KR102223807B1 - Water purifier and control method thereof - Google Patents

Abstract

The present invention relates to a water purifier and a control method thereof, and more particularly, to a water purifier having a small size and a compact internal structure, and a water purifier capable of rotating a water outlet from which water is taken out, and a control method thereof.

Description

Water purifier and control method of water purifier {WATER PURIFIER AND CONTROL METHOD THEREOF}

The present invention relates to a water purifier and a control method of the water purifier.

In general, a water purifier is a device that filters water to remove impurities and is widely used for home use.

In the case of a household water purifier, it is connected to the water supply to remove suspended matters or harmful components contained in the tap water using a filter, and is configured to purify and extract as much water as desired according to the user's operation.

Such a household water purifier is on the market in a variety of products capable of taking out hot and cold water as well as purified water. In recent years, water purifiers that are small in size and can be installed in various installation environments have been developed.

Republic of Korea Patent No.1381803 discloses a water purifier that includes a water outlet through which water is taken out at an upper end of the main unit, and the water outlet is separated from the main unit and rotated by a set angle and then re-coupled. The water purifier having such a structure allows the user to change the location of the water outlet to a set position by separating and recombining the water outlet while maintaining the position of the main body. Because of this, there is an advantage that it can be installed without being limited by the installation space of the water purifier.

However, the water purifier according to the prior art has the following problems.

First, in order to change the position of the water outlet, there is an inconvenience in that the water outlet must be separated from the main body unit and reassembled after changing the position. In addition, there is a problem that damage to the coupling portion may occur during the repetitive separation and coupling process of the outlet portion.

Second, since the water outlet pipe is connected to the water outlet, there is a problem in that water leakage may occur when the water outlet pipe is damaged during the separation and coupling process of the water outlet. In addition, when the water outlet is repeatedly rotated, damage to the water outlet pipe or a fitting portion to which the water outlet pipe is connected may occur, resulting in a problem in that water leakage may occur.

Third, the location of the water outlet is determined by the groove of the coupling hole formed in the main body unit. Therefore, the water outlet may be located only at a set position in which the groove is formed, and there is a problem that it cannot be located at any point.

It is an object of the present invention to provide a water purifier having a small size and compact configuration, so that the installation space is limited.

It is an object of the present invention to provide a water purifier that makes the overall size and shape of the water purifier compact by efficiently arranging a configuration for supplying purified water and cold water and hot water disposed inside the water purifier.

An object of the present invention is to provide a water purifier having various options without changing parts and structures by making the PCB that controls the operation of the water purifier modular for each function and mounted at a designated position on the control base.

An object of the present invention is to provide a water purifier capable of improving power consumption when cooling cold water using an inverter type compressor.

An object of the present invention is to provide a water purifier capable of efficiently cooling a compressor and a condenser provided inside a water purifier having a compact structure.

It is an object of the present invention to provide a water purifier in which a water outlet from which water is taken out is rotated by a simple rotation operation of a user to improve ease of use.

It is an object of the present invention to provide a water purifier capable of changing the position of a water outlet by rotating operation according to various installation environments.

An object of the present invention is to provide a water purifier capable of preventing twisting of a pipe or damage to a fitting even when the water outlet is repeatedly rotated.

An object of the present invention is to provide a water purifier capable of visualizing the state of water ejected by a water outlet nozzle or a state of a container for receiving water by irradiating light downward.

An object of the present invention is to provide a water purifier capable of displaying operation information of a water purifier by color visualization through an eject button.

An object of the present invention is to provide a water purifier in which an LED is disposed so as not to interfere with a switch in contact with an eject button operated by pressing, and input of a water ejection operation through a pressing operation and a status display of the water purifier can be implemented from a single eject button. It is in doing.

An object of the present invention is to provide a water purifier capable of fast and immediate heating of hot water, and a user can control the temperature of hot water to be discharged.

An object of the present invention is to provide a water purifier that discharges steam generated when hot water is heated to prevent excessive increase in pressure inside a hot water tank.

It is an object of the present invention to provide a water purifier that enables effective heating by allowing water passing through a hot water tank to spread evenly and to slow a flow rate.

An object of the present invention is to provide a water purifier provided with an induction heating assembly capable of heating hot water inside a water purifier having a compact structure.

It is an object of the present invention to provide a water purifier that makes the internal structure of a cooling tank compact and allows the internal cooling water to circulate actively.

An object of the present invention is to provide a water purifier that reduces noise by preventing ice generated from an evaporator inside a cooling tank from flowing and prevents damage to the internal structure of the cooling tank.

An object of the present invention is to provide a water purifier that facilitates drainage and re-watering of cooling water filled in a cooling tank.

An object of the present invention is to provide a water purifier capable of being rotated according to the rotation of the ejection portion so that it can be disposed below the ejection portion.

An object of the present invention is to provide a water purifier capable of collecting residual water and easily treating residual water under a take-out portion.

An object of the present invention is to provide a water purifier capable of easily transferring the level of residual water collected in a tray to a user.

It is an object of the present invention to provide a control method of a water purifier capable of filling a required amount of cooling water with a simple operation without disassembling the cooling tank.

A water purifier according to an embodiment of the present invention for achieving the object of the present invention as described above, the case forming the outer shape; A filter bracket provided inside the case and on which a filter and a valve are mounted; A condenser bracket provided inside the case spaced apart from the filter bracket and accommodating a condenser; A cooling tank mounted on an upper end of the condenser bracket and cooling water purified by the filter; A support plate connecting between the filter bracket and the cooling tank, and partitioning the space between the filter bracket and the cooling tank up and down; A compressor provided below the support plate; And a control assembly mounted on an upper surface of the support plate.

The filter bracket is fixedly mounted to the bottom of the water purifier, and a condenser mounting portion accommodating the condenser; It is characterized in that it includes a tank mounting portion extending from the upper surface of the condenser mounting portion and receiving the lower end of the cooling tank.

In order to correspond to the inner space of the condenser mounting part, the condenser is characterized in that it is formed in a hexahedral shape by successively arranging refrigerant tubes bent multiple times.

A filter mounting portion on which the filter is mounted is recessed in a front surface of the filter bracket, and a plurality of the valves are fixedly mounted on a rear surface of the filter bracket.

The filter bracket is provided with a front cover that is detachably provided to open and close the filter mounting portion, and to form a front exterior of the water purifier.

The condenser bracket is characterized in that the plate support portion for supporting the support plate is extendedly formed.

The support plate may further include an induction heating assembly for heating and supplying purified water by an induction heating method.

The induction heating assembly is coupled to the control assembly and mounted on the heating assembly in a modular state.

The control assembly includes: a control base; An induction heating PCB mounted on one surface of the control base facing the induction heating assembly and controlling the induction heating assembly; A main PCB mounted on a surface opposite to a surface on which the induction heating PCB is mounted, and controlling the compressor and the valve; It is mounted on the other side of the control base, characterized in that it comprises a power supply PCB for supplying power to the induction heating PCB and the main PCB.

An NFC PCB capable of short-distance communication is provided on an upper end of the control base, and the NFC PCB is arranged to be in contact with an upper surface of the case.

The control base may be provided with a plurality of covers respectively shielding the main PCB, the induction heating PCB, and the power supply PCB.

The compressor is characterized in that it is an inverter compressor.

In addition, a water purifier according to an embodiment of the present invention comprises: a base forming a bottom surface of the water purifier and having a suction port; A compressor mounted on the base; A condenser bracket mounted on the base so as to be spaced apart from the compressor and accommodating a condenser; A cooling tank mounted on the upper surface of the condenser bracket and provided with an evaporator therein to make cold water; A rear cover forming an exterior of the water purifier and having a discharge port formed at a position corresponding to the condenser bracket; And a cooling fan provided between the compressor and the condenser and configured to discharge air flowing through the suction port through the condenser and discharge the air through the discharge port.

The base is provided with a leg extending downward to separate the bottom of the base from the ground on which the water purifier is installed, and the suction port is formed on the bottom of the base.

The compressor is characterized in that it is disposed so as to overlap at least a portion of the suction port.

The base is characterized in that the mounting portion is formed to protrude so that the compressor is mounted spaced apart from the base.

A nut to which a screw for fixing the compressor is fastened is disposed on the mounting part by insert injection.

The condenser bracket is provided with a condenser mounting part for accommodating the condenser, and the condenser mounting part has an inlet open toward the compressor and an outlet open toward the discharge port to guide the flow of cooling air.

The discharge port has a size corresponding to the outlet of the condenser mounting part, and is in close contact with the opening of the condenser mounting part.

The cooling fan is characterized in that it is mounted to shield the inlet of the condenser mounting portion.

A fixing member which is fixed to the cooling fan through a fixing hole formed in the condenser mounting part is further provided, and the fixing member is formed of an elastic material.

The condenser is characterized in that the outer shape is formed in a cube shape corresponding to the condenser mounting portion.

And, the water purifier according to an embodiment of the present invention, the case forming the exterior; A circular rotator rotatably mounted inside the case; A water outlet protruding from the rotator to the outside of the case and including a water outlet nozzle through which water is extracted; And an operation unit mounted on the upper surface of the case and provided with a take-out button for extracting water, and connected to the rotator to rotate together when the rotator is rotated.

The case includes a front cover that forms a front exterior of the water purifier, and the front cover includes an upper cover and a lower cover disposed vertically and spaced apart from each other with the rotator interposed therebetween.

A filter bracket that extends up and down inside the case so that the filter is mounted and supports the rotator from below are provided, and the upper surface of the filter bracket maintains contact with one side of the rotator, and guides the rotation of the rotator. It is characterized in that it is provided with a rotating guide rail having a curvature so as to be able to.

The rotator is provided with an oil damper equipped with a pinion on a rotation shaft, and an internal gear extending along a curvature is formed on the filter bracket, and when the rotator rotates, the pinion is moved along the internal gear.

A rotation connection part extending downward is provided on a lower surface of the operation part, and a coupling ring which is coupled to each other by inserting the rotation connection part is provided in the rotator.

A center ring is formed at a rotation center of the rotator, and a rotation tube rotatably fitted to a connector connected to a water outlet pipe connected to the extraction nozzle is disposed on the center ring.

The rotating tube is formed of a metal material, and a fitting groove into which the collet of the connector is inserted is formed.

The manipulation unit is formed in a circular shape, and the upper surface of the water outlet is formed to have an inclined surface that decreases closer to the water outlet.

In the water outlet nozzle, a cold water connection part connected to a water outlet pipe through which cold water and purified water are supplied, and a hot water connection part connected to a hot water pipe through which hot water is supplied are formed, respectively.

The water outlet includes a water outlet housing having an open top surface, extending from the rotator, and mounting the water outlet nozzle; It characterized in that it consists of a water outlet cover for opening and closing the opened upper surface of the water outlet housing.

A lighting hole is formed on the bottom surface of the water outlet housing, and a lighting unit for irradiating light downward through the lighting hole is provided inside the water outlet housing.

And, the water purifier according to an embodiment of the present invention, the case forming the outer shape of the water purifier; An eject button provided in the case and operated by a user to eject water; A control unit PCB provided inside the case; A switch provided on the operation unit PCB, which is contacted by the operation of the eject button to be operated on and off; Includes; an LED provided on the control panel PCB to irradiate light toward the ejection button, wherein at least a portion of the ejection button is formed to allow light to be transmitted, and the LED is light of a different color according to the operation state of the water purifier. It is characterized in that to be investigated.

The operation button includes: a pressing unit that is moved by a user's pressing operation; An elastic portion cut along the periphery of the pressing portion to provide elasticity for returning the pressing portion; A contact portion protruding from one end of the pressing portion and in contact with the switch according to the movement of the pressing portion; And a rotation support portion protruding from the other end of the pressing portion facing the contact portion and serving as a rotation center of the pressing portion.

A light transmitting part through which light is transmitted is formed in the pressing part, and the contact part is formed outside the light transmitting part.

A light guide may be further formed along the light transmitting part and extending toward the LED to guide light of the LED toward the light transmitting part.

A button plate shielding the light transmitting part may be further provided on the pressing part, and the button plate may be formed to allow light transmission.

The LED is characterized in that it is located inside the light transmitting part.

The LED is characterized in that it irradiates light of different colors according to the replacement cycle of the filter.

A plurality of the LEDs are provided and are characterized in that they irradiate light of different colors.

The control unit PCB may be provided with a buzzer that displays information according to the state of the water purifier with sound.

And, the water purifier according to an embodiment of the present invention, the case forming the exterior; A filter provided inside the case; And an induction heating assembly for heating the purified water passing through the filter, wherein the induction heating assembly comprises: a hot water tank through which the purified water passes; A working coil wound a plurality of times at a position facing the hot water tank and emitting electromagnetic force for induction heating the hot water tank; A ferrite core disposed radially with respect to the center of the working coil and preventing loss of electromagnetic force generated from the working coil; And a heating bracket mounted on a surface of the hot water tank and the working coil facing each other.

An input pipe through which purified water is introduced is formed at a lower end of the hot water tank, and an output pipe through which hot water is discharged is formed at an upper end of the hot water tank.

A connector is connected to the input pipe, a check valve and a pipe for supplying water are connected to one side of the connector, and an end cap that opens and closes to drain water from the hot water tank is mounted on the other side of the connector. It is done.

A connector is connected to the output pipe, and a pipe through which hot water is discharged is connected to one side of the connector, and the other side of the connector is opened when the pressure of the hot water tank is higher than a certain pressure to discharge the steam inside the hot water tank. It characterized in that the valve is provided.

A steam pipe for discharging steam is connected to an outlet of the safety valve, and the steam pipe extends to the outside of the water purifier so that it can be drained to the outside of the water purifier.

The induction heating assembly is characterized in that it is coupled as a module with a control assembly that controls driving of the water purifier.

The heating bracket is characterized in that it is provided with a coupling boss extending so as to be coupled in a state spaced apart from the control assembly.

The heating bracket is provided with a hot water temperature sensor for measuring the temperature of the hot water tank in contact with the hot water tank, and a fuse for blocking power supply to the induction heating assembly when the hot water temperature sensor is above a set temperature. do.

The hot water tank includes: a first cover having a planar shape and forming a surface facing the working coil; The first cover and the circumferential surface are bonded to each other, and an uneven shape is formed to include a second cover that allows water to flow.

The second cover is characterized in that a plurality of protrusions extending from an inlet through which water is introduced into an outlet direction and protruding toward the first cover are formed.

The protrusion may include a vertical protrusion extending in a vertical direction and a horizontal protrusion extending in a horizontal direction from both ends of the vertical protrusion.

At least one of the protrusions is in contact with the first cover and is bonded to each other by welding.

At least one surface of both surfaces of the coil is provided with a mica sheet for maintaining a distance between the hot water tank or the ferrite core.

And, the water purifier according to an embodiment of the present invention, the case forming the exterior; A compressor mounted inside the case; A condenser bracket mounted inside the case and accommodating a condenser; And a cooling tank mounted on an upper surface of the condenser bracket to cool purified water, wherein the cooling tank includes: a tank body receiving cooling water; A tank cover shielding the opened upper surface of the tank body; A cooling coil wound in a coil shape inside the tank body and guiding purified water to pass through the inside of the tank body; An evaporator that is wound in a coil shape inside the tank body and cools the cooling water above the cooling coil; And a stirrer that rotates in a central space where the cooling coil and the evaporator are wound, and forcibly circulates the cooling water in the tank body.

The inside of the tank body is disposed between the cooling coil and the evaporator to partition the inside of the tank body, and a mesh member formed with a plurality of holes to allow the cooling water to enter and exit is provided.

The mesh member includes: a partition portion that vertically partitions the inside of the tank body and has a stirrer hole through which the stirrer passes; It is characterized in that it includes an extension portion extending upwardly along the periphery of the stirrer hole and partitioning between the stirrer and the evaporator.

The mesh member is characterized in that a lower support portion extending downwardly and seated on an upper end of the cooling coil is formed.

The mesh member is characterized in that the upper support portion protruding so that the evaporator can be seated is formed.

The mesh member is characterized in that a fixing hook that can be fixed by pressing the upper end of the evaporator is formed to extend.

A coil support part is formed on a bottom surface of the tank body to support the lower end of the cooling coil by protruding upward, and spaced apart the lower end of the cooling coil and the bottom surface of the tank body.

The stirrer is characterized in that it extends to one side of the cooling coil through the evaporator.

The tank body and the outer surface of the tank cover is characterized in that surrounded by a heat insulating material.

The upper surface of the condenser bracket is characterized in that a tank mounting portion opened upward to insert and mount the lower portion of the cooling tank is formed.

The cooling tank may be provided with a drain valve that opens and closes to drain the water inside the cooling tank to the outside.

A drain portion that is inclined or recessed is formed on the bottom of the cooling tank, and the drain portion communicates with the drain valve.

The drain valve is characterized in that it can be opened while a pipe for injection of coolant is connected.

The other end of the pipe for injecting the cooling water may be connected to the outlet nozzle of the water purifier, and the control unit for controlling the operation of the water purifier is characterized in that it discharges water in a predetermined amount so as to fill the cooling tank.

In addition, the water purifier according to an embodiment of the present invention includes a base forming a bottom surface, and a case forming an exterior; A dispensing part provided with a dispensing nozzle through which purified water is dispensed, and protruding outside the case, and provided so as to be rotatable about the inside of the case; A rotating ring rotatably mounted to the base; And a tray detachably mounted on the rotating ring and extending outward of the case.

The tray includes a tray body having an open top surface and receiving water dropped from the ejection nozzle; It is provided detachably on the upper surface of the tray body, and at least a portion is formed in a grill shape, and is configured as a tray cover through which water can pass.

A plotter is accommodated inside the tray, a recessed portion is formed in the tray body to a size that can accommodate the bottom of the plotter, and an indicator hole is formed in the tray cover to expose the top of the plotter. It is characterized by being.

The floater may include a floating portion accommodated in the recessed portion and formed of a material that floats in water; A cap coupled to the floating part and positioned inside the indicator hole; It is provided below the cap and includes an indicator formed in a color different from that of the cap and the tray cover, and when the tray is above a set water level, the indicator is exposed to the upper side of the indicator hole due to the rise of the floating part. It is characterized.

The depression is characterized in that it contacts the ground on which the water purifier is installed.

A water collecting hole is opened in the tray cover corresponding to the vertical lower side of the water outlet nozzle.

A tray coupling portion protruding from the tray is formed, a tray mounting portion into which the tray coupling portion is inserted is formed on the rotation ring, and the tray mounting portion is exposed to the outside from a lower end of the case.

The case includes a front cover forming an exterior of a rounded front, and a rear end of the base is recessed along a curvature corresponding to the front cover.

The base is characterized in that the stopper for restricting rotation by contacting the side of the rotator of the tray is formed to be stepped.

It is characterized in that the flow preventing portions are formed extending forward on both sides of the stopper and into which both sides of the lower end of the tray are inserted when the tray is rotated.

The base is extended to have a curvature corresponding to the curvature of the rotation ring, characterized in that the rotation guide portion is formed in contact with the inner surface of the rotation ring to guide the rotation of the rotation ring.

And, the control method of the water purifier according to an embodiment of the present invention, in a state in which the drain valve and the water outlet nozzle are connected using a separately provided service pipe, switching to a coolant replacement mode by a user input; Detecting the amount of water supplied by a user's take-out operation by a flow sensor and transmitting it to a control unit, wherein the control unit opens a water purification valve so that purified water is supplied by a predetermined flow rate; And when the supply of the set amount of purified water is completed to the cooling tank, closing the water purification valve and converting to a normal operation mode.

The drain valve is characterized in that it is opened when the service pipe is connected.

In the coolant replacement mode and the normal operation mode, the control unit may display a mode selected by the operation unit.

The control unit is characterized in that the LED irradiating light through the water outlet switch of the control unit irradiates light of different colors to display the coolant replacement mode and the normal operation mode.

The set flow rate is characterized in that it is set to an amount capable of immersing the cooling coil and the evaporator inside the cooling tank.

The water purifier according to an embodiment of the present invention has the following effects.

According to an embodiment of the present invention, it is possible to have a compact structure while having a structure including a compressor and an evaporator condenser for making cold water inside the water purifier, as well as a cooling tank. In particular, there is an advantage in that a cooling tank is disposed above the condenser and a control assembly is disposed in a space between the compressor and the cooling tank to efficiently use the internal space to make the shape of the water purifier compact.

Further, according to an embodiment of the present invention, the PCB that controls the driving of the water purifier is configured for each module, and has a configuration that is mounted at a designated position of the control base. Therefore, it is possible to implement various options according to the type of PCB mounted on one control base, and there is an advantage of being able to manufacture various models without changing the internal structure of the water purifier.

In addition, this control base can be arranged in the space between the filter bracket and the cooling tank to further improve the efficiency of the space, and it can be mounted in a module form with a hot water heating unit for making hot water. It is possible to expect an improvement in space efficiency.

In addition, the water purifier according to an embodiment of the present invention implements a refrigeration cycle including an inverter compressor, an evaporator, and a condenser, thereby making cold water. For effective cooling of the inverter compressor and the condenser, a condenser is placed on the suction port, the condenser is accommodated inside the condenser bracket, and the air flowing by the cooling fan is cooled evenly through the entire condenser, thereby effectively cooling the compressor and the condenser. You can do it.

In addition, since the suction port is formed on the base and the base is spaced apart from the ground, the suction port is not exposed to the outside, making the appearance more beautiful and at the same time facilitating suction of outside air.

In addition, the water purifier according to the embodiment of the present invention has a structure in which a water outlet portion provided with a water outlet nozzle protrudes, and has a structure that can be freely rotated by rotation of the rotator. Therefore, it is possible to freely change to a location that can be easily operated by the user, thereby improving the convenience of use.

In addition, since the water outlet can be used by moving the water outlet to an appropriate position without being restricted by various installation environments due to the rotation of the water outlet, an effect of improving usability can be expected.

In addition, when the water outlet portion is rotated, the operation portion is configured to rotate together so that easy operation at the water outlet position is possible, and the status can be easily confirmed, so that the convenience of use may be further improved.

In addition, since a light is provided in the water outlet, it is possible to easily identify a state of water extraction by the water outlet nozzle, so that the convenience of use may be further improved.

In addition, the water purifier according to an embodiment of the present invention includes a rotation ring at the center of rotation of the rotator, and the rotation ring includes a rotation tube rotatably fitted to a connector connected to a water outlet. In addition, the rotating pipe is formed of a stainless material, and thus durability can be improved by preventing the pipe from being twisted or damage to the fitting even during repeated rotation operation of the outlet portion.

In addition, the quieter according to an embodiment of the present invention can be discharged by pressing the ejection button, and light of various colors can be transmitted through the ejection button to indicate status information of the water purifier. Therefore, it is possible to display information such as whether the filter is exchanged or whether the extracted water is hot water, cold water, or purified water without a separate display.

In addition, it is designed to be positioned in a position where the switch and the LED do not interfere with each other while the push operation of the switch and the light transmission of the LED are performed at the same time with one ejection button, so there is an advantage that operation and information can be displayed through a single configuration. .

Further, the water purifier according to an embodiment of the present invention has a structure in which hot water is heated by an induction heating method of water passing through the plate-shaped hot water tank, so that hot water can be heated while passing through the hot water tank. There are possible advantages.

In addition, due to the characteristics of the induction heating method, the heating performance can be adjusted through the output control of the working coil, and thus hot water having various temperatures set by the user can be taken out.

In addition, the water purifier according to an embodiment of the present invention is provided with a safety valve on a branched side of the output pipe of the hot water tank so that steam can be discharged through the safety valve when the pressure increases due to the generation of steam during heating of the hot water. do. Accordingly, there is an advantage of preventing excessive pressure increase due to steam, improving hot water heating performance and improving durability of the hot water tank.

In addition, the water purifier according to an embodiment of the present invention is provided with a plurality of protrusions inside the hot water tank, and a flow path of water flowing through the inside of the hot water tank is branched by the protrusions to evenly water the entire hot water tank. This can flow, and the flow velocity is slowed down by collision with the protrusion. Accordingly, it is possible to evenly heat water distributed throughout the hot water tank, and as the residence time inside the hot water tank increases due to a decrease in flow rate, more efficient heating of hot water is possible.

In addition, the water purifier according to an embodiment of the present invention is arranged by winding a cooling coil through which purified water for cooling flows in a cooling tank, and an evaporator is wound and disposed above the cooling coil, and the cooling water is filled therein. It cools the water passing through the cooling coil. Accordingly, effective cooling of purified water is possible while compactly configuring the inside of the cooling tank.

In addition, the agitator is disposed in the coiled inner region of the cooling coil and the evaporator, thereby activating the circulation of the cooling water, and thus, the cooling efficiency of the purified water passing through the cooling coil can be further improved.

In addition, a water purifier according to an embodiment of the present invention is provided with a mesh member that partitions a region in which the evaporator, the cooling coil, and the stirrer are disposed in the cooling tank. The cooling water flows by the mesh member, but the ice frozen in the evaporator does not flow toward the agitator or the cooling tank, thereby preventing noise due to collision of ice or damage to the internal structure.

In addition, the water purifier according to an embodiment of the present invention is configured to discharge cooling water by a drain valve provided in the cooling tank. Therefore, it is possible to keep the inside of the cooling tank in a clean state, and in order to resupply the coolant in the cooling tank, the service valve is connected to the drain valve and the outlet nozzle, and the control can be controlled to supply a predetermined amount of coolant. . Therefore, there is an advantage in that the cooling water drainage and re-watering operation are facilitated.

In addition, the water purifier according to an embodiment of the present invention is provided with a tray that can be rotated according to the rotation of the ejection portion to be rotated. Therefore, even if the take-out portion is rotated at a specific angle, the tray can be disposed vertically below the container, so that the container can be seated and residual water can be received, thereby improving the convenience of use.

In addition, the tray cover is formed in a grill shape or a collection hole is formed to facilitate collection. In addition, since the tray has a detachable structure, there is an advantage in that it is easy to treat residual water.

In addition, a floater is formed inside the tray, and the floater rises according to the water level and is exposed to the tray cover to inform the user of the water level of the tray. In particular, when the indicator of the plotter is exposed, it is possible to effectively notify that the remaining water in the tray should be emptied above the set water level, so that the convenience of use may be further improved.

In addition, in the control method of a water purifier according to an embodiment of the present invention, the cooling water is drained through a drain valve in a state in which the cooling tank is assembled, and after connecting the drain valve and the water outlet nozzle through a service pipe, the cooling water replacement mode is set. After making the change, the water outlet is manipulated. During such an operation, the control unit supplies water of a set flow rate to fill the cooling tank, and returns to the normal operation mode after the supply of the set flow rate is completed. Therefore, the user can replace the cooling water in the cooling tank in a simple manner, and there is an advantage of maintaining the inside of the cooling tank in a clean state.

1 is a perspective view of a water purifier according to an embodiment of the present invention.
2 is an exploded perspective view of the water purifier.
3 is an exploded perspective view showing an assembly structure of a top cover, a filter bracket, and a base of the water purifier.
4 is an exploded perspective view of a top cover and a control unit of a water purifier according to an embodiment of the present invention.
5 is a perspective view of a state in which the operation unit and the top cover are coupled from below.
6 is a cross-sectional view 6-6' of FIG. 3.
7 is a perspective view of an eject button of the water purifier as viewed from above.
8 is a perspective view of the ejection button viewed from below.
9 is a view showing the lighting state of the switch LED of the water purifier.
10 is a diagram showing an operation state of the eject button.
11 is a perspective view of the rotator of the water purifier as viewed from above.
12 is a view of the head office from the bottom of the rotator.
13 is an exploded perspective view of the rotator of the water purifier.
14 is a view showing a flow path structure inside the rotator and a water outlet.
15 is a partial perspective view of a filter bracket of the water purifier.
16 is a cross-sectional view showing a coupling structure of the rotator.
17 is a view as viewed from the rear of the arrangement of the valve mounted on the filter bracket.
18 is an exploded perspective view of a water outlet of the water purifier.
19 is a cut-away perspective view of the water outlet.
20 is a perspective view of a heating and control module of the water purifier.
21 is a perspective view of the induction heating assembly of the water purifier as viewed from the front.
22 is a perspective view of the induction heating assembly viewed from the rear.
23 is an exploded perspective view of the induction heating assembly.
24 is a front view of the hot water tank.
25 is a cross-sectional view 25-25' of FIG. 24.
26 is a perspective view of the control assembly of the water purifier.
27 is an exploded perspective view of the control assembly.
28 is a perspective view of a cooling tank of the water purifier.
29 is an exploded perspective view of the cooling tank.
FIG. 30 is a cross-sectional view of 30-30' of FIG. 28.
31 is a perspective view of the mesh member.
FIG. 32 is a cross-sectional view 32-32' of FIG. 28.
33 is an exploded perspective view showing a mounting structure of a drain valve of the water purifier.
34 is an exploded perspective view showing the coupling structure of the drain valve.
35 is a partial cross-sectional view showing the coupling structure of the drain valve.
36 is a view showing a state in which the compressor bracket is mounted on the base of the water purifier.
37 is an exploded perspective view showing a coupling structure between the base and the tray.
38 is an exploded perspective view showing the coupling structure of the tray of the water purifier.
39 is a view showing the full water level of the tray.
40 is an exploded perspective view showing a combined structure of a condenser bracket of the water purifier, a blower fan, and a condenser.
41 is a cut-away perspective view showing the flow of cooling air in the water purifier.
42 is a circuit diagram schematically showing a flow path of water in the water purifier.
43 is a block diagram showing the flow of the control signal of the water purifier.
44 is a perspective view showing a coolant replacement operation state of the water purifier.
45 is a flowchart sequentially showing a method of controlling the water purifier.
46 is a diagram sequentially showing an assembly process of the water purifier.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. However, the present invention cannot be said to be limited to the embodiments in which the spirit of the present invention is presented, and other inventions that are regressive by addition, change, deletion, etc. of other components, or other embodiments included within the spirit scope of the present invention, are facilitated. I can suggest.

1 is a perspective view of a water purifier according to an embodiment of the present invention. And, Figure 2 is an exploded perspective view of the water purifier.

As shown in the drawings, the water purifier 1 according to the embodiment of the present invention has a long length in the front and rear direction and a narrow width in the left and right direction. Accordingly, the water purifier 1 has a slim and compact shape as a whole.

The outer shape of the water purifier 1 may be formed by the case 10. The case 10 includes a front cover 11 forming the front exterior, a rear cover 12 forming the rear exterior, a base 13 forming a lower surface, a top cover 14 forming an upper surface, and left and right It is composed of side panels 15 forming both side surfaces. The front cover 11 and the cooling fan cover 12, the base 13 and the top cover 14, and a pair of side panels 15 may be assembled to each other to form the exterior of the water purifier 1.

A water outlet 20 is disposed on the front surface of the water purifier 1. The water outlet 20 is formed to protrude forward of the front cover 11, and purified water is discharged through a water outlet nozzle 25 protruding downward.

The front cover 11 may include an upper cover 111 and a lower cover 112. In addition, a rotator 21 may be disposed rotatably between the upper cover 111 and the lower cover 112.

The water outlet 20 is configured to be rotated together with the rotator 21. Accordingly, the user can rotate the water outlet 20 at a desired angle according to the installation state or installation environment of the water purifier 1. At this time, the operation unit 40 provided in the top cover 14 also has a structure that can be rotated together.

The tray 90 protrudes in front of the front cover 11 on the base 13 and may be positioned vertically below the water outlet 20. In addition, the tray 90 may be rotated by a user's manipulation and may be separated from the base 13. The tray 90 may have an upper surface formed in a grill shape so that water falling from the water outlet 20 can be stored.

Inside the case 10, a filter 34 for water purification and a filter bracket 30 on which a plurality of valves 366, 367, 369 are mounted are provided, and the rotator 21 rotates at the top of the filter bracket 30 It is mounted as possible. In addition, the manipulation unit 40 may be provided above the rotator 21, and the manipulation unit 40 may be connected to the rotator 21 to rotate together when the rotator 21 is rotated.

The base 13 is provided with a rotation ring 91 that is rotatably mounted, and the tray 90 is detachably provided on the rotation ring 91. Accordingly, the tray 90 can be rotated in a mounted state, and can be positioned below the water outlet 20. And, if necessary, the tray 90 is configured to be separated and coupled from the rotary ring 91.

A compressor 51 and a condenser 52 are provided on the upper surface of the base 13. In addition, a cooling fan 53 is provided between the compressor 51 and the condenser 52 so that the compressor 51 and the condenser 52 can be cooled. The compressor 51 may be an inverter type compressor capable of adjusting a cooling capacity by varying a frequency. Therefore, cooling of the purified water can be efficiently performed, thereby reducing power consumption.

In addition, the condenser 52 is located at the rear of the base 13 and may be located at a position corresponding to the discharge port 121 formed in the rear cover 12. The condenser 52 may be formed by bending a refrigerant pipe of a flat tube type a plurality of times in order to improve heat exchange efficiency as well as efficient use of space, and is configured to be accommodated in the condenser bracket 54.

The condenser bracket 54 is provided with a condenser mounting part 541 to which the condenser 52 is fixed, and a tank mounting part 542 to which a cooling tank 60 for making cold water may be mounted. The condenser mounting part 541 forms a hexahedral space corresponding to the overall shape of the condenser 52 to accommodate the condenser 52. In addition, the condenser mounting portion 541 is formed such that portions facing the cooling fan 53 and the discharge port 121 are opened, respectively, so that effective cooling of the condenser 52 is possible.

In addition, the tank mounting part 542 is formed above the condenser bracket 54, that is, above the condenser mounting part 541. The tank mounting part 542 is inserted into the lower end of the cooling tank 60 to fix the cooling tank 60.

The cooling tank 60 is for cooling purified water to make cold water, and is filled with cooling water that exchanges heat with the incoming purified water. In addition, an evaporator 63 for cooling the cooling water may be accommodated in the cooling tank 60. In addition, the purified water can be cooled by allowing it to pass through the inside of the cooling tank.

A support plate 35 extending toward the cooling tank 60 is further provided on one side of the filter bracket 30. The support plate 35 is provided above the compressor 51 and extends from the filter bracket 30 to the condenser bracket 54 to provide a space in which the heating and control module 50 is mounted.

The heating and control module 50 may include an induction heating assembly 70 for making hot water and a control assembly 80 for controlling driving of the water purifier 1. The induction heating assembly 70 and the control assembly 80 may be combined with each other to form a single module, and may be mounted on the support plate 35 in a combined state.

The induction heating assembly 70 is for heating purified water and is configured to be heated by an induction heating (IH) method. The induction heating assembly 70 can heat water immediately and at a high speed during a hot water extraction operation, and can heat purified water to a desired temperature by controlling the output of a magnetic field and provide it to a user. Therefore, it is possible to take out hot water of a desired temperature according to the user's operation.

The control assembly 80 is for controlling the operation of the water purifier 1, and can control the compressor 51, the cooling fan 53, various valves and sensors, the induction heating assembly 70, and the like. It is structured to be. The control assembly 80 may be modularized and configured by a combination of PCBs divided into a plurality of parts for each function. That is, in a structure in which the water purifier 1 extracts only cold water and purified water, a PCB for controlling the induction heating assembly 70 may be omitted, and at least one PCB may be omitted in this manner.

Hereinafter, each component of the water purifier will be described in more detail with reference to the drawings.

3 is an exploded perspective view showing an assembly structure of a top cover, a filter bracket, and a base of the water purifier.

As shown in the figure, a rotation ring 91 is mounted on the first half of the base 13, and a tray 90 is detachably coupled to the rotation ring 91. The tray 90 protrudes toward the front of the base 13 while being coupled to the rotation ring 91.

The filter bracket 30 includes a bottom portion 31 coupled to the base 13, a filter receiving portion 32 in which the filter 34 is accommodated, and a rotator mounting portion 33 in which the rotator 21 is mounted. ).

In detail, the bottom portion 31 is formed to correspond to the shape of the front end of the base 13 and is coupled to the base 13. The mounting position of the filter bracket 30 may be fixed by the combination of the bottom part 31, and the shape of the bottom surface of the filter receiving part 32 may be formed.

The filter bracket 30 may be hooked and constrained to the base 13 by a hook method, and may be fixed by a screw that is fastened to the lower surface of the base 13. The bottom portion 31 may be coupled to the base 13 in the inner region of the rotation ring 91, and is configured not to interfere with the rotation ring 91 so that the tray 90 can rotate smoothly. Let it be done.

The filter receiving portion 32 is formed to extend in the vertical direction, and when viewed from the front (left in FIG. 3), a recessed space is formed so that the filter 34 can be accommodated. A plurality of filters 34 may be mounted on the filter receiving part 32. The filter 34 is for purifying supplied raw water (tap water) and may be configured to combine filters having various functions.

In addition, a filter socket 341 to which the filter 34 is mounted may be further provided in the filter receiving part 32, and a pipe for flowing purified water is provided in the filter socket 341, and the Piping may be connected to a plurality of valves (366, 367, 369). Accordingly, the raw water can be directed to the valves 366, 367 and 369 for water supply after passing through the filter 34 in sequence.

A plurality of valves 366, 367, and 369 may be provided on the rear surface of the filter receiving part 32 (the opposite side of the surface on which the filter is mounted), and the valves 366, 367, 369 may include the filter 34 as well as the cooling tank ( 60) and the induction heating assembly 70, and selectively supplying purified water, cold water, and hot water to the water outlet.

A rotator mounting portion 33 is formed at an upper end of the filter receiving portion 32. The rotator mounting portion 33 has a semicircular shape protruding forward so as to have a predetermined curvature, and has a structure in which the rotator 21 can be seated at an upper end. In this case, the rotator mounting portion 33 may be formed to have a curvature corresponding to the outer surface of the rotator 21. Accordingly, the rotator 21 is configured to be rotated while seated on the rotator mounting portion 33.

In addition, an internal gear 331 may be formed on an upper end of the rotator mounting portion 33. The internal gear 331 has a curvature corresponding to the rotator mounting portion 33, and is gear-coupled with the pinion gear 271 to be described below so that the rotation of the rotator 21 can be made smoothly.

The rotator 21 is formed in a circular shape, and a water outlet 20 protruding forward is further formed in the rotator 21. The water outlet 20 may be integrally configured with the rotator 21, and may be rotated together when the rotator 21 is rotated.

An upper cover 111 may be provided above the rotator 21. The upper cover 111 forms the front exterior of the water purifier 1 together with the lower cover 112 shielding the filter bracket 30 from the front. Accordingly, the upper cover 111 forms a part of the front surface of the water purifier between the rotator 21 and the top cover 14 and is rounded.

A top cover 14 may be provided on an upper end of the upper cover 111. The top cover 14 forms an upper surface of the water purifier 1. In addition, the operation unit 40 is mounted on the top cover 14. The operation unit 40 is formed in a circular shape, and is coupled to the rotator 21 to be configured to rotate together when the rotator 21 is rotated. In addition, the operation unit 40 is provided with an eject button 41.

4 is an exploded perspective view of a top cover and a control unit of a water purifier according to an embodiment of the present invention. And, Figure 5 is a perspective view from the bottom of the state in which the operation unit and the top cover are coupled. And, FIG. 6 is a cross-sectional view 6-6' of FIG. 3.

As shown in the drawing, the top cover 14 forms an upper surface of the water purifier 1. The front and rear ends of the top cover 14 are formed to be rounded, and are coupled to the front cover 11 and the rear cover 12, respectively, corresponding to upper ends of the front cover 11 and the rear cover 12. It can be formed to have a curvature.

In addition, a cover hole 141 is formed in the top cover 14. The cover hole 141 is opened in a size and shape corresponding to the manipulation unit 40 so that the manipulation unit 40 can be rotatably mounted.

A base mounting portion 142 and a base support portion 143 for fixing the operating portion base 42 forming the lower portion of the operating portion 40 may be formed inside the cover hole 141.

The base mounting portion 142 may extend from the cover hole 141 toward the center of the cover hole 141, and a plurality of the base mounting portions 142 are disposed so as to be spaced apart at equal intervals. Further, the base mounting portion 142 is formed in a shape in which an end portion is bent inward to press and fix the circumferential surface of the operation portion base 42.

In addition, the base support portion 143 extends from the rear portion of the cover hole 141 toward the inside. In addition, the base support part 143 is formed to have a downward slope toward the center of the cover hole 141 to support the operation part base 42 from below. In addition, a protrusion 425 protruding so as to have an inclined surface corresponding to the base support 143 is further formed on the circumferential surface of the operation part base 42. Accordingly, the base support part 143 and the protrusion 425 may maintain a contact state with each other, and a stable support state is maintained even when the operation part 40 is rotated.

In addition, a step portion 144 is formed around the cover hole 141 so that the circumference of the manipulation portion 40 is seated. Accordingly, it is possible to additionally support the manipulation unit 40, and the rotation of the manipulation unit 40 can be made stably.

The operation unit 40 may include the operation unit base 42, the operation unit PCB 43, and the operation unit cover 44. The operation unit base 42 forms a lower exterior of the operation unit 40 and is mounted in the cover hole 141 to support the operation unit 40 so as to be rotatable on the top cover 14.

The operation part base 42 may be formed to have the same diameter as the cover hole 141. In addition, the circumference of the operation unit base 42 may extend upward, and is combined with the operation unit cover 44 to form a space therein.

Rotation connection portions 421 extending downward may be further formed on both sides of the lower surface of the manipulation unit base 42. The rotation connection part 421 may be coupled to the rotator 21, and may be connected to each other so that the rotator 21 and the operation unit 40 can be rotated together.

Mounting bosses 422 and 423 for fixed mounting may be protruded inside the operation part base 42 by screwing the operation part PCB 43. In addition, a wire hole 424 through which an electric wire connected to the manipulation unit PCB 43 enters and exits may be further formed on a bottom surface of the manipulation unit base 42.

The mounting bosses 422 and 423 for supporting the manipulation unit PCB 43 are formed higher than the mounting boss 422 positioned at the rear than the mounting boss 423 positioned at the front. Accordingly, the manipulation unit PCB 43 may be disposed to be inclined so that the rear end is higher than the front end. In this case, the inclination of the PCB 43 of the manipulation unit may be formed to correspond to the inclination of the top surface 441 of the manipulation unit.

The operation unit PCB 43 is equipped with a plurality of operation members for manipulating the operation of the water purifier 1. The operation member may be composed of a switch or a sensor, and various types of input devices capable of inputting signals by user manipulation may be used.

For example, the manipulation unit PCB 43 may be provided with a plurality of touch sensors 431. The touch sensor 431 is for detecting a user's touch, and various types of touch sensors such as a resistive film method, a capacitance method, an ultrasonic method, and an infrared method may be used.

The plurality of touch sensors 431 are configured to select and manipulate various functions, such as a function of selecting purified water and cold water or hot water, a function of adjusting the temperature of hot water, and a function of adjusting the amount of water to be taken out, through a user's touch input. .

In addition, a switch 432 may be provided on one side of the operation unit PCB 43. The switch 432 is a general switch operated by a pressing operation and is pressed by the operation of the eject button 41. When the switch 432 is turned on or off, the valves 366, 367, and 369 for the water outlet may be selectively driven, and selected water among purified water, cold water, or hot water may be discharged.

In addition, a plurality of LEDs 433 and 434 may be provided in the control unit PCB 43. The plurality of LEDs 433 and 434 are for displaying information and may display positions or operation states of the plurality of touch sensors and switches.

In detail, the plurality of LEDs 433 and 434 include a sensor LED 433 disposed adjacent to the touch sensor 431 in order to display the location of the touch sensor 431 or the operation state of the water purifier 1. , It may be configured as a switch LED 434 disposed at a position adjacent to the switch 432 to display operation information of the water purifier 1.

A separate display device may be further provided on the manipulation unit PCB 43, and the operation state of the water purifier 1 may be output to the outside by the display device.

In addition, a buzzer 435 may be installed on the control panel PCB 43. The buzzer 435 may output an operating state of the water purifier 1 by voice. For example, in the event of an abnormal operation of the water purifier 1, it may be notified by outputting it as a sound, and at this time, the sound may be output as a sound having a specific pattern or a beep sound to deliver information to the user. Of course, it will be possible to transmit the operation state through the buzzer 435 even in a general operation situation other than an abnormal operation situation.

The operation part base 42 is coupled by the operation part cover 44. The operation part cover 44 forms an upper shape of the operation part 40, and forms the exterior of the operation part 40 exposed to the outside when the operation part 40 is mounted on the top cover 14. do.

The lower surface of the operation part cover 44 may be formed in a circular shape corresponding to the upper surface of the operation part base 42, and the upper surface of the operation part cover 44 may be formed to be inclined. That is, the operation part cover 44 may be formed in a shape having a low front end and a high rear end, and the upper surface 441 may be formed to have an inclination. The inclination of the upper surface 441 of the operation part cover 44 is formed to correspond to the inclination of the operation part PCB 43 to improve the operability of the touch sensor 431 and the switch 432 while improving the user's operation convenience and readability. The effect that can be improved can be expected.

A plurality of sensor holes 442 are formed on the upper surface of the operation part cover 44. The sensor hole 442 is opened at a position corresponding to the touch sensor 431. Accordingly, the user can operate the touch sensor 431 by touching a point corresponding to the sensor hole 442.

In addition, a button hole 443 is formed in the operation part cover 44. The button hole 443 is opened so that a part of the ejection button 41 can enter and exit, and may be located above the switch 432. In addition, a button hook portion 444 to which the eject button 41 is fixedly mounted is further formed outside the button hole 443. The button hook part 444 may be formed in a hook shape that can be inserted into the hook hole 414 of the take-out button 41. The button hook portion 444 extends through the hook hole 414, and its end portion is formed in a shape of a hook so that it can be caught and restrained. Accordingly, the ejection button 41 is mounted at an exact position on the operation part cover 44, and the mounting position can be fixed and maintained.

The eject button 41 is disposed on the lower surface of the button hole 443. In addition, a button plate 411 may be provided on an upper surface of the take-out button 41 to shield the opening of the take-out button 41 and to be exposed to the outside. The button plate 411 may be formed to be transparent or translucent, and formed so that the light irradiated from the switch LED 434 provided on the operation part PCB 43 at a position corresponding to the button hole 443 is transmitted. Can be. In addition, a button ring 412 is provided around the button plate 411. The button ring 412 is configured to shield a space between the button plate 411 and the button hole 443.

Meanwhile, an adhesive sheet 45 is provided on the upper surface of the operation part cover 44, and an operation part plate 46 is provided on the upper surface of the adhesive sheet 45 to form the upper surface of the operation part 40. Since the operation part plate 46 forms an exterior, it may be formed of a glass or a high-gloss plastic or metal material. In addition, the operation part plate 46 may be formed of a transparent or translucent material, and the light irradiated from the sensor LED 433 in a position adjacent to the touch sensor 431 is transmitted so that the user can more easily identify the operation position. You can do it. If necessary, the position of the touch sensor or the user's touch operation position may be displayed on the operation part plate 46 by surface processing or printing.

A hole 461 corresponding to the button plate 411 may be formed in the manipulation part plate 46, and the button plate 411 is positioned in the hole 461 to allow independent flow. In addition, the operation part plate 46 and the button plate 411 may be formed of the same material to have a sense of unity in appearance.

7 is a perspective view of an eject button of the water purifier as viewed from above. And, Fig. 8 is a perspective view of the ejection button as seen from below. And, Figure 9 is a view showing the lighting state of the switch LED of the water purifier. And, Figure 10 is a view showing the operation state of the eject button.

As shown in the drawing, the eject button 41 is mounted on the lower surface of the operation part cover 44, and hook holes 414 may be formed at four corners. The hook hole 414 is formed so that the rim extends upward and the button hook portion 444 is inserted to be coupled to each other.

In the center of the ejection button 41, a pressing part 413 that is operated by a user and flows by the user's operation may be formed. The pressing part 413 may be formed to have a size corresponding to the size of the button hole 443 so as to be positioned inside the button hole 443. In addition, the pressing part 413 protrudes upward so that at least a portion of the pressing part 413 is located inside the button hole 443 so that a user can press it.

A light transmitting part 4131 is formed in the center of the pressing part 413, and the light transmitting part 4131 may be shielded by the button plate 411. A plate rib 4132 through which the button plate 411 can be pressed may be formed outside the light transmitting part 4131.

In addition, a step portion 4111 to be seated on the plate rib 411 is formed around the button plate 411. In addition, the button plate 411 has an insertion part 4112 protruding, and the insertion part 4112 is formed in a shape corresponding to the light transmitting part 4131 to be inserted into the light transmitting part 4131. I can.

Further, a light guide 4133 extending downwardly along the circumference of the light transmitting part 4131 may be further formed on a lower surface of the pressing part 413. The light guide 4133 may extend from the light transmitting part 4131 toward the manipulation part PCB 43. At this time, the light guide 4133 is spaced apart from the manipulation part PCB 43 by a predetermined interval so as not to interfere with the manipulation part PCB 43 when the pressing part 413 flows.

In addition, the switch LED 434 is positioned on the manipulation unit PCB 43 corresponding to the inner region of the light guide 4133. A plurality of switch LEDs 434 may be mounted, and one switch LED 434 may be formed to irradiate light of various colors.

In addition, the light irradiated from the switch LED 434 is moved along the light guide 4133 to pass through the light transmitting part 4131 and pass through the button plate 411. Accordingly, the user can check the light irradiated through the ejection button 41, and the life of the filter 34 or selection of hot water, cold water, or purified water through the color of the light appearing through the ejection button 41 You can check the status.

For example, when the life of the filter 34 is over, the ejection button 41 emits a blue light, and when the life of the filter 34 is over and needs replacement, it emits an orange light. The status of the filter 34 can be immediately communicated to the user, and the replacement cycle of the filter 34 can be notified.

An elastic part 4134 formed by cutting along the circumference of the pressing part 413 may be formed around the pressing part 413. The elastic part 4134 may be configured by a plurality of cutouts 4135, and when the pressing part 413 is pressed, the elastic part 4134 may be moved while being elastically deformed downward from the upper surface of the ejection button 41, When the hand is released, the pressing part 413 can be returned to its original position by an elastic restoring force.

Meanwhile, a rotation support part 4136 is formed protruding from a front end (left in FIG. 10) of the pressing part 413, and a contact part 4137 is formed at a rear end of the pressing part 413. The rotation support part 4136 is formed to protrude downward and maintains a state in contact with the base support part 426 of the operation part base 42 when the take-out button 41 is mounted.

Therefore, no matter where the pressing part 413 is pressed, the pressing part 413 rotates clockwise (as seen in FIG. 9) around the rotation support part 4136 as an axis. In particular, when the pressing part 413 is rotated, the rotation distance of the contact part 4137 located in the opposite direction to the rotation support part 4136 becomes large enough to push the switch 432.

The contact part 4137 is located above the switch 432 and is kept away from the switch 432 before the pressing part 413 is pressed. In addition, when the pressing part 413 is pressed, the pressing part 413 rotates about the rotation support part 4136, so that the contact part 4137 presses the switch.

Due to this structure, even if the user presses any position of the pressing part 413, the contact part 4137 can accurately press the switch 432. In addition, by positioning the switch 432 more outside than the light transmitting part 4131, the switch LED 434 can be positioned at the opening position of the eject button 41, and the eject button 41 is Through this, light irradiated from the switch LED 434 can be transmitted.

11 is a perspective view of the rotator of the water purifier as viewed from above. And, Figure 12 is a view of the head office from the bottom of the rotator. And, Figure 13 is an exploded perspective view of the rotator of the water purifier. And, FIG. 14 is a view showing a flow path structure inside the rotator and a water outlet.

As shown in the figure, the rotator 21 includes a rotator housing 22. The rotator housing 22 is formed in a cylindrical shape having a hollow portion inside and having a height shorter than that of a diameter.

The rotator 21 includes an upper guide bracket 23 and a lower guide bracket 24 spaced apart from each other at an upper and lower portion of the rotator housing 22. In addition, a fastening part 221 is formed protruding from the inner surface of the rotator housing 22, and fastening holes 231 and 241 are formed at intervals in the circumferential direction between the upper guide bracket 23 and the lower guide bracket 24. . A bolt or the like may be inserted into the fastening part 221 through the fastening holes 231 and 241 so that the upper and lower guide brackets 24 may be fastened to the inner side of the rotator housing 22 to be spaced apart from each other.

In addition, a plurality of fastening hooks 237 and 247 may be formed along the circumference of the upper guide bracket 23 and the lower guide bracket 24, and a fastening protrusion 222 may be formed on the inner surface of the rotator housing 22. have. The fastening hooks 237 and 247 and the fastening protrusion 222 may be engaged with each other and serve as a temporary fix when the upper guide bracket 23 and the lower guide bracket 24 are coupled.

The rotator 21 further includes rail receiving grooves 232 and 242 formed concave in the circumferential direction in the upper guide bracket 23 or the lower guide bracket 24. The rail accommodating grooves 232 and 242 include a lower rail accommodating groove 242 accommodating a first rotation guide rail 332 formed in the upper cover 111, and a second rotation guide formed at the rotator mounting portion 331 It may be composed of an upper rail accommodating groove 232 for accommodating the rail 1111.

Protruding upward or downward from one side of the upper rail receiving groove 232 or the lower rail receiving groove 242, or upward from one side of the upper rail receiving groove 232 and the lower rail receiving groove 242 Rotation guide protrusions 233 and 243 protruding in the upward and downward directions are formed.

The rotator 21 includes a circular upper center ring 234 and a lower center ring 244 respectively disposed in the centers of the upper guide bracket 23 and the lower guide bracket 24. The upper connecting portion 235 and the lower connecting portion 245 are formed horizontally extending from the upper guide bracket 23 and the lower guide bracket 24 to the upper center ring 234 and the lower center ring 244, respectively, The upper center ring 234 and the lower center ring 244 are connected to and supported by the upper guide bracket 23 and the lower guide bracket 24 by the upper connection part 235 and the lower connection part 245. Each of the upper and lower connecting portions 245 has a fan shape and has a plurality of through holes therein.

The upper center ring 234 and the lower center ring 244 are formed to inform the operator of the installation position of the water outlet pipe through which the water to be taken out flows. The upper center ring 234 and the lower center ring 244 are formed in the center of the rotator 21 and become rotation centers when the rotator 21 rotates.

In addition, a T connector 264 may be provided on the upper center ring 234 and the lower center ring 244. One side of the T connector 264 extends toward the water outlet 20 and is connected to a water outlet pipe 261 connected to the water outlet nozzle 25, and on the other two sides, a cold water pipe 265 is connected to the upper and lower A water purification pipe 263 is connected to the. In this case, the purified water pipe 263 and the cold water pipe 265 may be connected to the T connector 264 by a rotating pipe 264.

At this time, the cold water pipe 265 and the purified water pipe 263 pass through the upper central ring 234 and the lower central ring 244, respectively, and the T connector 264 is the upper central ring 234 and the lower It is located in the space between the center ring 244. Therefore, the T connector 264 can always maintain a constant position without changing its position.

Meanwhile, the rotation tube 264 may be formed of a stainless material. In addition, fitting grooves 2641 may be formed along the circumferences of the upper and lower portions of the rotating tube 264. When the upper and lower ends of the rotary tube 264 are coupled to the T connector 26, a collet of metal is inserted into the fitting groove 2241.

Accordingly, when the rotator 21 is rotated, the T connector 26 may be rotated about the rotation pipe 264, and twisting of a pipe forming a flow path for water outlet can be prevented. In particular, the rotating tube 264 is formed of a stainless material, so that it is not damaged or deformed even when repeatedly rotated by the rotation of the rotator 21 and a collet of a metal material is combined, so that leakage can be prevented.

Meanwhile, the hot water pipe 262 connected to the hot water tank 71 to supply hot water may be directly connected to the water outlet nozzle 25 without passing through the water outlet 20. Accordingly, when hot water is taken out, water from the hot water tank 71 can be immediately taken out, and the quality of hot water is improved. That is, when a flow path common to cold water or purified water is used, there is a problem in that the temperature of the cold water remaining on the flow path or hot water first taken out by the purified water when hot water is taken out cannot satisfy the temperature. However, when the separate hot water pipe 262 is connected to the water outlet nozzle, the hot water from the hot water tank 71 can be supplied to the water outlet nozzle 25 as it is without loss of temperature.

The coupling rings 236 and 246 have a circular coupling hole formed therein, and a pair may be provided on both left and right sides. The pair of coupling rings 236 and 246 disposed on both sides may be disposed symmetrically with respect to a center line crossing the axis of rotation of the rotator 21 in a radial direction. The coupling rings 236 and 246 may be formed on both the upper guide bracket 23 and the lower guide bracket 24 or may be formed only on the upper guide bracket 23.

The coupling rings 236 and 246 may be coupled to the rotation connection part 421 on the bottom of the operation part 40. In detail, the pair of rotation connection parts 421 may be inserted through the coupling rings 236 and 246, and thus the operation part 40 may be rotated together when the rotator 21 is rotated.

When the operation part 40 and the rotator 21 rotate together by the combination of the operation part 40 and the rotator 21, the take-out button 41 and the water outlet 20 also rotate together. Accordingly, as the ejection button 41 and the water outlet nozzle 25 are positioned in the same line and rotated, the user's operability can be improved because the ejection button 41 and the water outlet nozzle 25 do not need to be separately aligned.

Meanwhile, an oil damper 27 may be provided on the bottom surface of the rotator 21, that is, the lower guide bracket 24. The oil damper 27 allows the rotator 21 to rotate smoothly without a feeling of being caught when the water outlet 20 rotates, and the rotator 21 rotates at a constant speed by simply applying a certain amount of force. To be able to be.

The oil damper 27 is a general configuration used to make the rotation speed constant, and a detailed description thereof will be omitted. In addition, a pinion gear 271 is coupled to the rotation axis of the oil damper 27, and the pinion gear 271 is arranged to move along the internal gear 331 formed on the upper end of the filter bracket 30. do.

The pinion gear 271 is formed in a circular shape with a radius of curvature that is much smaller than that of the internal gear 331, and the number of teeth is also small. When the rotator 21 is mounted on the upper end of the filter bracket 30, the pinion gear 271 is located on the inner surface of the internal gear 331 and is engaged with the internal gear 331.

15 is a partial perspective view of a filter bracket of the water purifier. And, Figure 16 is a cross-sectional view showing the coupling structure of the rotator.

As shown in the figure, an internal gear 331 is formed on the upper end of the filter bracket 30. The internal gear 331 may be formed at an upper end of the rotator mounting portion 33 with a constant curvature. In addition, the internal gear 331 is formed to be spaced apart from the first rotation guide rail 332 in the radial direction. The internal gear 331 may be located adjacent to the outer edge of the upper end of the filter bracket 30 and may be disposed concentrically with the first rotation guide rail 332. Accordingly, when the rotator 21 is mounted, the internal gear 331 may be configured to mesh with the pinion gear 271.

Meanwhile, the rear surface of the filter bracket 30 is opened to the rear, and the rear end of the filter bracket 30 is coupled to the front end of the side panel 15. The first rotation guide rail 332 is provided at an upper end of the filter bracket 30 so that the rotator 21 is rotatably mounted in the left and right directions.

The first rotation guide rail 332 may have a semicircular curvature to guide the rotation of the rotator 21. The first rotation guide rail 332 may be formed to be fixed inside the upper end of the filter bracket 30.

In addition, a second rotation guide rail 1111 protruding from the inner circumferential surface of the upper cover 111 may be further provided. The second rotation guide rail 1111 is positioned above the first rotation guide rail 332 and has the same shape to guide the rotation of the rotator 21.

The first rotation guide rail 332 and the second rotation guide rail 1111 are disposed to be spaced apart from each other in the vertical direction with the rotator 21 interposed therebetween. Therefore, by mounting the rotator 21, the upper and lower ends of the rotator 21 are coupled with the first rotation guide rail 332 and the second rotation guide rail 1111 to guide the rotation of the rotator 21. do.

The rotator 21 is a component for horizontally rotating the water outlet 20 to the left or right. The rotator 21 does not have a rotation axis in the center, has rotation guide protrusions 233 and 243 formed at a constant curvature in the center, and can slide along the rotation guide rails 332 and 1111 using the rotation guide protrusions 233 and 243 Are combined together.

The rotation guide protrusions 233 and 243 are provided in the rotator 21, and the rotation guide rails 332 and 1111 are provided in the filter bracket 30 and the upper cover 111, but the rotation guide protrusions The 233 and 243 and the rotation guide rails 332 and 1111 have the same curvature and are coupled to be engaged with each other to guide the rotation of the rotator 21.

In detail, for example, the rotation guide protrusions 233 and 243 have a lower rotation guide protrusion 243 protruding downward from the lower rail accommodating groove 242 of the lower guide bracket 24, and the upper guide bracket 23 It may be composed of an upper rotation guide protrusion 233 protruding upward from the upper rail receiving groove 232 of the.

In addition, ends of the rotation guide protrusions 233 and 243 have a hook shape. When the rotation guide protrusions 233 and 243 and the rotation guide rails 332 and 1111 are combined, the inner circumferential surfaces of the ends of the rotation guide protrusions 233 and 243 face each other and overlap in the thickness direction to be contacted. I can.

The rotation guide protrusions 233 and 243 are formed with the same curvature as the rotation guide rails 332 and 1111 and are slidably coupled to the rotation guide rails 332 and 1111 in the rotation direction. In addition, when the rotation guide protrusions 233 and 243 and the rotation guide rails 332 and 1111 are coupled, the rotation guide rails 332 and 1111 are accommodated in the rail receiving grooves 232 and 242 formed in the inside of the rotation guide protrusions 233 and 243. One side of the rail receiving grooves 232 and 242 and the rotation guide rails 332 and 1111 overlap in the thickness direction, and the ends of the rotation guide protrusions 233 and 243 are formed in a hook shape to overlap the rotation guide rails 332 and 1111 in the thickness direction. Are very combined.

According to such a coupling structure, the water outlet 20 can be stably rotated, and the position of the water outlet nozzle 25 can be freely changed without separating the water outlet 20. In this case, there is no need to separately form a rotation shaft at the center of the rotator 21.

For example, in a structure in which the water outlet 20 protrudes forward from one side of the rotator 21, even if the water outlet 20 is rotated by holding the rotator 21, the eccentric load of the water outlet 20 It is possible to solve a problem in that the water outlet 20 is lifted up or lowered so that the rotation of the water outlet 20 and the rotator 21 becomes unstable. In addition, by the hook shape of the rotation guide protrusions 233 and 243, it is possible to prevent the rotator 21 from being removed.

In addition, since the contact area between the rotation guide protrusions 233 and 243 and the rotation guide rails 332 and 1111 is wide when the rotator 21 rotates, the eccentric load can be distributed when rotating while holding the water outlet 20, It can reduce damage such as abrasion and scratches caused by friction.

It is preferable that the rotation guide protrusions 233 and 243 formed on the upper guide bracket 23 and the lower guide bracket 24 are formed of a different material from the rotation guide rails 332 and 1111. More preferably, the rotation guide protrusions 233 and 243 may be formed of engineering plastics (POM) having excellent fatigue resistance, toughness, and abrasion resistance. Therefore, when the rotation guide protrusions 233 and 243 rotate along the rotation guide rails 332 and 1111, wear and noise due to friction between the rotation guide protrusions 233 and 243 and the rotation guide rails 332 and 1111 can be reduced.

17 is a view as viewed from the rear of the arrangement of the valve mounted on the filter bracket.

As shown in the figure, on the rear surface of the filter bracket 30, a temperature sensor bracket 76, 361 and a flow sensor 363, a water outlet valve 367, a cold water outlet valve 366, a flow control valve ( 368) may be provided. These valves are disposed in an area above the support plate 35 in more detail on the rear surface of the filter bracket 30 so that the space inside the water purifier 1 can be efficiently used.

First, the water supply valve 361 is connected to a pipe connected to the outlet side of the filter 34 to determine the flow of water supplied from the filter 34. In addition, a flow rate sensor 363 is provided at the outlet side of the water supply valve 361 to detect the flow rate of water passing through the water supply valve 361.

The pipe connected to the outlet of the flow sensor 363 is connected to the branch pipe 364. The outlet of the branch pipe 364 is branched into a cold water side 3641 and a hot water side 3642, respectively. The pipe connected to the cold water side 3642 of the branch pipe 364 is branched again by the T connector 365 to be branched into the cold water side 3651 and the purified water side 3652. The cold water side 3651 and the purified water side 3652 are connected to the cold water outlet valve 366 and the purified water outlet valve 367, respectively, so that the supply of purified water and cold water can be determined.

The purified water outlet valve 367 is connected to the purified water pipe 263, and the purified water pipe 263 is extended and connected to one side of the T connector 26 by a rotary pipe 264. In addition, the cold water outlet valve 366 is connected to a cooling tank to supply purified water to the cooling tank 60 for cooling. In addition, a cold water pipe 265 is connected to the outlet of the cooling tank 60, and the cold water pipe 265 is extended and connected to the other side of the T connector 26 by the rotation pipe 264.

Meanwhile, a pipe connected to the hot water side 3642 of the branch pipe 364 is connected to the flow control valve 368. The flow rate control valve 368 is to adjust the flow rate of water supplied to the hot water tank 71, so that the temperature of the water passing through the hot water tank 71 can be heated to a predetermined temperature or higher through the adjustment of the flow rate. do.

In detail, if the amount of water passing through the hot water tank 71 is too large, water passing through the hot water tank 71 at a high speed cannot be effectively heated, and in such a situation, the temperature condition of hot water cannot be satisfied. Situations may arise.

Accordingly, when hot water is to be taken out, water may be heated by adjusting the amount of water supplied to the hot water tank 71. In addition, even when the temperature of the supplied water is too low, the heating performance in the hot water tank 71 may be improved by reducing the amount of water introduced.

Meanwhile, although not shown in detail, an inlet temperature sensor may be provided at either side of the inlet or outlet of the flow control valve 368 or the flow control valve 368, and the flow rate is controlled by the inlet temperature sensor. It may be configured to adjust the opening degree of the valve 368.

The pipe connected to the outlet of the flow control valve 368 is connected to the inlet of the hot water tank 71, the outlet of the hot water tank 71 is connected to the hot water outlet valve 369, and the hot water outlet valve 369 Hot water discharge is determined by opening and closing ). The hot water outlet valve 369 is connected to the hot water pipe 262, and the hot water pipe 262 is connected to the water outlet nozzle 25 of the water outlet unit 20 to be discharged to the outside.

18 is an exploded perspective view of a water outlet of the water purifier. And, Figure 19 is a cut-away perspective view of the water outlet.

As shown in the drawing, the water outlet 20 may extend from the rotator housing, and communicate with the inner side of the rotator housing 22 to allow the water outlet pipe 261 and the hot water pipe 262 to flow in. It is structured to be.

The water outlet 20 may include a water outlet housing 201 and a water outlet cover 202. The upper surface of the water outlet housing 201 is opened, and a space in which the water outlet pipe 261 and the hot water pipe 262 can be disposed is formed. In addition, the water outlet cover 202 is formed to shield the opened upper surface of the water outlet housing 201.

A water outlet hole 2011 may be formed on a bottom surface of the water outlet housing 201, and the water outlet nozzle 25 may be mounted in the water outlet hole 2011. In addition, the water outlet pipe 261 and the hot water pipe 262 connected to the water outlet nozzle 25 are guided to the inside of the rotator housing 22 through the inner side of the water outlet housing 201.

The water outlet nozzle 25 includes a cold water connection part 251 and a hot water connection part 252 to be independently connected to the water outlet pipe 261 and the hot water pipe 262, respectively. The cold purified water connection part 251 is formed to extend through one side of the water outlet nozzle 25 and is connected to the water outlet pipe 261. In addition, the hot water connection part 252 is formed to extend through the other side of the side surface of the water outlet nozzle 25 and is connected to the hot water pipe 262. Therefore, it is possible to independently take out cold water, purified water, and hot water through one of the water outlet nozzles 25.

A nozzle fixing part 253 is further formed on the other side of the water outlet nozzle 25 to fix the water outlet nozzle 25 to the water outlet housing 201 by a screw. In addition, the water outlet nozzle 25 is formed to be opened vertically to facilitate molding, and a nozzle cap 254 may be mounted on the opened upper surface of the water outlet nozzle 25.

In addition, a writing hole 2012 may be further formed on the bottom surface of the water outlet housing 201. The lighting hole 2012 allows light irradiated from the lighting unit 28 provided inside the water outlet housing 201 to be irradiated downward. In addition, a fixing protrusion 2013 to which the lighting unit 28 is fixedly mounted may be further formed on the bottom of the water outlet housing 201 adjacent to the lighting hole 2012.

The lighting unit 28 irradiates light toward the bottom of the water outlet 20 so as to show a water ejection state when operating the ejection button 41 or to check the amount of water filled in the water cup. It may be composed of (281) and a light PCB (282).

The light housing 281 is formed such that the upper surface thereof is opened, and the light PCB 282 is mounted therein. Further, a housing coupling portion 2811 extending outward is formed at a rear end of the light housing 281, and the housing coupling portion 2811 is formed to be engaged with the fixing protrusion 2013 to be engaged with the light housing 281. This ensures that it can be fixedly mounted in the correct position.

In the light housing 281, a transmissive portion 2812 capable of transmitting light is formed at a position corresponding to the writing hole 2012. The transmissive part 2812 may be configured by opening a part of the light housing 281 and mounting a transparent member at the opened position, and the light housing 281 itself may be formed to be transparent. The transmission part 2812 is formed to protrude from the light housing 281 and is formed to be inserted into the writing hole 2012. Accordingly, the transmissive portion 2812 allows the light housing 281 to be mounted in an accurate position together with the housing coupling portion 2811.

A light guide 2814 is extended along the periphery of the transmissive part 2812, and the light guide 2814 allows light from the LED 2821 mounted on the light PCB 282 to pass through the lighting hole 2012. It is guided so that it can be investigated to the outside.

In addition, a PCB support part 2813 for supporting the light PCB 282 may be extended in the center of the light housing 281. The light PCB 282 is seated on the PCB support portion 2813, and a screw penetrates the light PCB 282 and is fastened to the PCB support portion 2813 to fix the light PCB 282.

The light PCB 282 is formed in a size and shape capable of shielding the opened upper surface of the light housing 281, and is mounted on the PCB support part 2813. The LED 2821 is mounted on the light PCB 282, and when the light PCB 282 is mounted, the LED 281 may be positioned at a position corresponding to the light guide 2814.

The water outlet cover 202 is seated on the upper end of the water outlet housing 201 to form an upper surface of the water outlet 20. In addition, cover coupling portions 2021 extending downward may be formed at both side ends of the water outlet cover 202. The cover coupling part 2021 may be coupled with a coupling protrusion 2014 protruding from the inner wall of the light housing 281, and the water outlet cover 202 is coupled to the water outlet housing 201 To be able to maintain.

20 is a perspective view of a heating and control module of the water purifier.

As shown in the drawing, the heating and control module 50 may be configured by combining the induction heating assembly 70 and the control assembly 80. The induction heating assembly 70 and the control assembly 80 may be combined in a single module state, and may be fixedly mounted on the support plate 35 as shown in FIG. 2. The heating and control module 50 may be disposed in a space between the filter bracket 30 and the cooling tank 60, and disposed between the top cover 14 and the support plate 35.

The induction heating assembly 70 is configured to heat purified water by an induction heating (IH) method. In addition, the induction heating assembly 70 is formed in an outer shape by a hot water case 10 coupled to the control assembly 80, and a hot water tank 71 and a working coil 72 inside the hot water case 10 Each component of the induction heating assembly 70 including) may be accommodated.

The control assembly 80 is for controlling the overall operation of the water purifier 1, and induction heating for controlling the main PCB 82 and the induction heating assembly 70 for controlling the compressor 51 and various valves The PCB 84, the power supply PCB 86 for supplying power, and the NFC (Near Field Communication) PCB 88 are configured to be mounted respectively.

To this end, the control assembly 80 shields the control base 81 and the first control cover 83 shielding the rear surface of the control base 81, the second control cover 85 shielding the front surface, and the side surface. The external shape may be formed by the third control cover 87.

21 is a perspective view of the induction heating assembly of the water purifier as viewed from the front. And, Figure 22 is a perspective view of the induction heating assembly viewed from the rear. And FIG. 23 is an exploded perspective view of the induction heating assembly.

As shown in the drawing, the induction heating assembly 70 is configured to receive purified water that has passed through the filter 34 and heat it with hot water, and is configured to be heated by an induction heating method.

The induction heating assembly 70 includes a hot water tank 71 through which purified water passes, a working coil 72 for heating water passing through the hot water tank 71, and the working coil 72 and a hot water tank ( 71) may be configured to include a heating bracket 73 is mounted.

The heating bracket 73 provides a mounting space for the hot water tank 71, the working coil 72, and the ferrite core 74. In addition, the heating bracket 73 may be formed of a resin material that is not deformed or damaged even at high temperatures.

A bracket coupling part 731 for coupling with the control assembly 80 is formed at the corner of the heating bracket 73. A plurality of bracket coupling portions 731 may be provided, and an extended end portion of the bracket coupling portion 731 may be formed to have a different shape, and may be formed to have directionality. Accordingly, the induction heating assembly 70 may have a structure matching each of the control assembly 80, and the induction heating assembly 70 may be mounted in an accurate position.

In addition, an edge 732 having a predetermined width is formed along the edge of the heating bracket 73 to accommodate the hot water tank 71 and the working coil 72 on both sides of the heating bracket 73, respectively. It forms a space that can be used.

In addition, a bracket depression 733 for mounting the temperature sensor bracket 76 may be further formed at the center of one surface of the heating bracket 73 on which the hot water tank 71 is mounted. The bracket recessed part 733 is recessed in a corresponding shape so that the temperature sensor bracket 76 can be press-fitted. In addition, an opening 7331 through which a wire connected to the hot water temperature sensor 761 and the fuse 762 enters and exits is formed in the center of the bracket depression 733.

A hot water temperature sensor 761 for measuring the temperature of the hot water tank 71 may be mounted on the temperature sensor bracket 76. The hot water temperature sensor 761 measures the temperature in the center of the hot water tank 71, so that it is possible to determine the temperature of the hot water without directly measuring the temperature of the hot water inside the hot water tank 71. Accordingly, the temperature of the hot water taken out by the hot water temperature sensor 761 is maintained in an appropriate range. That is, it may be controlled by determining whether to further heat or stop heating according to the temperature sensed by the hot water temperature sensor 761.

In addition, a fuse 762 may be mounted on the temperature sensor bracket 76. The fuse 762 cuts off the power of the induction heating assembly 70 when the water in the hot water tank 71 is excessively overheated.

A sensor mounting groove 763 in which the hot water temperature sensor 761 is mounted is formed on the rear surface (right side in FIG. 23) of the temperature sensor bracket 76 in contact with the hot water tank 71. Accordingly, the hot water temperature sensor 761 is in contact with the hot water tank 71 and can effectively measure the surface temperature of the hot water tank 71. In addition, a fuse mounting groove 764 in which the fuse 762 is mounted is formed on the front surface of the temperature sensor bracket 76. A fuse mounting protrusion 7332 is formed in the bracket depression 733 corresponding to the fuse mounting groove 764 so that the fuse 762 can be fixed by mounting the temperature sensor bracket 76.

A working coil 72 is provided on the front surface of the heating bracket 73. The working coil 72 forms a magnetic line of force that causes heat generation of the hot water tank 71. When current is supplied to the working coil 72, a magnetic field line is formed in the working coil 72, and the magnetic field line affects the hot water tank 71, and the hot water tank 71 is affected by the magnetic field line. Fever.

The working coil 72 is disposed on the front surface of the heating bracket 73 and is disposed to face one side of the hot water tank 71 in a planar shape. In addition, the working coil 72 is made of several strands of copper or other conductor wires, and the strands are insulated. The working coil 72 forms a magnetic field or a line of magnetic force by the current applied to the working coil 72.

Accordingly, the front surface of the hot water tank 71 facing the working coil 72 generates heat by being influenced by the magnetic force line formed by the working coil 72. In FIG. 23, the strands of the working coil 72 are not shown in detail, and only the overall outline of the working coil 72 formed by winding each strand to the outside of the bracket depression 733 is shown.

Mica sheets 75 are provided on the front and rear surfaces of the working coil 72. The mica sheet 75 corresponds to the shape of the front and rear surfaces of the working coil 72 and shields the entire front and rear surfaces of the working coil 72.

The mica sheet 75 has a predetermined thickness. Therefore, in the hot water tank 71 and the ferrite core 74, the working coil 72 is maintained at a certain interval so that the hot water tank 71 is effectively heated by the magnetic field line formed by the working coil 72. You will be able to. Of course, the mica sheet 75 may be provided only on one of the front and rear surfaces of the working coil 72 as necessary.

In addition, a ferrite core 74 is provided on the front surface of the mica sheet 75. The ferrite core 74 is for suppressing current loss and serves as a shielding film for magnetic field lines. The working coil 72 may include a plurality of ferrite cores 74, and the plurality of ferrite cores 74 may be radially disposed based on a central portion of the working coil 72.

Core fixing parts 734 and 735 are formed in the heating bracket 73 to fix the ferrite core 74. The core fixing parts 734 and 735 are composed of an inner fixing part 734 and an outer fixing part 735, and are protruding from a position corresponding to a position where the ferrite core 74 is disposed. The inner fixing part 734 supports a surface close to the rotation center of the working coil 72 among the circumferential surfaces of the ferrite core 74, and the outer fixing part 735 is the inner fixing part 734 It is positioned on a surface facing the ferrite core 74 to support one side of the circumferential surface of the ferrite core 74. The core fixing portions 734 and 735 may be formed in a radial shape like the arrangement of the ferrite core 74.

The hot water tank 71 is mounted on the rear surface of the heating bracket. The hot water tank 71 is configured to generate heat under the influence of a magnetic force line formed by the working coil 72. Accordingly, the purified water is heated while passing through the inner space of the hot water tank 71 to become hot water.

In addition, the overall shape of the hot water tank 71 may be formed in a flat and compact shape. In addition, the hot water tank 71 is formed to correspond to the overall shape of the induction heating assembly 70 so that the induction heating assembly 70 is disposed between the filter bracket 30 and the cooling tank 60 in the water purifier 1. It will be able to be accommodated in the space. In addition, the hot water tank 71 is formed to have a large area, so that a heating area can be sufficiently secured and instantaneous heating is possible.

The hot water tank 71 is formed by bonding the circumferences of a first cover 711 having a planar shape and a second cover 712 having an uneven shape. In addition, an output pipe 713 through which heated water is discharged is formed at an upper end of the hot water tank 71, and an input pipe 714 through which water for heating is supplied is formed at a lower end of the hot water tank 71. The output pipe 713 extends laterally to have an upward slope, and the input pipe 714 extends laterally to have a downward slope. Accordingly, a connection space of a pipe connected to the hot water tank 71 is secured and water flow is facilitated.

A T connector 715 is connected to the output tube 713. In addition, a hot water pipe 262 connected to the hot water outlet valve 369 is connected to one side of the T connector 715 facing the output pipe 713. In addition, a safety valve 716 is provided on the other side of the T connector 715, that is, in a direction crossing the output pipe 713, that is, toward the bottom surface of the water purifier 1.

The safety valve 716 is for discharging steam generated when hot water is heated in the hot water tank 71, and prevents an excessive increase in pressure in the inside of the hot water tank 71 due to steam. . The safety valve 716 is configured to be opened at a set pressure, and may have various structures in which steam inside the hot water tank 71 can be smoothly discharged.

The outlet of the safety valve 716 is directed toward the bottom surface of the water purifier 1, and a silicone hose and an additional steam pipe 7161 are connected to the outlet of the safety valve 716. A steam pipe 7161 connected to the safety valve 716 extends to the outside of the water purifier 1 along the base 13. Accordingly, when the water purifier 1 is installed, the steam pipe 7161 is pulled out to a sink or a separate drainable tub so that the steam or water generated by the steam can be drained.

A T connector 717 is also connected to the input tube 714, and an end cap 7171 is provided on one side of the T connector 717 to shield an opening at one side of the T connector 717. In addition, a check valve 718 may be provided at one side of the T connector 717 opened downward. The check valve 718 is for supplying purified water to the input pipe 714 and is formed to be opened in a supply direction. Accordingly, when the end cap 7171 is removed while the check valve 718 is closed, water inside the hot water tank can be discharged through the input pipe 714.

Looking at this in more detail, the water purifier 1 fills the hot water tank 71 with water before shipping and tests the heating performance. After completion of this test, the water inside the hot water tank 71 is completely drained before shipment.

Accordingly, the end cap 7171 is opened to completely empty the water inside the hot water tank 71 upon shipment after the hot water tank 71 is tested. At this time, the check valve 718 is in a closed state, and the end cap 7171 has a structure to shield the opening of the T connector 717 connected to the input pipe 714 at the lower end of the hot water tank 71. Due to such structural characteristics, the water inside the hot water tank 71 can be discharged by its own weight when the end cap 7171 is opened.

Of course, the end cap 7171 may be configured as a valve capable of opening and closing operation instead of a simple stopper structure, and may be configured to empty the water inside the hot water tank 71 by the operation of the valve.

24 is a front view of the hot water tank. And FIG. 25 is a cross-sectional view 25-25' of FIG. 24.

As shown in the drawing, the hot water tank 71 is formed by coupling the edges of the first cover 711 and the second cover 712 to each other. The rim of the first cover 711 and the rim of the second cover 712 may be coupled to each other by welding or the like to maintain airtightness.

The first cover 711 has a shape of a flat plate so as to generate heat by being influenced by a line of magnetic force formed by the working coil 72. In addition, the first cover 711 may be made of an appropriate material for heat generation. The first cover 711 may be made of a stainless steel material, and preferably made of four series of stainless steel materials. More preferably, the first cover 711 may be made of STS (STainless Steel, Korean Industrial Standard) 439 material.

Since the second cover 712 is disposed on the opposite side of the working coil 72 based on the first cover 711 and has less influence of the magnetic force line, it is less related to heat generation than the first cover 711. Therefore, it is preferable that the second cover 712 is made of a material having corrosion resistance properties rather than heat generation properties. In addition, an output tube 713 and an input tube 714 are provided at the centers of the upper and lower ends of the second cover 712. The output tube 713 and the input tube 714 may extend toward opposite directions.

The second cover 712 includes a base surface 7121 and a protrusion 7122. The base surface 7121 and the protrusion 7122 may be integrally formed by pressing. When the second cover 712 having the base surface 7121 is partially pressed, the protrusion 7122 may be formed on the second cover 712.

The base surface 7121 faces the first cover 711 at a position spaced apart from the first cover 711, and is spaced apart from the first cover 711 to form an inner space of the hot water tank 71. . In addition, the protrusion 7122 protrudes from the base surface 7121 toward the first cover 711, and when the first cover 711 and the second cover 712 are joined, the protrusion 7122 is a first It may be formed to be positioned in contact with or adjacent to the cover 711. In addition, the circumference of the protruding portion 7122 may be formed to be inclined.

The protrusion 7122 is located between the input tube 714 and the output tube 713, and a plurality of the protrusions 712 are formed to disperse the flow of water flowing into the input tube 714 and discharged to the output tube 713. The residence time inside the hot water tank 71 can be lengthened.

The protrusion 7122 may include a horizontal protrusion 7112 and a vertical protrusion 7123. The vertical protrusion 7123 may extend in the same direction as the vertical direction of the hot water tank 71. Further, the horizontal protrusion 7112 is formed at both ends of the vertical protrusion 7123 and extends to have a predetermined length.

A plurality of the protrusions 7122 may be disposed at regular intervals, and preferably, one may be formed in the center and a plurality of the same number may be formed on both sides thereof. In the embodiment of the present invention, it is described for example that three are formed, but the number is not limited.

Therefore, the water flowing into the input pipe 714 collides with the horizontal protrusion 7112 below and is dispersed, flows along the vertical protrusion 7123, and then collides with the horizontal protrusion 7123 above and dispersed. After that, it is discharged to the output tube 713. And this action occurs at the same time in the plurality of protrusions (7122).

In this process, the water flowing inside the hot water tank 71 is dispersed so that the residence time in the hot water tank 71 becomes longer, so that it can be further heated. In addition, since the hot water tank 71 is spread evenly throughout the interior of the hot water tank 71, more efficient heating of the water is possible.

Meanwhile, a welding portion 7125 is formed on at least one of the plurality of protrusions 7122. The welding part 7125 is formed to protrude toward the first cover like the protruding part 7122. It is preferable that the location of the welding part 7125 is formed in the central part of the hot water tank 71. In addition, the welding part 7125 and the first cover 711 may be joined to each other by welding.

Other protrusions 7122 other than the welding part 7125 are not coupled to the first cover 711 by welding and are simply in contact with or adjacent to the first cover 711, whereas the welding part 7125 is It is in a state of being combined with the first cover 711.

Therefore, the hot water tank 71 is not deformed or damaged even when the pressure inside the hot water tank 71 is increased, which is generated when the hot water is heated, and the first cover 711 and the second cover 712 maintain their shape and are stable. You will be able to maintain the bonded state.

26 is a perspective view of the control assembly of the water purifier. And, Figure 27 is an exploded perspective view of the control assembly.

As shown in the drawing, the control assembly 80 includes a control base 81 and a first control cover 83 shielding the rear surface of the control base 81, and a second control cover 85 shielding the front surface. ) And the external shape may be formed by the third control cover 87 shielding the side.

The control base 81 may be equipped with the main PCB 82 constituting the control assembly 80, the induction heating PCB 84, the power supply PCB 86, and the NFC PCB 88. Provide space.

A first mounting surface on which the main PCB 82 is mounted is formed on the rear surface (right side in FIG. 27) of the control base 81. The main PCB 82 controls the overall operation of a water supply device such as the water purifier 1. For example, the main PCB 82 may control driving of a plurality of valves, including the compressor 51 and the cooling fan 53.

In addition, a first control cover 83 is provided on the first mounting surface 811 of the control base 81 on which the main PCB 82 is mounted. The main PCB 82 may be disposed inside a space formed by a combination of the first mounting surface 811 and the first control cover 83.

A second mounting surface 812 on which the induction heating PCB 84 is mounted is formed on the front surface of the control base 81 (left side in FIG. 27). The induction heating PCB 84 controls the induction heating operation of the working coil 72. For example, the induction heating PCB 84 controls the current to flow through the working coil 72, and the hot water tank 71 is heated by the current supplied to the working coil 72 to heat the hot water.

In addition, a second control cover 85 is provided on the second mounting surface 812 of the control base 81 on which the induction heating PCB 84 is mounted. The induction heating PCB 84 may be disposed inside a space formed by a combination of the second mounting surface 812 and the second control cover 85.

The induction heating PCB 84 consumes a lot of power, and accordingly, high-temperature heat generation may be generated. A heat dissipating member 841 may be provided in the induction heating PCB 84 to cool the induction heating PCB 84. In addition, the second control cover 85 may be provided with a heat dissipation opening 851 at a position corresponding to the heat dissipation member 841.

In addition, a coupling boss 852 coupled to the bracket coupling portion 731 of the induction heating assembly 70 may be further formed on the second control cover 85. The coupling boss 852 extends to a predetermined length at a position corresponding to the bracket coupling portion 731 and is coupled to the bracket coupling portion 731. The coupling boss 852 extends to a predetermined length so that the induction heating assembly 70 and the second control cover 85 are separated by a predetermined distance. Accordingly, the control assembly 80 is prevented from malfunctioning or being damaged by the hot water tank 71 or the induction heating assembly 70 of high temperature.

The second mounting surface 812 may form a partial area of the entire front surface of the control base 81. A cable fixing part 813 may be further formed above the second mounting surface 812 of the front surface of the control base 81. The cable fixing part 813 is formed by a pair of ring-shaped protrusions protruding forward, and allows wires connected to a plurality of PCBs to pass through and be fixed between the pair of protrusions.

A third mounting surface 814 may be formed on the side of the second mounting surface 812. The third mounting surface 814 provides a space in which the power supply PCB 86 is mounted, and may be extended to vertically cross the front surface of the control base 81.

The power supply PCB 86 is for supplying power to the induction heating PCB 84. Since the output voltage for induction heating is very high, sufficient power must be supplied. Accordingly, a separate power supply PCB 86 may be provided to supply separate power to the induction heating PCB 84 to satisfy an output voltage for induction heating. The power supply PCB 86 provides power to not only the induction heating PCB 84 but also the main PCB 82, and may provide auxiliary power to other configurations.

In addition, a third control cover 87 is provided on a third mounting surface of the control base 81 on which the power supply PCB 86 is mounted. The power supply PCB 86 may be disposed in a space formed by a combination of the third mounting surface 814 and the third control cover 87.

Meanwhile, a fourth mounting surface 815 may be formed on an upper end of the control base 81. The fourth mounting surface 815 extends in the front-rear direction to form a space in which the NFC PCB 88 can be mounted.

The NFC PCB 88 is for exchanging data with a terminal such as a mobile phone. The usage information, operation, or status information of the water purifier 1 can be transmitted to the user's terminal through the NFC PCB 88, and the setting of the water purifier 1 can be manipulated using the terminal. .

For example, the usage of purified water and cold water hot water may be delivered to the terminal through the NFC PCB 88, and daily, weekly or monthly usage may be delivered. In addition, by transmitting a telegram such as the replacement cycle of the filter 34 or the temperature of cold water and hot water, the user may check through the terminal.

In addition, the user may set the temperature of the hot water of cold water through the terminal, and may set the amount of water to be taken out once. These other settings of the water purifier 1 may be grouped so that the terminal can be automatically performed only by an operation of bringing the terminal to a specific position of the top cover 14 adjacent to the NFC PCB 88. On the top cover 14, a location capable of communication connection with the NFC PCB 88 may be displayed, and a user may place the terminal on the corresponding location so that communication with the NFC PCB 88 is possible. can do.

Meanwhile, the control assembly 80 may be provided with various options according to the model of the water purifier 1. That is, the control base 81 and the main PCB 82 are used as they are, but when only the purified water and cold water functions are used, the induction heating PCB 84 and the power supply PCB 86 may be omitted. . In addition, in the model in which the NFC function is omitted, the NFC PCB 88 may be omitted.

As such, the water purifier may have a structure in which a PCB is arranged for each function module on one control base 81. Accordingly, according to the option of the water purifier 1, a PCB having a corresponding function can be mounted at a designated position on the control base 81. Accordingly, the space structure inside the water purifier 1 can be used in common, and various options can be selected without changing the design of the existing configuration.

28 is a perspective view of a cooling tank of the water purifier. And, Figure 29 is an exploded perspective view of the cooling tank. And FIG. 30 is a cross-sectional view of 30-30' of FIG. 29.

As shown, the cooling tank 60 is provided at the rear of the heating and control module 50, and the lower end is inserted into the condenser bracket 54 and mounted. The cooling tank 60 may have an external appearance as a whole by a tank body 61 and a tank cover 62 covering an opened upper surface of the tank body 61.

The tank body 61 includes an inner case 611 forming an inner space filled with coolant therein and an insulating material body 612 formed outside the inner case 611. The inner case 611 may be injection formed of a resin material, and the heat insulating material body 612 may be formed by foaming a foaming liquid outside the inner case 611.

In addition, the tank cover 62 is formed to shield the opening of the tank body 61 from above, and an inner cover 621 formed of a molded product and an insulating material cover 622 surrounding the outer side of the inner cover 621 ).

The exterior of the tank cover 62 may be formed by insulating materials 612 and 622 like the exterior of the tank body 61. In addition, the evaporator 63 may be introduced through the tank cover 62, and the pipe of the evaporator 63 connected to the outside of the tank cover is an insulating material such as PE (polyethylene) foam 631 To insulate. At this time, a part of the capillary tube 55 used as the expansion device may be wrapped and fixed together with the pipe of the evaporator 63.

A cold water temperature sensor 601 may be provided in the cooling tank 60. The temperature of the cooling water measured by the cold water temperature sensor 601 serves as a basis for determining the operation of the refrigeration cycle.

For example, when the temperature of the cooling water measured by the cold water temperature sensor 601 is higher than the first reference temperature, the refrigeration cycle of the water purifier 1 operates to lower the temperature of the cooling water. In addition, the coolant stored in the inner case 611 is cooled by the refrigerant passing through the evaporator 63.

And, when the temperature of the cooling water measured by the cold water temperature sensor 601 is less than or equal to the second reference temperature, the refrigeration cycle of the water purifier 1 stops operating. The second reference temperature is lower than the first reference temperature. The first reference temperature and the second reference temperature serve as standards for operation and shutdown of the refrigeration cycle, respectively. Accordingly, the cooling water stored in the inner case 611 may be maintained between the first reference temperature and the second reference temperature by temperature measurement by the cold water temperature sensor 601 and the operation of the refrigeration cycle.

A cooling coil 64 is accommodated in the inner space of the inner case 611. The cooling coil 64 is a flow path through which purified water passes. The cooling coil 64 is installed inside the inner case 611 and is immersed in cooling water. The purified water passing through the cooling coil 64 exchanges heat with the cooling water. Accordingly, the heat of the purified water inside the cooling coil 64 is transferred to the cooling water, and the purified water becomes cold water within a short time by heat exchange with the cooling water. The cooling coil 64 may be formed of a metal material such as stainless steel to promote heat exchange. In addition, the inlet 641 and the outlet 642 of the cooling coil 64 pass through the tank cover 62 and are exposed to the outside of the cooling tank 60.

A coil support part 6111 supporting the cooling coil 64 is provided on the bottom surface of the inner case 611. The coil support part 6111 protrudes toward the cooling coil 64 from the inner bottom surface of the inner case 611. The coil support part 6111 has a groove 6112 having a size corresponding to the outer peripheral surface of the cooling coil 64. The cooling coil 64 is mounted in the groove 6112 of the coil support part 6111 and is supported by the coil support part 6111.

Accordingly, the cooling coil 64 may be spaced apart from the bottom surface of the inner case 611, and coolant may flow through the space between the bottom of the cooling coil 64 and the bottom of the inner case 611. As a result, the cooling water can be smoothly circulated, and the cooling efficiency of the purified water inside the cooling coil 64 can be improved.

A mesh member 65 may be provided inside the inner case 611. The mesh member 65 may be located between the evaporator 63 and the cooling coil 64. The evaporator 63 flows into the inner case 611 and may be wound in a coil-like shape, and is positioned higher than the cooling coil 64. In addition, the mesh member 65 is positioned between the evaporator 63 and the cooling coil 64 to support the evaporator 63 and has a structure to be seated on the upper end of the cooling coil 64.

In addition, a gasket 66 for sealing the space between the tank body 61 and the tank cover 62 may be provided at an upper end of the inner case 611.

On the other hand, the inner cover 621 forming the lower surface of the tank cover 62 is equipped with a plug mounting portion 6211 on which a plug 623 is mounted and a motor 67 for operating an agitator 68 The motor mounting portion 6212 may be formed.

The plug 623 forms a portion through which the pipe and the electric wire of the evaporator 63 enters and exits, and prevents direct contact between the pipe of the evaporator 63 and the inner cover 621 and maintains airtightness. The plug 623 may be formed of a soft material such as rubber or silicone so that the pipe or wire of the evaporator 63 that is bent is not damaged in the process of entering and leaving the tank cover 62.

The motor 67 is mounted on a motor mounting portion 6212 that is opened in the center of the inner cover 621. In addition, the motor 67 is disposed such that the rotation shaft faces downward so that the agitator 68 can be coupled to the lower side of the motor 67.

The stirrer 68 may be rotated by the motor 67, and is configured to extend downwardly so as to be immersed in the cooling water. The agitator 68 may extend so that the lower end is positioned further below the upper end of the cooling coil 64. Accordingly, when the water is forced to flow by the agitator 68, the cooling water and the purified water inside the cooling coil 64 can be actively heat-exchanged.

In addition, a plurality of blades 681 are formed in the agitator 68, and the plurality of blades 681 are formed to have a wider width as they go downward, and in particular, from the lower end of the blade 681 toward the side. It has a protruding shape. In addition, the lower portion of the blade 681 may be formed to be inclined to have directionality in one direction. Accordingly, when the agitator 68 is rotated, water in the inner case 611 may be forcibly flowed downward, and circulation may be actively performed in the inner case 611.

The blade 681 is disposed to pass through the mesh member 65, and when the blade 681 is driven, cooling water may be circulated while passing through the mesh member 65.

31 is a perspective view of the mesh member. And FIG. 32 is a cross-sectional view 32-32' of FIG. 28.

As shown in the drawing, the mesh member 65 may be injection-formed from a plastic material, and a partition portion 651 crossing the inner case 611 and a stirrer hole in the center of the partition portion 651 It may be composed of an extension portion 652 extending upward along the (6511). In addition, the partition portion 651 and the extension portion 652 may both be formed in a mesh member shape, and are formed to smoothly enter and exit the coolant through a plurality of holes.

The shape of the partition part 651 is formed to correspond to the cross-sectional shape of the inner case 611, so that the inside of the inner case 611 may be partitioned when the mesh member 65 is mounted. In addition, a plurality of partition protrusions 6512 may be formed around the partition 651 to protrude outward.

In addition, a stepped 6113 and a protrusion 6114 are formed on the inner surface of the inner case 611. When the mesh member 65 is mounted, the partition 651 or the partition protrusion 6512 may be mounted between the stepped 613 and the protrusion 6114, and the mesh member 65 It is possible to maintain a fixed position inside the inner case 611.

A lower support part 6513 may be formed on a lower surface of the partition part 651. The lower support part 6513 is for accommodating the upper end of the cooling coil 64, and extends downward and may have a groove 6514 into which the cooling coil 64 can be inserted. A plurality of lower support portions 6513 may be formed, and are positioned in a direction facing each other or in a direction crossing each other to prevent the mesh member 65 from tilting when the mesh member 65 is mounted, and at the same time, the cooling coil ( 64) It prevents the flow of the upper part.

In addition, an upper support portion 6251 may be formed on the upper surface of the partition portion 651. The upper support part 6251 is for accommodating the lower end of the evaporator 63 wound in a coil shape, and extends upward and a groove 6252 into which the evaporator 63 can be inserted may be formed.

The upper support part 6251 may extend outwardly from the extension part 652, and may extend upward at the same position as the lower support part 6513. The evaporator 63 may be seated in a correct position by the upper support part 6251 and does not flow inside the inner case 611 and maintains a stable mounting state.

A coil guide portion may be formed on one side of the circumference of the partition portion 651 to be recessed inward so that the inlet portion 6516 and the outlet portion 6517 of the cooling coil 64 can be located. In addition, a guide protrusion 6515 protruding outward is formed on the coil guide part. Accordingly, an inlet portion 6516 of the cooling coil 64 may be positioned on one side of the guide protrusion 6515, and an outlet portion 6517 of the cooling coil 64 may be positioned on the other side. In addition, a guide groove 6518 is formed on one side of the coil guide. The guide groove 6518 is formed so that the bent portion of the cooling coil 64 connected to the inlet 6516 of the cooling coil 64 can pass.

A fixing hook 6519 extending upward may be formed on one side of the upper surface of the partition part 651. The fixing hook 6519 is formed to restrain the evaporator 63. The fixing hook 6519 is formed to extend upward from the outside of the wound portion of the evaporator 63, and the upper end of the fixing hook 6519 presses and restrains the top of the wound portion of the evaporator 63. . Accordingly, the evaporator 63 may be fixed inside the inner case 611, and noise or damage due to flow does not occur.

The extension part 652 is formed along the stirrer hole 6511 in the center of the partition part 651, and is formed so that the stirrer 68 can penetrate the inner space of the extension part 652. In addition, the extension part 652 may extend from the partition part 651 to the motor 67. In addition, the extension part 652 is formed so that a plurality of ribs 6523 extending vertically are continuously spaced apart so that cooling water can pass through, but foreign substances can be blocked.

Accordingly, the inner space of the inner case 611 by the partition part 651 and the extension part 652 is a region where the evaporator 63 is located and a lower region of the evaporator 63, that is, the cooling coil ( The area where 64) is located can be partitioned. In addition, the evaporator 63 in a wound state is located outside the extension part 652, and the blade 681 is located inside the extension part 652.

Meanwhile, freezing may be generated around the evaporator 63 by the refrigerant passing through the evaporator 63 while the refrigeration cycle is driven to cool the cooling water, and cooling water due to rotation of the agitator 68 During the circulation process, some of the ice frozen in the evaporator 63 may come off. However, ice around the evaporator 63 is blocked by the mesh member 65 without passing through the mesh member 65. Eventually, ice around the evaporator 63 is prevented from colliding with the agitator 68. Therefore, it is possible to prevent the agitator 68 from being damaged, and noise generated when the ice is hit can be prevented. In addition, it is possible to prevent ice from flowing by the mesh member 65 and colliding with the cooling coil 64, and circulating and flowing inside the inner case 611 together with cooling water. There will be.

A drain valve 69 for draining coolant is provided at the lower end of the cooling tank 60. The drain valve 69 allows the coolant stored in the inner case 611 to be periodically replaced. In addition, at least a portion of the bottom surface of the inner case 611 is formed with a drain portion 6115 having an inclined or recessed portion. In addition, the drain portion 6115 communicates with the drain valve 69 so that the cooling water in the cooling tank 60 can be drained smoothly.

The drain valve 69 is connected to the inner case 611. The drain valve 69 protrudes from the inner case 611 to form a discharge passage for the cooling water filled in the inner case 611.

A drain passage part 6161 protruding toward the heat insulating material body 612 is formed under the inner case 611, and the drain passage part 6161 is connected to the drain valve 69. Since the drain valve 69 is configured to discharge coolant to the outside of the water purifier 1, when the coolant drain passage part 6116 is inserted into the drain valve 69, a channel capable of draining the coolant stored in the inner case 611 Is formed. In addition, the drain valve is fixed by a valve fixing part 6117. A detailed description of the drain valve 69 and the valve fixing part 6117 will be described later.

The drain valve 69 may be embedded and fixed by the heat insulating material body 612, and the end of the drain valve 69 is exposed to the outside of the heat insulating material body 612 so that it can be connected from the outside. Accordingly, the drain valve 69 may be insulated, and it prevents dew from forming on the outer peripheral surface of the drain valve 69.

33 is an exploded perspective view showing a mounting structure of a drain valve of the water purifier. And, Figure 34 is an exploded perspective view showing the coupling structure of the drain valve. And, Figure 35 is a partial cross-sectional view showing the coupling structure of the drain valve.

As shown in the drawing, the inner case 611 includes a valve fixing part 6117 for fixing the position of the drain valve 69. The valve fixing part 6117 surrounds at least a part of the drain valve 69. The valve fixing part 6117 is formed to correspond to the outer shape of the drain valve 69.

A sealing member 691 is provided inside the valve fixing part 6117. The sealing member 691 is formed to surround a connection portion between the inner case 611 and the drain valve 69. The sealing member 691 serves to connect and seal the inner case 611 and the drain valve 69. Accordingly, the sealing member 691 prevents the cooling water from leaking through the gap formed in the connection portion between the inner case 611 and the drain valve 69.

Meanwhile, the drain valve 69 includes a valve housing 692, a valve seat 694, an elastic member 695, a first O-ring 693, and a second O-ring 696.

The valve housing 692 forms the exterior of the drain valve 69. In addition, the valve housing 692 has a hollow portion. The hollow portion of the valve housing 692 corresponds to a drain passage for draining the coolant and communicates with the drain passage portion 6116. The hollow portion of the valve housing 692 corresponds to a space accommodating the valve seat 694, the elastic member 695, and the like.

The valve housing 692 is formed by a combination of the first housing 6921 and the second housing 6922. In addition, the valve seat 694 is disposed inside the valve housing 692. The valve seat 694 receives a pressing operation from a user. The user's pressing operation is for opening and closing the drain passage of the drain valve 69.

The opening of the drain passage may be opened to drain the cooling water, but may be opened to fill the cooling water in a state in which the cooling water is completely drained.

The first O-ring 693 seals the valve seat 694 and the first housing 6921. In addition, the first O-ring 693 is coupled to the valve seat 694 and is in close contact with the housing by an elastic force provided by the elastic member 695. The elastic member 695 provides an elastic force for bringing the valve seat 694 into close contact with the first housing 6921. The elastic member 695 is supported by the second housing 6922.

The second O-ring 696 seals a connection portion between the first housing 6921 and the second housing 6922. The second O-ring 696 is made of a material having elasticity.

36 is a view showing a state in which the compressor bracket is mounted on the base of the water purifier. And, Figure 37 is an exploded perspective view showing the coupling structure of the base and the tray.

As shown in the drawing, the base 13 forms the bottom surface of the water purifier 1. In addition, the base 13 is formed so that the circumference of the base 13 extends upward to be coupled to the side panel 15, the front cover 11, and the rear cover 12.

Legs 131 protruding downward may be formed on the base 13. A plurality of legs 131 may be formed on the base 13, and the entire lower surface of the base 13 may be configured to be spaced apart from the ground. Therefore, it is possible to facilitate suction of outside air through the lower surface of the base 13.

A rotation ring 91 is rotatably mounted on the first half of the base 13. The tray 90 is detachably coupled to one front side of the rotation ring 91 and is connected to the rotation ring 91 so as to be rotated left and right.

The first half of the base 13 is formed to be stepped lower than the second half of the base 13. In addition, an opening is formed between the first half of the base 13 and the lower end of the lower cover 112, and the side surface of the tray 90 is exposed to the outside through the opening, and the left and right sides are combined with the rotating ring 91. It can be rotated laterally.

In addition, the stepped portion between the first half and the second half of the base 13 becomes a stopper 1301 when the tray 90 is rotated. In addition, when the tray 90 is rotated, both sides of the tray 90 come into contact with the stopper 1301, and rotation of the tray 90 may be restricted.

In addition, the stopper 1301 of the base 13 has a flow preventing portion 1302 that prevents the tray 90 from flowing up and down, extending forward. The flow prevention part 1302 is formed to restrain both sides of the rear end of the tray 90 while the tray 90 is rotated.

A rotation guide 132 is provided inside the base 13. The rotation guide 132 may include a first rotation guide 1321 and a second rotation guide 1322 disposed concentrically on the base 13. The first rotation guide 1321 is disposed outside the second rotation guide 1322. The first rotation guide 1321 and the second rotation guide 1322 are formed to protrude upward from the bottom surface of the base 13 at a constant curvature, so that the rotation of the rotation ring 91 may be guided. The rotation guide 132 may be formed in a circular shape or may be formed in an arc shape.

The rotation ring 91 is guided by the rotation guide 132 and is rotatably mounted with respect to the base 13 and serves to support the tray 90. The rotating ring 91 may include an outer ring part 911, an inner ring part 912, and a ring joint 913.

The outer ring part 911 forms the outer skeleton and shape of the rotating ring 91. The outer ring part 911 is formed in a circular shape, and a part of the outer ring part 911 is in contact with the outer surface of the first rotation guide part 1321 and is rotatably mounted along the first rotation guide part 1321.

In addition, the inner ring part 912 is disposed to have concentricity inside the outer ring part 911. The inner ring part 912 is made in a circular shape, and is in contact with a part of the second rotation guide part 1322 and the outer surface of another part, so that the movement in the front and rear direction of the water purifier and the base 13 is restricted, and the second rotation guide As guided by the part 1322, it is mounted rotatably in place.

The outer ring part 911 is provided with a tray mounting part 914 on one side for coupling with the tray 90. The tray mounting portion 914 includes a receiving hole 9141 having the same size and shape as the tray coupling portion 96 of the tray 90. The receiving hole 9141 is opened in a direction facing the tray connecting portion 96, and the tray connecting portion 96 is inserted into the tray mounting portion 914 through the receiving hole 9141.

When the tray coupling portion 96 is inserted and coupled into the tray mounting portion 914, the tray mounting portion 914 surrounds the tray coupling portion 96 and contacts the outer surface of the tray coupling portion 96. The tray coupling portion 96 is supported so that the tray coupling portion 96 does not move in the vertical/left/right direction. However, the tray coupling part 96 is movable in the front-rear direction inside the tray mounting part 914 so that it may be inserted and withdrawn.

Meanwhile, a protrusion 9142 may be formed inside the tray mounting part 914. In addition, a fastening groove 961 is formed in the tray coupling part 96 so that when the tray coupling part 96 is inserted into the inner side of the tray mounting part 914, the protrusion 9142 is connected to the fastening groove 961. It is combined so that the tray 90 can support the state of being mounted on the rotating ring 91. In addition, when the tray 90 is mounted, it can be easily recognized that the protrusion 9142 and the fastening groove 961 are coupled. As the tray coupling portion 96 is inserted and coupled to the tray mounting portion 914, the tray 90 may be coupled to the rotation ring 91 and rotated in the left and right directions with respect to the base 13.

On the other hand, the second rotation guide portion 1322 is formed with a separation preventing protrusion 1323 to prevent the rotation ring 91 from being separated from the second rotation guide portion 1322. The upper end of the separation preventing protrusion 1323 is formed in a hook shape so as to be caught on the upper surface of the inner ring part 912. Therefore, when the tray 90 is rotated, the rotation ring 91 can be prevented from being separated from the second rotation guide 1322 as the rotation ring 91 is lifted upward, and the tray 90 The rotation of the can be stably maintained.

In this embodiment, the front cover 11 is detachably coupled to the case 10, and a grip portion 1121 is formed convexly bent forward at the lower end of the front cover 11 (Fig. 2, 3), and a gripping groove 9143 that is concave inward at a position corresponding to the gripping part 1121 is formed in the rotation ring 91 (see FIGS. 36 and 37), so that the user can use the gripping part 1121 After gripping the front cover 11 between the and gripping grooves 9143, the front cover 11 may be separated from the case 10. At this time, after removing the tray 90, the front cover 11 is removed.

In addition, a gripping groove 311 concave inward may be formed on the bottom surface 31 of the filter bracket 30 at a position corresponding to the gripping part 1121 (see FIGS. 2 and 3 ).

A pressure reducing valve 133 may be provided in the center of the first half of the base 13. The pressure reducing valve 133 adjusts the pressure of water supplied from the tap water to smooth the water purification operation, and allows the water pressure at the time of extraction to be adjusted. When the rotation ring 91 is mounted, the pressure reducing valve 133 is located in the inner region of the inner ring 912 to enable efficient use of space.

A mounting portion 134 on which the compressor 51 is mounted is formed in the central portion of the base 13. The mounting part 134 may be formed to protrude upward to support the compressor 51. In addition, four mounting portions 134 may be provided, and four corners of the bottom surface of the compressor 51 may be supported. In addition, a nut is insert-injected into the mounting part 134, and is configured to fix the compressor 51 by fastening a screw from a lower side after the compressor 51 is seated.

A suction grill 135 is further formed at the central portion of the base 13. At least a portion of the suction grille 135 may be positioned between the mounting portions 134, and may be positioned below the compressor 51. Accordingly, the air sucked into the water purifier 1 can cool the compressor 51 while passing through the compressor 51. The suction grille 135 is formed in the lattice shape, and forms a plurality of suction ports to prevent the inflow of foreign substances from the outside.

A condenser bracket 54 accommodating the condenser 52 is disposed behind the suction grill 135. The condenser bracket 54 is located at the rear of the base 13. The condenser bracket 54 may include a condenser mounting part 541 fixed to the base 13 and a tank mounting part 542 positioned above the condenser mounting part 541.

A cooling fan 53 is provided on the front side of the condenser mounting part 541. The outside air is sucked in through the suction grille 135 by the cooling fan 53 to cool the compressor 51 and the condenser 52 and discharge it to the discharge port 121. In addition, the rear surface of the condenser mounting part 541 is in contact with the discharge port 121. Accordingly, the condenser 52 accommodated inside the condenser mounting part 541 is disposed in a position adjacent to the discharge port 121 of the water purifier 1.

A cord mounting portion 1303 to which the power cord 136 is fixed is formed at the rear end of the base 13. In addition, a cord guide portion 1304 is formed from the cord mounting portion 1303 to an intermediate portion of the base 13. Accordingly, the power cord 136 can be moved along the cord guide portion 1304 and is connected to the control assembly 80.

In addition, an inlet pipe entrance 1305 through which an inlet pipe 360 (see FIG. 42) is introduced is formed at the rear end of the base 13, and an inlet pipe 360 connected to the water supply through the inlet pipe entrance 1305 Is inflow. The end of the intake pipe 360 may extend to the pressure reducing valve 133. In addition, a tube guide 3601 for preventing the intake pipe 360 from being folded may be further provided in a portion of the bent section of the intake pipe 360. The tube guide 3601 is formed of a plastic material, and guides the inlet pipe 360 so as not to be excessively bent or folded. Such a tube guide 3601 may be further provided on a pipe through which purified water, cold water, and hot water flow.

38 is an exploded perspective view showing the coupling structure of the tray of the water purifier. And, Figure 39 is a view showing the state of the full water level of the tray.

As shown in the drawing, the tray 90 is composed of a tray body 92 having a storage space therein, and a tray cover 93 detachably coupled to cover the upper portion of the tray body 92. I can.

A storage space is formed in the tray body 92 to be recessed in a downward direction to store residual water therein. The edge portion of the tray body 92 may be configured to surround the edge side of the tray cover 93. In addition, a support part 921 for supporting a lower surface of the tray cover 93 may be provided inside the tray body 92.

A depression 922 is formed on the bottom of the tray body 92. The depression 922 protrudes downward from the bottom surface of the tray body 92 and supports the bottom surface of the tray 90 in contact with the ground on which the water purifier 1 is installed. Accordingly, when the tray 90 is rotated in the left and right direction, it can be supported at a constant height without sagging on the ground on which the water purifier 1 is installed.

Meanwhile, the depression 922 may be formed to be the same as or larger in size than the plotter 94 so that the plotter 94 can be accommodated. Accordingly, the floater 94 may be disposed inside the recessed portion 922 so as to be able to move up and down according to the water level.

The plotter 94 may include a floating part 941, an indicator 942, and a cap 943. The floating part 941 is formed to have a size that can be accommodated inside the recessed part 922 and may be formed of a material that can float in water by buoyancy.

In addition, an indicator 942 may be disposed on an upper end of the floating part 941, and fixedly mounted to the floating part 941 by the cap 943. The indicator 942 may be formed in a ring shape, and may be formed in a color different from that of the floating part 941, the cap 943, and the tray cover 93.

In addition, the cap 943 forms an upper end of the plotter 94 and forms a portion exposed to the tray cover 93. The cap 943 may be formed of an exposed portion 9431 exposed to the tray cover 93 and a through portion 9432 extending downward from the exposed portion 9431. The exposed part 9431 may be formed in the same shape as the diameter of the indicator 942. In addition, the through part 9432 may pass through the indicator 942 and be inserted into the upper end of the plotter 94.

When the tray 90 is not filled with a certain amount of water, the upper surface of the cap 943 is positioned on the same plane as the upper surface of the tray cover 93 or further lower. In addition, when the tray 90 is filled with a certain amount of water or the water level reaches full water, the floating part 941 rises due to buoyancy, and the cap 943 may also protrude more than the upper surface of the tray cover 93. There will be.

At this time, as shown in FIG. 39, when the floating part 941 is completely raised, the indicator 942 protrudes more upward than the upper surface of the tray cover 93. Accordingly, when the color of the indicator 942 is identified, the user can recognize the full water level, and can empty the stored water by separating the tray 90.

A concave portion 923 is formed to be concave in an arc shape at the rear surface of the tray body 92 and the rear end of the tray cover 93, so that the concave portion 923 surrounds a part of the rotating ring 91 May be, and the rear end of the tray is in close contact with the rotary ring.

In addition, protrusions 95 are formed to protrude rearward on both sides of the rear end of the tray body 92. The outer surface of the protrusion 95 is formed to extend in the same plane from one side of the tray body 92 to cover the connection portion between the tray 90 and the rotary ring 91.

In particular, even when the tray 90 is rotated, it is possible to form an exterior shape in a shape that continues from the front exterior of the water purifier formed to be round. Therefore, regardless of whether the tray 90 is rotated, the appearance may be beautiful.

In addition, the tray engaging portion 96 is formed to protrude rearward at the center of the recessed portion of the tray body 92 for coupling the tray 90 and the rotary ring 91. When the tray 90 is mounted, the tray coupling part 96 may be inserted into and coupled to the tray mounting part 914.

Meanwhile, a plurality of slits 931 are formed in the tray cover 93, so that residual water can be introduced into the storage space of the tray body 92 through the slit 931, and the residual water is It can prevent from sticking out to the outside.

An indicator hole 932 is further formed in the tray cover 93. The indicating hole 932 is formed at a position corresponding to the position of the cap 943 of the plotter 94 and may be formed to have the same size as the cap 943. Accordingly, when the floater 94 is raised or lowered, the cap 943 moves up and down through the indicator hole 932. In addition, when the tray 90 is filled, the indicator 942 is exposed to the outside of the indicator hole 932 so as to be able to display a flood situation to the user.

A collection hole 933 may be further formed in the tray cover 93. The water collecting hole 933 is opened vertically below the water outlet nozzle 25. Therefore, when water is taken out of the tray 90 without a container such as a cup, the water falling through the collecting hole 933 is directly collected in the tray 90.

40 is an exploded perspective view showing a combined structure of a condenser bracket of the water purifier, a blower fan, and a condenser. And, FIG. 41 is a cut-away perspective view showing the flow of cooling air in the water purifier.

As shown in the drawing, the condenser bracket 54 may have the condenser mounting portion 541 formed at the lower portion, and the tank mounting portion 542 formed at the upper portion of the condenser bracket 54.

A bracket mounting part 1307 is formed at the lower end of the condenser mounting part 541. The bracket mounting part is supported on the base, and a screw is fastened to fix the condenser bracket.

The condenser mounting part 541 is formed to have front and rear openings, and is formed to accommodate the condenser 52 therein. In addition, a condenser support part 921 protruding upward is formed on the inner bottom surface of the condenser mounting part 541. The condenser 52 is supported by the condenser support part 921, is spaced apart from the bottom of the condenser mounting part, and facilitates the flow of cooling air to promote heat exchange.

The condenser 52 is formed by bending a plate-shaped tube 521 a plurality of times, and a heat exchange plate 522 continuously bent is disposed between the plate-shaped tubes. Further, headers 523 communicating with a plurality of tubes 521 are provided at both ends of the tube 521. A refrigerant pipe connected to the compressor 51 and the evaporator 63 may be connected to the header 523, and the refrigerant may circulate through a refrigeration cycle. Accordingly, the condenser 52 is formed in a hexahedral shape as a whole, and is formed in the compact size to be accommodated in the condenser mounting portion 541.

A fixing hole 5411 into which a fixing member 543 for mounting the cooling fan 53 is inserted may be formed on a front surface of the condenser mounting part 541. The fixing holes 5411 are formed at four corners of the front surface of the condenser mounting part 541, and the fixing members 543 fix the four corners of the cooling fan 53.

The fixing member 543 may be formed of a material having elasticity such as rubber or silicone so as to absorb vibration when the cooling fan 53 is driven. The fixing member 543 may be further formed with a pair of locking portions 541 along the circumference of the fixing member 543 so that the fixing member 543 may be inserted and fixed in the fixing hole 5411. In addition, the shape of the locking portion 541 is formed in a shape whose diameter becomes narrower toward the front, so that the fixing member 543 is easily inserted and mounted, and the cooling fan 53 is not easily removed. Further, the front end of the fixing member 543 is inserted into an insertion hole 531 formed at the corner of the cooling fan 53 so that the cooling fan 53 can be fixed to the front surface of the condenser mounting part 541.

The tank mounting part 542 is located above the condenser mounting part 541 and has a size and shape corresponding to the cross section of the cooling tank 60 so as to accommodate the lower end of the cooling tank 60. In addition, the tank mounting portion 542 has a rim 5241 extending upward along the periphery, and an inner side of the rim 5241 forms a predetermined space so that the lower portion of the cooling tank 60 is inserted.

In addition, a drain hole 5242 through which the drain valve 69 passes may be formed in the rim 5241. The drainage hole 5242 is exposed when the rear cover 12 is removed. Accordingly, the drain valve 69 is exposed to the outside to allow the cooling water to be drained or filled.

In addition, a plate support portion 5223 for supporting one end of the support plate 35 may be formed on the front surface of the condenser mounting portion 541, that is, above the cooling fan 53. Accordingly, both ends of the support plate 35 may be fixed to the filter bracket 30 and the condenser bracket 54 and provide a space for mounting the heating and control module 50.

Hereinafter, a water extraction process of a water purifier according to an embodiment of the present invention having the above structure will be described.

42 is a circuit diagram schematically showing a flow path of water in the water purifier. And, Figure 43 is a block diagram showing the flow of the control signal of the water purifier.

As shown in the figure, the inlet pipe 360 of the water purifier 1 is connected to the water supply to receive raw water. The inlet pipe 360 is connected to the pressure reducing valve 133, and the raw water passing through the pressure reducing valve 133 is reduced to a pressure set for the operation of the water purifier 1.

In addition, the reduced pressure raw water flows toward the filter 34 along a pipe connecting the pressure reducing valve 133 and the filter 34. The raw water passing through the filter 34 is in a purified state by removing foreign substances. In addition, by opening the water supply valve 361, purified water passes through the water supply valve 361 along a pipe and passes through the flow sensor 363 in sequence.

At this time, the water supply valve 361 and the flow sensor 363 may be connected to the main PCB 82, so that the opening degree of the water supply valve 361 can be adjusted according to a signal transmitted from the main PCB 82. do. In addition, the flow rate sensed by the flow rate sensor 363 may be transferred to the main PCB 82 and used as data necessary for controlling the water purifier.

The purified water that has passed through the flow sensor 363 may be branched into a cold water side 3642 and a hot water side 3642 through a branch pipe 364. The purified water flowing through the pipe of the cold water side (3641) is branched into the cold water side (3651) and the purified water side (3652) again by the T connector (365) and connected to the cold water outlet valve 366 and the purified water outlet valve 367, respectively. do. The purified water outlet valve 367 and the cold water outlet valve 366 may be connected to the main PCB 82 to be opened or closed. That is, the purified water outlet valve 367 and the cold water outlet valve 366 may be selected according to the user's setting, and the selected valve may be opened through the operation of the take-out button 41 to allow water to be dispensed.

Meanwhile, water that has passed through the cold water outlet valve 366 passes through the cooling coil 64 inside the cooling tank 60. The water flowing along the cooling coil 64 is cooled by heat exchange with the cooling water in the cooling tank 60, and for this purpose, the cooling water is cooled to maintain a set temperature.

The compressor 51 connected to the main PCB 82 is driven to cool the cooling water. The driving of the compressor 51 may be determined by a cold water temperature sensor 601 provided in the cooling tank 60. Accordingly, the cooling water can always maintain a set temperature, and for this purpose, the drive of the compressor 51 can be controlled. The compressor 51 is an inverter compressor whose frequency is adjusted in response to a required load, and a cooling capacity may be adjusted. That is, the compressor 51 may be driven by inverter control, and it is possible to cool the cooling water with optimum efficiency.

Meanwhile, the compressor 51 may be set to a forcibly off state by a user manipulating the manipulation unit 40. The compressor 51 may be forcibly maintained in the off state in winter when the consumption of cold water is low, when power saving is required, or when the use of cold water is not desired.

In addition, the main PCB 82 controls not only the driving of the compressor 51 but also the driving of the cooling fan 53. In addition, the main PCB 82 controls the driving of the motor 67. The motor 67 is driven to increase heat exchange efficiency between the cooling water and the cold water passing through the cooling coil 64, and is controlled by the main PCB 82. The agitator 68 is rotated by the driving of the motor 67, and the cooling water may be forcibly convective in the cooling tank 60, thereby effectively cooling the purified water inside the cooling coil 64. do.

The cold water passing through the cooling tank 60 is introduced into the water outlet pipe 261 through the T connector 26, and the cold water passing through the water outlet pipe 261 is taken out through the water outlet nozzle 25 Can be.

When the purified water outlet valve 367 is opened, the purified water passing through the purified water outlet valve 367 flows into the water outlet pipe 261 through the T connector 26, and passes through the water outlet pipe 261. It can be taken out to the outside through the water outlet nozzle (25).

Meanwhile, when the user selects to take out hot water, purified water may flow to the hot water side 3642 of the branch pipe 364. The flow control valve 368 is opened by the control of the main PCB 82, and the water flowing through the flow control valve 368 is adjusted to a flow rate suitable for heating hot water. That is, the amount of purified water supplied to the hot water tank 71 is adjusted so that water can be heated to a temperature set by the induction heating assembly 70.

The purified water passing through the flow rate control valve 368 passes through the hot water tank 71. In addition, in the process of passing through the hot water tank 71, it can be heated to a set temperature. The hot water tank 71 may be heated by an induction heating method, and for this purpose, the output of the magnetic force of the working coil 72 may be adjusted by the control of the induction heating PCB 84.

In order to drive the induction heating assembly 70, a higher voltage is required than the main PCB 82, and power is supplied from the power supply PCB 86 connected to the power line to supply the high voltage. The power supply PCB 86 supplies appropriate power according to whether the induction heating assembly 70 is driven, and supplies suitable power to the main PCB 82 as well.

Water in the hot water tank 71 may be heated to a set temperature by driving the induction heating assembly 70. The hot water outlet valve 369 may be provided with a hot water temperature sensor. The hot water temperature sensor senses the temperature of hot water discharged through the hot water tank 71 and transmits it to the main PCB 82. In addition, the main PCB 82 can adjust the output of the working coil 72 based on the input hot water temperature data.

In addition, the temperature of the hot water tank 71 itself may be sensed by a hot water temperature sensor 761 provided outside the hot water tank 71. When the hot water temperature sensor 761 rises above a set temperature and there is a risk of a fire, the fuse 762 may be short-circuited by transmitting a signal to the main PCB 82. Meanwhile, an OLP (Over Load Protection) 511 may be connected to the main PCB, and the OLP 511 protects the compressor 51 by blocking power supply when an overload of the compressor 51 occurs. do.

When the fuse 762 is short-circuited due to an abnormal operation of the induction heating assembly 70, power supplied from the power supply PCB 86 to the induction heating PCB 84 is cut off and the induction heating assembly 70 ) To prevent overheating and damage.

The hot water heated by passing through the hot water tank 71 by the hot water outlet valve 369 is flowed to the water outlet nozzle 25 through the hot water pipe 262 to be taken out to the outside.

On the other hand, when water is ejected by the operation of the ejection button 41, the LED 2821 of the water outlet 20 may be turned on under the control of the control unit PCB 43. The lower side of the water outlet 20 may be illuminated by the lighting of the LED.

And, the control panel PCB 43 is the state of the filter 34 through the lighting color of the switch LED 434 irradiated through the takeout button 41 irrespective of whether or not the takeout button 41 is operated. Alternatively, you can recognize the exchange period.

In addition, the operating state or degree of operation of the water purifier 1 may be transmitted to a terminal such as a user's mobile phone through the NFC PCB 88 and displayed. In addition, information and manipulation signals may be transmitted to the NFC PCB 88 through the terminal, and the water purifier 1 may be driven using the transmitted information.

For example, the user can check information such as the life of the filter 34 and the usage pattern of the water purifier 1 through an app installed on the mobile phone, and a power saving mode that turns off the cold water mode of the water purifier 1 through the app. It is possible to set the operation of other water purifier 1, such as setting.

Meanwhile, while the water purifier 1 is in use, the coolant inside the cooling tank 60 may be drained and new coolant may be filled.

Hereinafter, the process of replacing the cooling water will be described with reference to the drawings.

44 is a perspective view showing a coolant replacement operation state of the water purifier. And, Figure 45 is a flow chart sequentially showing the control method of the water purifier.

As shown in the drawing, in order to maintain a clean state inside the cooling tank 60, the cooling water inside the cooling tank 60 must be replaced at regular intervals. To this end, the user first exposes the drain valve 69 and then opens the drain valve 69 to discharge the cooling water inside the cooling tank 60 to the outside.

The user can connect to the drain valve 69 by using a separately provided service pipe 2. The end of the service pipe 2 may be connected to the drain valve 69 in a coupling manner, and may have a structure capable of opening the drain valve 69 by connection. Since such a structure is the same as that of a general coupling pipe, a detailed description thereof will be omitted.

Meanwhile, after the cooling water in the cooling tank 60 is completely drained, the other end of the service pipe 2 is connected to the water outlet nozzle 25. By connecting the service pipe 2, the drain valve 69 is kept open, and the water outlet nozzle 25 is able to communicate with the inside of the cooling tank 60.

In this state, the user manipulates the operation unit 40 to set the mode of the water purifier 1 to the coolant replacement mode. In the coolant replacement mode state, the control unit (main PCB) takes out purified water so that the coolant can be charged when the take-out button 41 is operated, and a predetermined amount of water can be supplied by one operation. Is set. [S110]

In the state set as described above, it is determined whether or not the eject button 41 is operated. [S120]

If the user does not operate the ejection button 41 for a set time after selecting to enter the coolant replacement mode, the work for coolant replacement is not performed, and the main PCB 82 returns to the normal operation mode. It is done. [S130]

When the user presses the ejection button 41, the purified water drawn from the water outlet nozzle 25 flows into the cooling tank 60 through the service pipe 2 to start refilling the cooling water. It is done. [S140]

In the state in which the coolant replacement mode is set, the flow rate of purified water supplied by the flow sensor 363 is sensed, and the purified water outlet valve 367 is controlled to supply water at a set capacity in the main PCB 82. do. [S150]

The main PCB 82 determines the detection value transmitted from the flow rate sensor 363 and maintains the open water outlet valve 367 until the detected flow rate reaches a set flow rate. The capacity set in the main PCB 82 is preset as an appropriate capacity to fill the cooling tank 60. For example, in the main PCB 82, when the withdrawal button 41 is operated in the cooling water replacement mode, the purified water outlet valve 367 is opened and the cooling coil 64 and the evaporator 63 are locked. It is possible to supply 2.4L of purified water to the cooling tank 60. [S160]

When the flow rate sensed by the flow rate sensor 363 reaches the set flow rate, the main PCB 82 determines that the cooling water has been filled and closes the purified water outlet valve 367. [S170]

And, after the supply of all the water of the set flow rate is completed, the replacement of the coolant is displayed through the operation unit 40. At this time, it will be possible to display the completion of the replacement of the coolant through the color of light passing through the ejection button 41. Of course, the completion of the coolant replacement may be output by the buzzer 435, and it may be possible to display the completion of the coolant replacement using a separate display means. [S180]

When the replacement of the coolant is completed, the user separates the service pipe 2 from the drain valve 69 and the water outlet nozzle 25. In addition, the control unit automatically releases the coolant replacement mode or switches to a normal normal operation mode according to a user setting. The normal operation mode is a state in which hot water, purified water, and cold water can be discharged in a desired amount through the operation of the ejection button 41. [S190]

Hereinafter, a process of assembling a water purifier according to an embodiment of the present invention having the above structure will be described with reference to the drawings.

46 is a diagram sequentially showing an assembly process of the water purifier.

As shown in the drawing, looking at the assembly process of the water purifier 1 according to the embodiment of the present invention, first, the power cord 136 and the inlet pipe 360 are disposed on the base 13.

In addition, the condenser 52 is disposed on the condenser mounting portion 541 of the molded condenser bracket 54. In addition, the cooling fan 53 is coupled to the front surface of the condenser mounting portion 541. The condenser bracket 54 in the assembled state is mounted on the molded base 13.

In addition, the rotary ring 91 and the pressure reducing valve 133 are mounted on the base 13. [STEP 1]

Next, the condenser 52 is mounted on the base 13. At this time, the compressor 51 is positioned above the suction grill 135 formed on the base 13. In addition, the pipes of the compressor 51 and the condenser 52 and the dryer pipe are welded to be connected to each other. [STEP 2]

Next, after the installation of the condenser 52 is completed, the cooling tank 60 is mounted on the tank mounting portion 542 of the condenser bracket 54. The cooling tank 60 is in a state in which the cooling coil 64 and the evaporator 63, the motor 67 and the agitator 68, the mesh member 65, etc. are arranged inside, and the heat insulating material body 612 and the heat insulating material are It is mounted in a completely completed state until the foaming of the cover 622 is completed.

After the cooling tank 60 is mounted, pipes such as the dryer and the capillary tube 55 are welded and wires are connected. In order to drive the refrigeration cycle, the pipe, the compressor 51 and the condenser 52 are vacuumed, and then the refrigerant is injected and then sealed. [STEP 3]

Next, the filter bracket 30 is mounted on the base 13. At this time, while a plurality of valves are installed in the filter bracket 30, the filter bracket 30 is mounted and the flow path pipes through which water is supplied are connected to each other.

In addition, a support plate 35 is mounted between the filter bracket 30 and the condenser bracket 54. The mounting space of the heating and control module 50 is secured by the support plate 35. [STEP 4]

Next, the heating and control module 50 is mounted on the support plate 35. The heating and control module 50 may be fixedly mounted on the support plate 35 in a state in which the induction heating assembly 70 and the control assembly 80 are combined as one module.

The heating and control module 50 may be located in a space between the filter bracket 30 and the cooling tank 60 in a mounted state. In addition, the upper end of the heating and control module 50 extends to the position of the top cover 14 so as to be in contact with each other. Accordingly, the heating and control module 50 can be efficiently disposed in a space provided in the water purifier 1. In a state in which the heating and control module 50 is mounted, the induction heating assembly 70 and the connector of the control assembly 80 are connected.

Of course, if the water purifier 1 is not a model that dispenses hot water, but a model that dispenses only purified water and cold water, only the control assembly 80 may be mounted on the support plate 35. In addition, the control assembly 80 in which a corresponding PCB is assembled may be mounted according to an optional function. [STEP 5]

Next, the rotator 21 is mounted on the upper end of the filter bracket 30. The water outlet 20 is assembled to the rotator 21, the upper guide bracket 23 and the lower guide bracket 24 are assembled to the rotator housing 22, and a water outlet pipe 261 is arranged inside. Can be.

The rotator 21 is mounted on the rotator mounting portion 33 of the filter bracket 30 and is rotatably mounted. In addition, the pinion gear 271 provided in the rotator 21 is gear-coupled with the internal gear 331 on the upper end of the filter bracket 30 so that the pinion gear 271 is rotated when the rotator 20 rotates. It moves along the internal gear 331 to make the rotation speed of the rotator 21 constant.

In addition, after the rotator 21 is mounted, the water outlet pipe 261 and the T connector 26 to which the cold water and purified water pipes are connected are fitted together. And the end of the water outlet pipe 261 is connected to the water outlet nozzle 25. In addition, the hot water pipe 262 is also connected to the water outlet nozzle 25 to complete the connection of the pipe.

In addition, the upper cover 111 is coupled to an upper end of the rotator 21. Accordingly, the rotator 21 may be provided with a structure capable of stable rotation since the vertical coupling is completed. [STEP 6]

Next, the top cover 14 is assembled. The top cover 14 may be formed to be seated on the upper cover 111 and the upper surface of the cooling tank 60 in a state in which the operation part 40 is rotatably mounted.

When the top cover 14 is mounted, the rotation connection part 421 extending from the front of the operation part 40 is inserted into the coupling rings 236 and 246 of the rotator 21 so that the operation part 40 and the rotator 21 Are combined with each other to form a structure that can rotate together.

In addition, the operation unit PCB 43 and the main PCB 82 provided in the control assembly 80 are connected by a connector, so that power and signals can be transmitted.

In this state, a filter for testing may be mounted in the filter socket of the filter bracket 30, and the test is performed after the filter is connected. After the test is completed, the filter for inspection is removed, the residual water in the flow path is removed, and the filter 34 is assembled to the filter socket.

Then, water is injected into the hot water tank 71 and the induction heating assembly 70 is operated to test hot water heating. After the test is completed, the end cap 7171 is removed, the residual water inside the hot water tank 71 is completely drained, and the end cap 7171 is mounted again. [STEP 7]

Next, the rear cover 12 is screw-fastened to the base 13 to be fixed, and then side panels 15 are screw-fastened to both sides of the base 13 to be fixed. In this case, the side panel 15 may be coupled to the top cover 14 by a screw. [STEP 8]

In addition, the lower cover 112 is coupled to the side panel 15 and the rotator 21 to complete the assembly of the water purifier 1. The lower separately assembled tray 90 may be packaged and shipped together, and when installed and used, the tray 90 is coupled to the rotating ring 91 and used by the user. [STEP 9]

Claims (15)

In a water purifier comprising a case forming an outer shape, a filter provided inside the case, and a cooling tank in which water purified while passing through the filter is cooled,
The cooling tank is:
An inner case in which an inner space for accommodating cooling water is formed;
An insulation body formed by foaming a foaming liquid outside the inner case;
An evaporator and a cooling coil disposed inside the inner space of the inner case;
A drain passage part horizontally extending from a lower portion of the inner case toward the heat insulating material body; And
It is coupled to the drain passage part in the interior of the insulation body, is embedded and fixed in a horizontal direction by the insulation body, the end of which includes a drain valve exposed to the outside of the insulation body,
The drain valve is:
A valve housing having a hollow drain passage formed in communication with the drain passage part;
A valve seat that opens and closes the drain passage while moving in a horizontal direction by a user's pressing motion inside the valve housing;
A first O-ring sealing between the valve housing and the valve seat;
A water purifier comprising an elastic member providing an elastic force when the valve seat is in close contact with the valve housing so that the drain passage is closed.
The method of claim 1,
Through the drain valve, the coolant accommodated in the inner case is drained to the outside.
The method of claim 1,
A water purifier that is inclined or recessed is formed on a bottom surface of the inner case, and the drain is communicated with the drain valve.
The method of claim 1,
The drain valve is a water purifier that is opened while a separate pipe for injecting or discharging coolant is connected.
delete The method of claim 1,
A water purifier having a valve fixing part configured to fix a position of the drain valve while surrounding at least a portion of the drain valve in the inner case.
The method of claim 6,
A water purifier provided with a sealing member surrounding a connection portion between the inner case and the drain valve inside the valve fixing part.
The method of claim 1,
The valve housing is a water purifier formed by a combination of the first housing and the second housing.
The method of claim 8,
The first O-ring is made of an elastic material, the water purifier sealing between the valve seat and the first housing.
The method of claim 9,
The first O-ring is coupled to the valve seat, and the valve seat is in close contact with the first housing by an elastic force provided from an elastic member.
The method of claim 10,
The elastic member is a water purifier supported by the second housing.
The method of claim 8,
A water purifier further comprising a second O-ring made of an elastic material sealing a connection portion between the first housing and the second housing.
In a water purifier comprising a case forming an outer shape, a filter provided inside the case, and a cooling tank in which water purified while passing through the filter is cooled,
The cooling tank is:
An inner case in which an inner space for accommodating cooling water is formed;
An insulation body formed by foaming a foaming liquid outside the inner case;
An evaporator and a cooling coil disposed inside the inner space of the inner case;
A drain passage part horizontally extending from a lower portion of the inner case toward the heat insulating material body; And
A tank mounting portion having an edge portion surrounding a lower portion of the insulating material body and a drain hole passing through the edge portion; And
It is coupled to the drain passage part in the inside of the insulation body and extends in a horizontal direction, and an end thereof includes a drain valve that is exposed to the outside of the insulation body and passes through the drain hole,
The drain valve is:
A valve housing having a hollow drain passage formed in communication with the drain passage part;
A valve seat that opens and closes the drain passage while moving in a horizontal direction by a user's pressing motion inside the valve housing;
A first O-ring sealing between the valve housing and the valve seat;
Including an elastic member for providing an elastic force when the valve seat is in close contact with the valve housing so that the drain passage is closed,
A water purifier capable of selectively draining the coolant by the user.
The method of claim 13,
The drain hole and the drain valve are exposed to the outside when the rear cover forming the rear surface of the case is removed.
The method of claim 13,
The drain valve is a water purifier that automatically opens when a service pipe is connected.

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