus, cold water or hot water may be drained to the outside through the water outlet drain line LD2 and the heat dissipation cooling drain line LD1.

In addition, when the temperature of the cold or hot water of the cold/hot water outlet line LO measured by the outlet temperature sensor T2 reaches the target temperature input to the input unit 510, the control unit 500 operates the flow path switching valve VS to provide cold water Alternatively, hot water may be drained to the outside through the water outlet member 600 and supplied to the user.

In addition, the control unit 500 adjusts the power applied to the thermoelectric module 300 so that the hot/cold water is cooled or heated by the thermoelectric module 300 while flowing in the first flow space S1 of the hot/cold water unit 200, and cold/hot water is discharged. The temperature of cold water or hot water flowing through the line LO may be adjusted.

Meanwhile, the temperature of the cold or hot water flowing in the cold/hot water outlet line L0 after being cooled or heated by the thermoelectric module 300 while flowing in the first flow space S1 of the instantaneous cold/hot water unit 200 is below a predetermined minimum temperature. or higher than the predetermined maximum temperature, the controller 500 may not apply a voltage to the thermoelectric module 300 for a predetermined period of time.

For example, in the cold water mode, if the temperature of the cold water in the cold and hot water outlet line LO measured by the outlet temperature sensor T2 is 2°C or less, the controller 500 does not apply a voltage to the thermoelectric module 300 for 500 milliseconds. Alternatively, if the temperature of the cold water in the cold/hot water outlet line LO is 0.5° C. or less, the controller 500 may not apply a voltage to the thermoelectric module 300 for 2 seconds.

Accordingly, it is possible to prevent water flowing in the first flow space S1 of the instantaneous cold and hot water unit 200 from being excessively cooled by the thermoelectric module 300 in the cold water mode.

In addition, when the hot water temperature of the hot and cold water outlet line LO measured by the outlet temperature sensor T2 in the hot water mode is 93° C. or higher, the controller 500 does not apply a voltage to the thermoelectric module 300 for 500 milliseconds. Alternatively, if the temperature of hot water in the cold/hot water outlet line LO is 96° C. or higher, the controller 500 may not apply a voltage to the thermoelectric module 300 for 2 seconds.

Accordingly, it is possible to prevent water flowing in the first flow space S1 of the instantaneous cold and hot water unit 200 from being excessively heated by the thermoelectric module 300 in the hot water mode.

Meanwhile, if the hot water mode is not input to the input unit 510 of the controller 500 for a predetermined time after the hot water mode ends, the controller 500 may switch to the cold water mode.

For example, if the hot water mode is not input to the input unit 510 within 10 seconds after the hot water mode ends, the controller 500 may switch to the cold water mode.

The temperature of the water introduced into the first flow space S1 of the instantaneous cold and hot water unit 200 through the hot and cold water intake line LI1 may be, for example, approximately 15°C.

In the cold water mode, the temperature of the cold water cooled by the thermoelectric module 300 while flowing in the first flow space S1 of the instantaneous cold and hot water unit 200 is, for example, about 5° C., and in the hot water mode, the instantaneous cold and hot water unit ( The temperature of the hot water heated by the thermoelectric module 300 while flowing in the first flow space S1 of 200 may be, for example, approximately 70°C.

Accordingly, more power must be applied to the thermoelectric module 300 in the hot water mode than in the cold water mode, whereby more load is applied to the thermoelectric module 300 in the hot water mode than in the cold water mode.

Therefore, if the hot water mode is continuously maintained despite not using hot water, the thermoelectric module 300 may be overloaded and the thermoelectric module 300 may malfunction or not operate.

Accordingly, as described above, if the hot water mode is not input to the input unit 510 of the controller 500 for a predetermined time after the hot water mode is terminated, the controller 500 switches to the cold water mode. ) can be prevented from malfunctioning or not working.

In addition, since the controller 500 is switched to the cold water mode, when the user wants cold water, cold water can be relatively quickly made and supplied to the user.

After switching to the cold water mode, the control unit 500, as shown in FIG. 7 , supplies and flows water in the first flow space S1 of the instantaneous cold and hot water unit 200 for a predetermined period of time, so that the first flow space S1 The hot water remaining in may be drained through the outlet drain line LD2.

For example, after switching to the cold water mode, the control unit 500 may open the first supply valve VF1 and the flow control valve VC and operate the flow path switching valve VS.

Accordingly, water is supplied and flows through the cold/hot water inlet line LI1 to the first flow space S1 of the instantaneous cold/hot water unit 200, and together with the hot water remaining in the first flow space S1, the cold/hot outlet water line L0 ) and through the water outlet drain line LD2 and the heat dissipation cooling drain line LD1.

Then, after a predetermined time, for example, after 2 to 3 seconds, the control unit 500 may close the first supply valve VF1 and the flow control valve VC and operate the flow path switching valve VS.

Accordingly, in the cold water mode or the hot water mode, the water flowing in the first flow space S1 of the instantaneous cold/hot water unit 200 can be relatively easily and rapidly cooled or heated by the thermoelectric module 300 .

When the hot water mode is input to the input unit 510 of the controller 500 within a predetermined time after the end of the cold water mode, the controller 500 enters the first flow space S1 of the instantaneous cold and hot water unit 200 as shown in FIG. Water may be supplied and flowed for a predetermined time so that the cold water remaining in the first flow space S1 is drained through the water outlet drain line LD2.

For example, when the hot water mode is input to the input unit 510 within 10 seconds after the end of the cold water mode, the control unit 500 may open the first supply valve VF1 and the flow control valve VC and operate the flow path switching valve VS. there is.

Accordingly, water is supplied and flows through the cold and hot water inlet line LI1 to the first flow space S1 of the instantaneous cold and hot water unit 200, and together with the cold water remaining in the first flow space S1, the cold and hot water outlet line L0 ), and may be drained to the outside through the water outlet drain line LD2 and the heat dissipation cooling drain line LD1.

Then, after a predetermined time, for example, after 2 to 3 seconds, the control unit 500 may close the first supply valve VF1 and the flow control valve VC and operate the flow path switching valve VS.

Accordingly, the water flowing in the first flow space S1 of the instantaneous cold and hot water unit 200 can be heated relatively easily and quickly by the thermoelectric module 300 .

water treatment device

As shown in FIG. 1 , the first embodiment of the water treatment device according to the present invention may include a filtering unit 20 and the above-described instantaneous water heater 100 connected to the filtering unit 20 .

Since the instantaneous water heater 100 has been described above, only the filtering unit 20 will be described below.

The filtering unit 20 may include water filters 21 and 22 filtering the inflow water. The filtering unit 20 may include, for example, two water filters 21 and 22 . Also, the two water filters 21 and 22 may be connected to each other by a connection line LC.

However, the number of water filters 21 and 22 included in the filtering unit 20 is not particularly limited and may be any number.

As shown in FIG. 1 , one side of the filtering unit 20 may be connected to the raw water supply line LS to which the radiating cooling water supply line LI2 of the instantaneous cold or hot water dispenser 100 is connected.

For example, one side of the connection line LC connecting the above-described two water filters 21 and 22 to each other may be connected to the raw water supply line LS.

In addition, as shown in FIG. 1 , the other side of the filtering unit 20 may be connected to the hot/cold water intake line LI1 and the purified water line LP of the instantaneous cold/hot water dispenser 100 .

For example, the other side of the connection line LC connecting the above-described two water purification filters 21 and 22 to each other may be connected to the hot/cold water intake line LI1 and the water purification line LP.

In addition, a pressure reducing valve (VPC) and a normal open valve (VNO) may be provided in the connection line (LC) at the front end of the two water filters (21, 22). In addition, a purified water supply valve VP is provided in the purified water line LP, and the purified water line LP can be connected to the water outlet member 600 to which the hot/cold water outlet line LO of the instantaneous cold/hot water dispenser 100 is connected.

Accordingly, when the first supply valve VF1 and the flow control valve VC or the purified water supply valve VP are opened by the control unit 500, the water of the raw water supply source, that is, the raw water is connected through the raw water supply line LS. After flowing into the line (LC) and reduced to a predetermined pressure by the pressure reducing valve (VPC), it can pass through the normal open valve (VNO) and be filtered by the water filters (21, 22) of the filtering unit (20).

In this way, water filtered by the water filters 21 and 22 of the filtering unit 20, that is, purified water may flow into the hot/cold water intake line LI1 or the water purification line LP through the connection line LC.

And, when the purified water supply valve VP is opened by the control unit 500, as shown in FIG. 8, the water filtered by the filtering unit 20, that is, purified water flows through the purified water line LP and 600) may be discharged to the outside and supplied to the user.

On the other hand, the normal open valve (VNO) is normally open but closed in an emergency to prevent water from a raw water supply source, that is, raw water from entering the water filter 21, 22 of the filtering unit 20, so that in an emergency, the instantaneous cold or hot water dispenser ( 100) to protect the water treatment device 10.

[Second Embodiment of Instantaneous Water Cooler and Heater and Water Treatment Device]

Hereinafter, with reference to FIG. 9, a second embodiment of an instantaneous hot/cold water dispenser and a water treatment device according to the present invention will be described.

9 is a view showing a second embodiment of an instantaneous hot/cold water dispenser and a water treatment device including the same according to the present invention.

Here, the second embodiment of the instantaneous hot and cold water dispenser and the water treatment device including the same according to the present invention is the instantaneous cold and hot water dispenser and the second embodiment of the water treatment device including the same according to the present invention described with reference to FIGS. 1 to 8. There is a difference in the configuration of the cold and hot water unit 200 and the radiation cooling unit 400.

Therefore, in the following, the differentiated configuration will be mainly described, and the remaining configurations can be replaced with those described with reference to FIGS. 1 to 8.

As shown in FIG. 9, at least one of the instantaneous hot/cold water unit 200 and the heat radiation cooling unit 400 of the second embodiment of the instant hot/cold water dispenser 100 according to the present invention and the water treatment device 10 including the same includes a malfunction preventing unit. (210, 410) may be provided.

The malfunction prevention units 210 and 410 may include, for example, a temperature sensor or a bimetal (not shown).

The malfunction prevention units 210 and 410 may be electrically connected to the control unit 500 .

When the malfunction prevention unit 210 or 410 includes a temperature sensor, the temperature sensor flows in the first flow space S1 of the instantaneous cold/hot water unit 200 or the second flow space S2 of the radiating cooling unit 400. The water temperature can be measured.

Further, the controller 500 controls the water treatment device 10 including the instantaneous water heater 100 when the temperature of the water flowing in the first and second flow spaces S1 and S2 measured by the temperature sensor is a predetermined abnormal temperature. can cut off the power and stop the entire operation.

In addition, even when the malfunction prevention units 210 and 410 include a bimetal, when the temperature of the water flowing in the first and second flow spaces S1 and S2 is above a predetermined temperature, the power is cut off by the bimetal and the entire operation is performed. this can be stopped

Accordingly, in case of a malfunction of the water treatment device 10 including the instantaneous water heater/cooler/heater 100, such as when the thermoelectric module 300 malfunctions, the instant water heater/heater 100 and the water treatment device 10 can be protected.

[Third Embodiment of Instantaneous Water Cooler and Heater and Water Treatment Device]

Hereinafter, with reference to FIG. 10, a third embodiment of an instant hot/cold water dispenser and a water treatment device according to the present invention will be described.

10 is a view showing a third embodiment of an instantaneous hot/cold water dispenser and a water treatment device including the same according to the present invention.

Here, the third embodiment of the instant cold and hot water dispenser and the water treatment device including the same according to the present invention is sterilized with the first embodiment of the instant cold and hot water dispenser and the water treatment device including the same according to the present invention described with reference to FIGS. 1 to 8 There is a difference in that the unit 700 is further included.

Therefore, in the following, the differentiated configuration will be mainly described, and the remaining configurations can be replaced with those described with reference to FIGS. 1 to 8.

As shown in FIG. 10 , the third embodiment of the instantaneous hot/cold water dispenser 100 and the water treatment device 10 including the instant water dispenser 100 according to the present invention may further include a sterilization unit 700 .

The sterilization unit 700 includes the first and second flow spaces S1 and S2, the cold and hot water intake line LI1, the cold and hot water outlet line LO, the radiating cooling water intake line LI2, and the radiating cooling drain line of the instantaneous cold and hot water dispenser 100. At least one of (LD1) and the water outlet drain line (LD2) may be sterilized.

In addition, the sterilization unit 700 may also sterilize the connection line LC and the water purification line LP of the filtering unit 20 .

The sterilization unit 700 may sterilize the above components by making, for example, sterilizing water.

In this case, the sterilization unit 700 may be provided in a sterilization line LST having one side and the other side respectively connected to the raw water supply line LS. In addition, a sterilization valve VST electrically connected to the control unit 500 may be provided in the sterilization line LST.

Accordingly, when the sterilization valve VST is opened by the control unit 500, water from the raw water supply source, that is, raw water flows into the sterilization unit 700 through the raw water supply line LS and the sterilization line LST to make sterilizing water. can lose

Thus, the sterilized water produced in the sterilization unit 700 returns to the raw water supply line LS and flows into the connection line LC of the filtration unit 20 or the heat radiation and cooling inlet line LI2 of the instantaneous water heater 100, The components described above can be sterilized.

In the sterilizing unit 700, sterilizing water may be made by, for example, electrolysis. However, a configuration in which sterilizing water is produced in the sterilizing unit 700, such as sterilizing water by introducing a sterilizing material, is not particularly limited.

In addition, the configuration and location of the sterilization unit 700 are not particularly limited, and any configuration and location capable of sterilizing the instantaneous water heater 100 according to the present invention described above and the components of the water treatment device 10 including the same can be sterilized by an ultraviolet lamp Any well-known configurations and locations are possible, including, but not limited to, the like.

As described above, if the instantaneous hot/cold water dispenser and the water treatment device including the same according to the present invention are used, cold water or hot water can be instantaneously produced and supplied to the user with one thermoelectric module, miniaturization of the device and energy saving can be achieved, and thermoelectric Malfunctions of the module can be minimized.

The instantaneous hot and cold water dispenser described above and the water treatment device including the same are not limitedly applicable to the configuration of the above-described embodiment, but all or part of each embodiment is selectively combined so that various modifications can be made. may be configured.

10: water treatment device 20: filtration unit
21: first water filter 22: second water filter
100: instantaneous cold and hot water dispenser 200: instantaneous cold and hot water unit
210, 410: malfunction prevention unit 300: thermoelectric module
400: heat dissipation cooling unit 500: control unit
510: input unit 600: water outlet member
700: sterilization unit S1: first flow space
S2: 2nd flow space CS: cooling side
HS: heating side LS: raw water supply line
LI1: Cold and hot water inlet line LO: Cold and hot water outlet line
LI2: radiant cooling intake line LD1: radiant cooling drain line
LD2: Outlet drain line LP: Water purification line
LST: sterilization line SF1: 1st flow sensor
SF2: 2nd flow sensor VF1: 1st supply valve
VC: flow control valve VS: flow control valve
VF2: 2nd supply valve VPC: pressure reducing valve
VNO: Normal open valve VP: Clean water supply valve
VST: Sterilization valve T1: Inlet temperature sensor
T2: Outlet water temperature sensor T3: Drain temperature sensor

Claims (28)

a cold/hot water unit in which a first flow space through which water flows is formed;
a thermoelectric module that is connected to the instantaneous cold and hot water unit and transfers heat from one side to the other side when a voltage is applied;
a heat dissipation cooling unit connected to the thermoelectric module to cool the thermoelectric module or to be cooled by the thermoelectric module;
a controller that applies a positive voltage or a reverse voltage to the thermoelectric module so that the water flowing in the first flow space is instantaneously cooled or heated by the thermoelectric module to become cold water or hot water; and
An instantaneous cold/hot water dispenser comprising a malfunction prevention unit including a temperature sensor or a bimetal to prevent malfunction in at least one of the instantaneous cold/hot water unit and the heat radiation cooling unit. The instantaneous water heater or heater of claim 1 , wherein a cooling side of the thermoelectric module that is cooled when a constant voltage is applied is connected to the instantaneous cold/hot water unit, and a heat radiation cooling unit is connected to a heating side of the thermoelectric module that is heated when a constant voltage is applied. The instantaneous water heater or water dispenser of claim 2, wherein water flows through the heat dissipation cooling part to cool the heating side when a positive voltage is applied to the thermoelectric module or to be cooled by the heating side when a reverse voltage is applied to the thermoelectric module. The hot/cold water dispenser according to claim 3, wherein a second flow space through which water flows is formed in the radiating cooling unit. The method of claim 4, wherein a cold/hot water intake line connected to one side of the first flow space and a cold/hot water outlet line connected to the other side of the first flow space are connected to the instantaneous cold/hot water unit,
The radiating cooling unit is connected to a radiating cooling water intake line connected to one side of the second flow space and a radiating cooling drain line connected to the other side of the second flow space. The hot/cold water dispenser according to claim 5, wherein a water outlet drain line connected to the radiation cooling drain line is connected to the cold/hot outlet line. The method of claim 6, wherein the cold and hot water intake line is provided with a first flow rate sensor, a first supply valve, a flow control valve, and an inlet temperature sensor,
A second flow rate sensor and a second supply valve are provided in the heat dissipation cooling water supply line,
The cold and hot water outlet line is provided with a water outlet temperature sensor and a flow path switching valve to which the outlet drain line is connected.
An instantaneous water heater or hot water dispenser in which a drain temperature sensor is provided in the heat dissipation cooling drain line. delete 7. The instantaneous water heater or heater of claim 6, further comprising a sterilization unit for sterilizing at least one of the first and second flow spaces, the cold/hot water inlet line, the cold/hot water outlet line, the radiant cooling water inlet line, the radiant cooling drain line, and the water outlet drain line. a cold/hot water unit in which a first flow space through which water flows is formed;
a thermoelectric module that is connected to the instantaneous cold and hot water unit and transfers heat from one side to the other side when a voltage is applied;
a heat dissipation cooling unit connected to the thermoelectric module to cool the thermoelectric module or to be cooled by the thermoelectric module;
a controller that applies a positive voltage or a reverse voltage to the thermoelectric module so that the water flowing in the first flow space is instantaneously cooled or heated by the thermoelectric module to become cold water or hot water;
Including,
The cooling side of the thermoelectric module, which is cooled when a constant voltage is applied, is connected to the instantaneous cold and hot water unit, and the heat dissipation cooling unit is connected to the heating side of the thermoelectric module, which is heated when a constant voltage is applied.
Water flows through the heat dissipation cooling unit to cool the heating side when a positive voltage is applied to the thermoelectric module or to be cooled by the heating side when a reverse voltage is applied to the thermoelectric module;
A second flow space in which water flows is formed in the heat dissipation cooling unit,
The instantaneous cold and hot water unit is connected to a cold and hot water intake line connected to one side of the first flow space and a cold and hot water outlet line connected to the other side of the first flow space,
The radiating cooling unit is connected to a radiating cooling water intake line connected to one side of the second flow space and a radiating cooling drain line connected to the other side of the second flow space,
The cold and hot water outlet line is connected to a water outlet drain line connected to the radiation cooling drain line,
Further comprising a sterilization unit for sterilizing at least one of the first and second flow spaces, cold and hot water intake lines, cold and hot water outlet lines, radiating cooling water intake lines, radiating cooling drain lines, and water outlet drain lines,
The sterilization unit makes sterilizing water and sterilizes it instantly. The method of claim 6, when a cold water mode for producing cold water or a hot water mode for producing hot water is input to the input unit included in the control unit,
The control unit first supplies and causes water to flow in the second flow space, then applies a voltage to the thermoelectric module, and supplies and causes water to flow in the first flow space. 12. The instantaneous water heater or heater of claim 11, wherein the control unit applies a positive voltage to the thermoelectric module in the cold water mode and applies a reverse voltage to the thermoelectric module in the hot water mode. The method of claim 12 , wherein when one of the cold water mode and the hot water mode is input to the input unit for the first time, the control unit supplies a predetermined amount of water to the first flow space before applying a voltage to the thermoelectric module so as to flow the water. Instant hot water dispenser. a cold/hot water unit in which a first flow space through which water flows is formed;
a thermoelectric module that is connected to the instantaneous cold and hot water unit and transfers heat from one side to the other side when a voltage is applied;
a heat dissipation cooling unit connected to the thermoelectric module to cool the thermoelectric module or to be cooled by the thermoelectric module; and
a controller that applies a positive voltage or a reverse voltage to the thermoelectric module so that the water flowing in the first flow space is instantaneously cooled or heated by the thermoelectric module to become cold water or hot water;
Including,
The cooling side of the thermoelectric module, which is cooled when a constant voltage is applied, is connected to the instantaneous cold and hot water unit, and the heat dissipation cooling unit is connected to the heating side of the thermoelectric module, which is heated when a constant voltage is applied.
Water flows through the heat dissipation cooling unit to cool the heating side when a positive voltage is applied to the thermoelectric module or to be cooled by the heating side when a reverse voltage is applied to the thermoelectric module;
A second flow space in which water flows is formed in the heat dissipation cooling unit,
The controller applies a voltage to the thermoelectric module only when water is supplied to the second flow space and flows, and does not apply a voltage to the thermoelectric module when water is supplied to the second flow space and does not flow. Instantaneous water heater. a cold/hot water unit in which a first flow space through which water flows is formed;
a thermoelectric module that is connected to the instantaneous cold and hot water unit and transfers heat from one side to the other side when a voltage is applied;
a heat dissipation cooling unit connected to the thermoelectric module to cool the thermoelectric module or to be cooled by the thermoelectric module; and
a controller that applies a positive voltage or a reverse voltage to the thermoelectric module so that the water flowing in the first flow space is instantaneously cooled or heated by the thermoelectric module to become cold water or hot water;
Including,
The cooling side of the thermoelectric module, which is cooled when a constant voltage is applied, is connected to the instantaneous cold and hot water unit, and the heat dissipation cooling unit is connected to the heating side of the thermoelectric module, which is heated when a constant voltage is applied.
Water flows through the heat dissipation cooling unit to cool the heating side when a positive voltage is applied to the thermoelectric module or to be cooled by the heating side when a reverse voltage is applied to the thermoelectric module;
A second flow space in which water flows is formed in the heat dissipation cooling unit,
The instantaneous cold and hot water unit is connected to a cold and hot water intake line connected to one side of the first flow space and a cold and hot water outlet line connected to the other side of the first flow space,
The radiating cooling unit is connected to a radiating cooling water intake line connected to one side of the second flow space and a radiating cooling drain line connected to the other side of the second flow space,
When the temperature of the water flowing through the radiating cooling drain line after flowing in the second flow space becomes higher than a predetermined ideal heating temperature in cold water mode or lower than a predetermined abnormal cooling temperature in hot water mode, the controller cuts off the power Instant hot water dispenser that stops the entire operation. a cold/hot water unit in which a first flow space through which water flows is formed;
a thermoelectric module that is connected to the instantaneous cold and hot water unit and transfers heat from one side to the other side when a voltage is applied;
a heat dissipation cooling unit connected to the thermoelectric module to cool the thermoelectric module or to be cooled by the thermoelectric module; and
a controller that applies a positive voltage or a reverse voltage to the thermoelectric module so that the water flowing in the first flow space is instantaneously cooled or heated by the thermoelectric module to become cold water or hot water;
Including,
The cooling side of the thermoelectric module, which is cooled when a constant voltage is applied, is connected to the instantaneous cold and hot water unit, and the heat dissipation cooling unit is connected to the heating side of the thermoelectric module, which is heated when a constant voltage is applied.
Water flows through the heat dissipation cooling unit to cool the heating side when a positive voltage is applied to the thermoelectric module or to be cooled by the heating side when a reverse voltage is applied to the thermoelectric module;
A second flow space in which water flows is formed in the heat dissipation cooling unit,
The instantaneous cold and hot water unit is connected to a cold and hot water intake line connected to one side of the first flow space and a cold and hot water outlet line connected to the other side of the first flow space,
The radiating cooling unit is connected to a radiating cooling water intake line connected to one side of the second flow space and a radiating cooling drain line connected to the other side of the second flow space,
The cold and hot water outlet line is connected to a water outlet drain line connected to the radiation cooling drain line,
When water is supplied to the first flow space to flow, when the temperature difference between the water in the cold and hot water inlet line and the water in the cold and hot water outlet line is greater than or equal to a predetermined temperature difference,
The control unit drains the water remaining in the first flow space through the water outlet drain line until the temperature difference between the water in the cold and hot water intake line and the water in the cold and hot water outlet line is less than a predetermined temperature difference. 13. The method of claim 12, wherein the control unit continuously supplies water to the first flow space only after the water supplied to the first flow space is cooled or heated by the thermoelectric module to become cold water or hot water at a predetermined preliminary temperature. An instantaneous water dispenser that allows cold or hot water to be discharged through the cold/hot water outlet line while being supplied. The method of claim 17, wherein the control unit adjusts the flow rate of the water flowing into the first flow space through the cold and hot water inlet line so that the temperature of the cold water or hot water discharged through the cold and hot water outlet line is within a predetermined target temperature range Instantaneous water heater. 18. The instantaneous water heater or heater of claim 17, wherein the controller drains the cold water or hot water from the cold or hot water outlet line through the water outlet drain line until the temperature of the cold or hot water in the cold or hot water outlet line is within a predetermined target temperature range. a cold/hot water unit in which a first flow space through which water flows is formed;
a thermoelectric module that is connected to the instantaneous cold and hot water unit and transfers heat from one side to the other side when a voltage is applied;
a heat dissipation cooling unit connected to the thermoelectric module to cool the thermoelectric module or to be cooled by the thermoelectric module; and
a controller that applies a positive voltage or a reverse voltage to the thermoelectric module so that the water flowing in the first flow space is instantaneously cooled or heated by the thermoelectric module to become cold water or hot water;
Including,
The cooling side of the thermoelectric module, which is cooled when a constant voltage is applied, is connected to the instantaneous cold and hot water unit, and the heat dissipation cooling unit is connected to the heating side of the thermoelectric module, which is heated when a constant voltage is applied.
Water flows through the heat dissipation cooling unit to cool the heating side when a positive voltage is applied to the thermoelectric module or to be cooled by the heating side when a reverse voltage is applied to the thermoelectric module;
A second flow space in which water flows is formed in the heat dissipation cooling unit,
The instantaneous cold and hot water unit is connected to a cold and hot water intake line connected to one side of the first flow space and a cold and hot water outlet line connected to the other side of the first flow space,
The control unit adjusts the flow rate of water supplied to the first flow space through the cold/hot water inlet line to adjust the temperature of cold or hot water cooled or heated by the thermoelectric module and discharged through the cold/hot water outlet line. a cold/hot water unit in which a first flow space through which water flows is formed;
a thermoelectric module that is connected to the instantaneous cold and hot water unit and transfers heat from one side to the other side when a voltage is applied;
a heat dissipation cooling unit connected to the thermoelectric module to cool the thermoelectric module or to be cooled by the thermoelectric module; and
a controller that applies a positive voltage or a reverse voltage to the thermoelectric module so that the water flowing in the first flow space is instantaneously cooled or heated by the thermoelectric module to become cold water or hot water;
Including,
The cooling side of the thermoelectric module, which is cooled when a constant voltage is applied, is connected to the instantaneous cold and hot water unit, and the heat dissipation cooling unit is connected to the heating side of the thermoelectric module, which is heated when a constant voltage is applied.
Water flows through the heat dissipation cooling unit to cool the heating side when a positive voltage is applied to the thermoelectric module or to be cooled by the heating side when a reverse voltage is applied to the thermoelectric module;
A second flow space in which water flows is formed in the heat dissipation cooling unit,
The instantaneous cold and hot water unit is connected to a cold and hot water intake line connected to one side of the first flow space and a cold and hot water outlet line connected to the other side of the first flow space,
The radiating cooling unit is connected to a radiating cooling water intake line connected to one side of the second flow space and a radiating cooling drain line connected to the other side of the second flow space,
The cold and hot water outlet line is connected to a water outlet drain line connected to the radiation cooling drain line,
The control unit drains cold water or hot water flowing through the cold or hot water outlet line, cooled or heated by the thermoelectric module while flowing in the first flow space, through the water outlet drain line, and discharged through the cold or hot water outlet line. Instantaneous water heater to adjust the temperature of the water heater. a cold/hot water unit in which a first flow space through which water flows is formed;
a thermoelectric module that is connected to the instantaneous cold and hot water unit and transfers heat from one side to the other side when a voltage is applied;
a heat dissipation cooling unit connected to the thermoelectric module to cool the thermoelectric module or to be cooled by the thermoelectric module; and
a controller that applies a positive voltage or a reverse voltage to the thermoelectric module so that the water flowing in the first flow space is instantaneously cooled or heated by the thermoelectric module to become cold water or hot water;
Including,
The cooling side of the thermoelectric module, which is cooled when a constant voltage is applied, is connected to the instantaneous cold and hot water unit, and the heat dissipation cooling unit is connected to the heating side of the thermoelectric module, which is heated when a constant voltage is applied.
Water flows through the heat dissipation cooling unit to cool the heating side when a positive voltage is applied to the thermoelectric module or to be cooled by the heating side when a reverse voltage is applied to the thermoelectric module;
A second flow space in which water flows is formed in the heat dissipation cooling unit,
The instantaneous cold and hot water unit is connected to a cold and hot water intake line connected to one side of the first flow space and a cold and hot water outlet line connected to the other side of the first flow space,
When the temperature of the cold or hot water flowing through the cold/hot water outlet line being cooled or heated by the thermoelectric module while flowing in the first flow space is below a predetermined minimum temperature or above a predetermined maximum temperature, the controller controls the thermoelectric module to set a predetermined temperature. Instantaneous water heater or water dispenser that does not apply voltage for a period of time. a cold/hot water unit in which a first flow space through which water flows is formed;
a thermoelectric module that is connected to the instantaneous cold and hot water unit and transfers heat from one side to the other side when a voltage is applied;
a heat dissipation cooling unit connected to the thermoelectric module to cool the thermoelectric module or to be cooled by the thermoelectric module; and
a controller that applies a positive voltage or a reverse voltage to the thermoelectric module so that the water flowing in the first flow space is instantaneously cooled or heated by the thermoelectric module to become cold water or hot water;
Including,
The cooling side of the thermoelectric module, which is cooled when a constant voltage is applied, is connected to the instantaneous cold and hot water unit, and the heat dissipation cooling unit is connected to the heating side of the thermoelectric module, which is heated when a constant voltage is applied.
Water flows through the heat dissipation cooling unit to cool the heating side when a positive voltage is applied to the thermoelectric module or to be cooled by the heating side when a reverse voltage is applied to the thermoelectric module;
A second flow space in which water flows is formed in the heat dissipation cooling unit,
The instantaneous cold and hot water unit is connected to a cold and hot water intake line connected to one side of the first flow space and a cold and hot water outlet line connected to the other side of the first flow space,
The radiating cooling unit is connected to a radiating cooling water intake line connected to one side of the second flow space and a radiating cooling drain line connected to the other side of the second flow space,
The cold and hot water outlet line is connected to a water outlet drain line connected to the radiation cooling drain line,
When a cold water mode for producing cold water or a hot water mode for producing hot water is input to the input unit included in the control unit,
The control unit first supplies and causes water to flow in the second flow space, applies a voltage to the thermoelectric module, and supplies and causes water to flow in the first flow space;
The control unit applies a positive voltage to the thermoelectric module in the cold water mode and applies a reverse voltage to the thermoelectric module in the hot water mode;
If the hot water mode is not re-inputted to the input unit for a predetermined time after the hot water mode is terminated, the control unit switches to the cold water mode instantly. 24. The method of claim 23, wherein after switching to the cold water mode, the control unit supplies and flows water to the first flow space for a predetermined time so that the hot water remaining in the first flow space is drained through the water outlet drain line. Instantaneous water heater. a cold/hot water unit in which a first flow space through which water flows is formed;
a thermoelectric module that is connected to the instantaneous cold and hot water unit and transfers heat from one side to the other side when a voltage is applied;
a heat dissipation cooling unit connected to the thermoelectric module to cool the thermoelectric module or to be cooled by the thermoelectric module; and
a controller that applies a positive voltage or a reverse voltage to the thermoelectric module so that the water flowing in the first flow space is instantaneously cooled or heated by the thermoelectric module to become cold water or hot water;
Including,
The cooling side of the thermoelectric module, which is cooled when a constant voltage is applied, is connected to the instantaneous cold and hot water unit, and the heat dissipation cooling unit is connected to the heating side of the thermoelectric module, which is heated when a constant voltage is applied.
Water flows through the heat dissipation cooling unit to cool the heating side when a positive voltage is applied to the thermoelectric module or to be cooled by the heating side when a reverse voltage is applied to the thermoelectric module;
A second flow space in which water flows is formed in the heat dissipation cooling unit,
The instantaneous cold and hot water unit is connected to a cold and hot water intake line connected to one side of the first flow space and a cold and hot water outlet line connected to the other side of the first flow space,
The radiating cooling unit is connected to a radiating cooling water intake line connected to one side of the second flow space and a radiating cooling drain line connected to the other side of the second flow space,
The cold and hot water outlet line is connected to a water outlet drain line connected to the radiation cooling drain line,
When a cold water mode for producing cold water or a hot water mode for producing hot water is input to the input unit included in the control unit,
The control unit first supplies and causes water to flow in the second flow space, applies a voltage to the thermoelectric module, and supplies and causes water to flow in the first flow space;
The control unit applies a positive voltage to the thermoelectric module in the cold water mode and applies a reverse voltage to the thermoelectric module in the hot water mode;
When the hot water mode is input to the input unit within a predetermined time after the end of the cold water mode, the control unit causes water to be supplied and flowed in the first flow space for a predetermined time so that the cold water remaining in the first flow space is discharged through the water outlet drain line. Instant hot water dispenser to drain. a filtering unit including a water filter for filtering inflow water; and
The instantaneous water heater or hot water dispenser according to any one of claims 1 to 7 and 9 to 25 connected to the filtering unit;
A water treatment device comprising a. The method of claim 26, wherein one side of the filtering unit is connected to a raw water supply line to which a radiating cooling water intake line connected to one side of the second flow space formed in the radiating cooling unit is connected,
The other side of the filtering unit is connected to a cold and hot water intake line and a water purification line connected to one side of the first flow space formed in the instantaneous cold and hot water unit. 28. The water treatment device according to claim 27, wherein the hot and cold water outlet line connected to the other side of the first flow space and the purified water line are connected to a water outlet member.

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