KR102129072B1 - Module for discharging water - Google Patents

Abstract

The present invention relates to a water discharge module, a case in which a water discharge nozzle is exposed at the bottom, provided inside the case and provided on an upper side of the water discharge nozzle, an ultraviolet lamp that emits ultraviolet rays on the inner surface of the water discharge nozzle, and the ultraviolet lamp It is provided on the lower side of the protection window of the light-transmitting material to protect the UV lamp from water, when water is taken out from the water outlet nozzle, the UV lamp is turned off, the control unit to cut off the power supplied to the UV lamp It includes.

Description

Exit module {MODULE FOR DISCHARGING WATER}

The present invention relates to a water extraction module.

In general, water purifiers are used for household purposes as a mechanism to remove impurities by filtering water.

In detail, the water purifier is connected to the water supply to remove suspended substances or harmful components contained in tap water using a filter, and is configured to purify and take out as much water as desired according to the user's operation.

Various water purifiers such as purified water as well as hot and cold water have been released. And, in recent years, water purifiers having a small size and capable of being installed in various installation environments have been developed.

However, when water purifiers are used in each home, institution, or office, germs in the hands and bacteria or dust floating in the air are deposited on the water discharge nozzles where water, cold water, and hot water are selectively taken out, thereby contaminating the water discharge nozzles. In addition, in the process of taking out water through the water extraction nozzle to drink coffee, etc., impurities such as coffee come into contact with the water extraction nozzle, and the water extraction nozzle is contaminated, and the water extraction nozzle inevitably has a large amount of bacteria.

In addition, water is always stored in the water discharge nozzle of the water purifier and is exposed to the air, which is forced to be placed in a state where bacteria can reproduce.

However, the daily cleaning of the extraction nozzle is not easy for the general user, and thus the extraction nozzle has a problem that germs can propagate.

In addition, to prevent this, a water purifier equipped with illumination that emits ultraviolet rays is installed in the water discharge nozzle.

However, the conventional water purifier as described above has a problem of exposing the outside of the water outlet nozzle to threaten the safety of the user, and the user does not recognize whether or not the ultraviolet sterilization is properly performed, so that the user's sense of stability or satisfaction decreases. There was an inevitable problem.

In addition, the conventional water purifier has to be assured that the UV sterilization is in progress even when the user is not aware of the sterilization of the water discharge nozzle caused by UV light, and the user is inadvertently deceived the user. There is a fear that a situation may occur.

In addition, the conventional water purifier is difficult to check the amount of water contained in the cup, under the condition that the field of view is not secured, and it has been a hassle to illuminate the light to confirm this.

An object of the present invention is to provide a water purifier that allows the user to always receive clean water through a sterilized water outlet nozzle.

An object of the present invention is to provide a water purifier capable of confirming that the user sees the illumination of a specific color from the outside of the water purifier and that UV sterilization of the water discharge nozzle is in progress.

An object of the present invention is to provide a water purifier that allows a user to check how much water is filled in a cup placed on a tray in a condition in which visibility is not secured.

The object of the present invention is not only to prevent water flowing inside the water discharge module from splashing on the ultraviolet lamp, but also to transmit the ultraviolet light emitted from the ultraviolet lamp to the water extraction nozzle near 100% without loss, to the ultraviolet light emitted from the ultraviolet lamp. It is to provide a water purifier that can increase the sterilization efficiency of the water discharge nozzle.

An object of the present invention is to provide a water purifier that does not suffer injury even if a user exposes a finger to the water outlet nozzle of the water purifier because the ultraviolet rays emitted from the ultraviolet lamp are not exposed outside the water outlet nozzle.

An object of the present invention, when the light output from the light source is output to the lower side along the periphery of the water outlet nozzle through a ring-shaped diffusion member provided to surround the outer peripheral surface of the water outlet nozzle, the user can see the entire area of the water outlet nozzle by ultraviolet light It is to provide a water purifier that can more intuitively confirm that it is being sterilized.

The object of the present invention is to provide a water purifier that is hygienic and can prevent breakage and deformation of the water discharge nozzle.

An object of the present invention is to provide a water purifier capable of preventing a safety accident because a user of a small child cannot recognize the operation unit and cannot easily operate it even if it is recognized.

An object of the present invention is to provide a water purifier capable of recognizing an exit button to an adult user as well as a small child user, and to easily operate the exit button when proceeding with exit.

A water purifier according to an embodiment of the present invention for achieving the above object, a water purifier body including a housing forming an outer shape and a filter provided inside the housing to filter raw water flowing from the outside, and the water purifier body It is formed to protrude toward the front and includes a water discharge module including a water discharge nozzle for supplying water passing through the filter to the outside of the water purifier body, and a tray provided below the water discharge nozzle, wherein the water discharge module has a lower end. In the case where the water outlet nozzle is exposed, provided inside the case and provided on the upper side of the water outlet nozzle, an ultraviolet lamp that emits ultraviolet rays on the inner surface of the water outlet nozzle, is provided on the lower side of the ultraviolet lamp, and the ultraviolet lamp It includes a protective window of a light-transmitting material to protect from water and at least one light source for irradiating light to the inside or outside of the water outlet nozzle depending on whether the UV lamp is on or off. According to this, the user can always receive clean water through the sterilized water outlet nozzle. In addition, the user can confirm that the UV sterilization of the water outlet nozzle is in progress by looking at the lighting of a specific color from the outside of the water purifier.

In addition, ultraviolet rays emitted from the ultraviolet lamp may not be exposed outside the water outlet nozzle. According to this, it is safe because it is possible to prevent an accident in which a user's hand or the like is injured by ultraviolet rays exposed to the outside of the water discharge nozzle.

In addition, a diffusion member of a light-transmitting material is provided between the extraction nozzle and the case, and light output from the light source may be exposed to the outside of the extraction nozzle through the diffusion member. According to this, the light output from the light source is output downward along the periphery of the outlet nozzle, so that the user can more intuitively confirm that the entire area of the outlet nozzle is sterilized by ultraviolet rays.

In addition, the light source may be mounted on the bottom surface of the light source PCB, which is provided with an LED and is inclined so that the bottom surface faces the water outlet nozzle. According to this, the light of the light source is concentrated down the water outlet nozzle, so that a clearer light can be seen outside the water purifier.

In addition, the light source may be provided in plural, and may be provided to output at least two colors. At least one of the light sources may output light when ultraviolet light is irradiated from the ultraviolet lamp, or output light when water is extracted through the water extraction nozzle. According to this, the user can check how much water is filled in the cup placed on the tray under the condition that the field of view is not secured.

In addition, the protective window may be formed of a quartz material. According to this, it is possible to prevent the water flowing inside the water discharge module from splashing on the UV lamp, and to transmit the ultraviolet light emitted from the UV lamp to the water discharge nozzle near 100% without loss. Therefore, it is possible to increase the sterilization efficiency of the water discharge nozzle by ultraviolet rays emitted from the ultraviolet lamp.

In addition, the ultraviolet lamp can intermittently irradiate ultraviolet light. According to this, it is possible to lower the power consumption of the UV lamp while securing the sterilizing ability of the water discharge nozzle by UV light.

In addition, the outer member may be formed of a stainless material. According to this, it is hygienic because rust does not rust on the water discharge member, and damage and deformation occurring during frequent use can be prevented. In addition, it is possible to add a luxurious image to the water purifier, which is beautiful in appearance.

Further, the inner member and the outer member may be integrally injection molded. According to this, the bonding force between the inner member and the outer member is increased, and leakage can be prevented. In addition, it may be easier to manufacture than the conventional assembly method.

In addition, an operation unit may be provided on the upper surface of the water extraction module. According to this, in the case of a child user with a short height, the operation unit cannot be recognized, and even if it is recognized, it cannot be easily operated, so that a safety accident can be prevented.

In addition, a water extraction button may be provided on the front surface of the water extraction module. According to this, an exit button can be recognized by an adult user as well as a small child user, and if you want to exit, you can easily operate the exit button to proceed with the exit.

According to the present invention, there are the following effects.

According to the present invention, the user can always receive clean water through the sterilized water outlet nozzle.

According to the present invention, the user can see the illumination of a specific color from the outside of the water purifier, and confirm that UV sterilization of the water discharge nozzle is in progress.

According to the present invention, the user can check how much water is filled in the cup placed on the tray under the condition that the field of view is not secured.

According to the present invention, it is possible to prevent the water flowing inside the water discharge module from splashing on the ultraviolet lamp, and transmit the ultraviolet light emitted from the ultraviolet lamp to the water discharge nozzle near 100% without loss. Therefore, it is possible to increase the sterilization efficiency of the water discharge nozzle by ultraviolet rays emitted from the ultraviolet lamp.

According to the present invention, the ultraviolet light emitted from the ultraviolet lamp is not exposed to the outside of the water discharge nozzle, so that even if a user exposes a finger to the water discharge nozzle of the water purifier, there is an effect that does not cause injury.

According to the present invention, when the light output from the light source is output downward along the periphery of the outlet nozzle through a ring-shaped diffusion member provided to surround the outer peripheral surface of the outlet nozzle, the user sterilizes the entire area of the outlet nozzle by ultraviolet light. It can be seen more intuitively.

According to the present invention, it is hygienic and has the advantage of preventing breakage and deformation of the water discharge nozzle.

According to the present invention, in the case of a child user with a short height, the operation unit cannot be recognized, and even if it is recognized, it cannot be easily operated, thereby preventing safety accidents.

According to the present invention, an adult user as well as a child user of a short height can recognize the exit button, and if there is a desire to exit, there is an advantage of easily operating the exit button to proceed with the exit.

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 a partially cut-away perspective view of a water extraction module which is a part of the present invention.
FIG. 4 is a perspective view of the water extraction module with the case removed in FIG. 3.
5 is a longitudinal sectional view of a water extraction module, which is a component of the present invention.
6 is a cross-sectional view of a water extraction module that is a part of the present invention.
7 is a rear perspective view of the water extraction module, which is a component of the present invention.
8 is a view showing an example of on and off signals input to the ultraviolet lamp.
9 is a table comparing the sterilization performance according to the ultraviolet irradiation time.
10 is a circuit diagram schematically showing a water flow path of the water purifier.
11 is a block diagram showing the flow of the control signal of the water purifier.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. However, the spirit of the present invention is not limited to the embodiments presented below, and those skilled in the art to understand the spirit of the present invention may add other embodiments included within the scope of the same spirit by adding, changing, deleting, and adding components. It may be easily implemented, but it will also be said to be included within the scope of the present invention.

The drawings attached to the following embodiments are examples of the same invention idea, but in order not to be damaged, the invention may be expressed differently for each drawing in order to facilitate understanding. In some cases, a specific part may not be displayed according to the drawing or may be exaggerated according to the drawing.

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.

1 to 2, the water purifier 10 according to an embodiment of the present invention is provided with a housing 10 forming an outer shape and a filter provided inside the housing 10 to filter raw water introduced from the outside Water purifier main body 100 including 120, water outlet nozzle 280 formed to protrude in front of the water purifier main body 100 and supplying water that has passed through the filter 120 to the outside of the water purifier main body 100 ), and a tray 300 provided below the water extraction nozzle 280.

The outer shape of the water purifier body 100 may be formed by the housing 110. The housing 110 includes a front cover 111 forming a front appearance, a rear cover 112 forming a rear appearance, a base 113 forming a bottom surface, a top cover 114 forming a top surface, and left and right sides. It is composed of side panels 115 forming both sides. The front cover 111 and the rear cover 112, the base 113 and the top cover 114, and a pair of side panels 115 are assembled to each other to form a housing 110 that forms the exterior of the water purifier body 100 ).

At this time, the front and rear ends of the base 113 and the top cover 114 may be formed to be rounded, and the front cover 111 and the rear cover 112 may be formed to be rounded to the base 113 and the top cover ( 114) may be formed convexly in front and rear, respectively, to have a curvature corresponding to the front end and the rear end.

In addition, the water discharge module 200 is formed on the front surface of the water purifier main body 100. The water discharge module 200 is formed to protrude forward of the front cover 111, and purified water may be taken out through the water discharge nozzle 280 protruding downward.

For this, the mounting grooves 111a and 114a are formed in the front cover 111 and the top cover 114 so that the water outlet module 200 can be inserted and fixed.

In detail, the mounting groove 111a has a concave shape downward from the center top of the front cover 111, and the mounting groove 114a has a concave shape rearward from the front end of the top cover 114.

More detailed description of the water extraction module 200 will be described later.

Inside the housing 110, a filter 120 for water purification and a filter bracket 130 on which a plurality of valves (not shown) are mounted are provided.

The filter bracket 130 includes a bottom portion 131 coupled with the base 113, a filter receiving portion 132 in which the filter 120 is accommodated, and an outlet module mounting portion in which the outlet module 200 is mounted. (133).

In detail, the bottom portion 131 is formed to correspond to the shape of the front end of the base 113, and is coupled to the base 113. The mounting position of the filter bracket 130 may be fixed by the combination of the bottom surface portion 131, and a bottom surface shape of the filter receiving portion 132 may be formed.

The filter bracket 130 may be locked by a hook method to the base 113, and may also be fixed by a screw that is fastened on the lower surface of the base 113.

The filter accommodating part 132 is formed to extend in the vertical direction, and forms a recessed space from the front (left in the drawing) to the rear (right in the drawing) so that the filter 120 can be accommodated. A plurality of filters 120 may be mounted on the filter accommodation unit 130. The filter 120 is for purification of raw water (tap water) supplied, and may be configured to combine filters having various functions.

In addition, the filter housing 130 may be further provided with a filter socket 134 on which the filter 120 is mounted, and the filter socket 134 is provided with a pipe through which purified water flows. The piping can be connected to multiple valves (not shown). Therefore, the raw water passes through the filter 120 in order to be directed to a valve (not shown) for water supply.

A plurality of valves (not shown) may be provided on the rear surface (right side of the drawing) of the filter accommodating part 132, and the valves (not shown) may include the filter 120, as well as the cooling tank 150. The induction heating assembly 160 and the water extraction module 200 selectively supply purified water, cold water, and hot water.

The water receiving module mounting portion 133 is formed at an upper end of the filter receiving portion 132. The water outlet module mounting portion 133 has a structure in which the mounting groove 133a is formed from the top to the bottom at the top so that the water outlet module 200 can be inserted and fixed. At this time, the outlet module mounting portion 133 may be formed to have a curvature corresponding to the curvature of the front cover 111 that covers the front of the outlet module mounting portion 133. The upper portion of the filter bracket 130 may be shielded by a top cover 114.

A compressor 141 and a condenser 142 are provided on the upper surface of the base 113. In addition, a cooling fan 143 is provided between the compressor 141 and the condenser 142 to be configured to cool the compressor 141 and the condenser 142. As the compressor 141, an inverter type compressor capable of adjusting the cooling capacity by varying the frequency may be used. Therefore, cooling of purified water can be efficiently performed, thereby reducing power consumption.

In addition, the condenser 142 may be located at the rear of the base 113 and may be positioned at a position corresponding to the outlet 112a formed in the rear cover 112. The condenser 142 may be formed by bending a plurality of flat tube type refrigerant tubes multiple times in order to improve the heat exchange efficiency while simultaneously using the space efficiently and configured to be accommodated in the condenser bracket 144.

The condenser bracket 144 is formed with a condenser mounting portion 145 to which the condenser 142 is fixed, and a tank mounting portion 146 on which a cooling tank 150 for making cold water can be mounted. The condenser mounting portion 145 forms a space corresponding to the overall shape of the condenser 142 to accommodate the condenser 142. In addition, the condenser mounting portion 145 is formed such that the portions facing the cooling fan 143 and the discharge port 112a are opened, thereby enabling effective cooling of the condenser 142.

And, the tank mounting portion 146 is formed above the condenser bracket 144, that is, above the condenser mounting portion 145. The lower end of the cooling tank 150 is inserted into the tank mounting part 146 so that the tank mounting part 146 fixes the cooling tank 150.

The cooling tank 150 is for cooling purified water to make cold water, and cooling water for heat exchange with the purified water is filled. In addition, an evaporator 151 for cooling the cooling water may be accommodated in the cooling tank 150. And, it is possible to cool the purified water by allowing the purified water to pass through the inside of the cooling tank.

One side of the filter bracket 130 is further provided with a support plate 135 extending toward the cooling tank 150. The support plate 135 is provided above the compressor 141 and extends from the filter bracket 130 to the condenser bracket 144 to provide a space in which the heating and control modules 160 and 170 are mounted.

The heating and control modules 160 and 170 may include an induction heating assembly 160 for making hot water and a control assembly 170 for controlling the overall driving of the water purifier 10. The induction heating assembly 160 and the control assembly 170 may be combined with each other to be combined in a single module state, and may be mounted on the support plate 135 in a combined state.

The induction heating assembly 160 is for heating purified water and is configured to be heated by an induction heating (IH) method. The induction heating assembly 160 is capable of heating water at an instant and rapid rate during a hot water extraction operation, and controlling the output of a magnetic field to heat purified water to a desired temperature and provide it to a user. Therefore, it is possible to take out hot water at a desired temperature according to the user's operation.

The control assembly 170 is for controlling the operation of the water purifier 10, it is possible to control the compressor 141, the cooling fan 143, and various valves and sensors, the induction heating assembly 160, etc. It is configured to. The control assembly 170 may be configured to be modularized by a combination of PCBs divided into a plurality of parts for each function. In addition, in the structure in which the water purifier 10 takes out only cold water and purified water, the fish ratio for controlling the induction heating assembly 160 may be omitted, and at least one or more fish ratios may be omitted in this manner.

Hereinafter, the water extraction module, which is a part of the present invention, will be described in more detail.

3 is a partially cut-away perspective view of a water extraction module which is a part of the present invention. And, Figure 4, in Figure 3, is a perspective view of the water extraction module with the case removed. And, Figure 5 is a longitudinal cross-sectional view of the water extraction module that is a component of the present invention.

3 to 5, the water extraction module 200 includes a case 220 in which the water discharge nozzle 210 is exposed at the bottom, and is provided inside the case 220 and is provided in the water discharge nozzle 210. It is provided on the upper side, is provided on the lower side of the ultraviolet lamp 230 and the ultraviolet lamp 230 to emit ultraviolet rays on the inner surface of the water outlet nozzle 210, the light transmittance to protect the ultraviolet lamp 230 from water It includes a protective window 240 of the material, and at least one light source 250 for irradiating light to the inside or outside of the water outlet nozzle 210 depending on whether the UV lamp 230 is on or off.

The ultraviolet lamp 230 is provided on the upper side of the water outlet nozzle 210, and emits ultraviolet rays. The ultraviolet light emitted from the ultraviolet lamp 230 sterilizes the inner space of the water outlet nozzle 210. Therefore, the user can always receive clean water through the sterilized water outlet nozzle 210.

For example, the ultraviolet lamp 230 may be provided with a UV LED that emits ultraviolet rays. In addition, the ultraviolet lamp 230 may emit ultraviolet rays having a wavelength of 300 nm to 400 nm, specifically, 380 nm.

In this embodiment, the UV LED may be mounted on the UV LED PCB 280.

In addition, the protection window 240 is provided to prevent water flowing along the inside of the water discharge module 200 from splashing toward the ultraviolet lamp 230.

In detail, the protective window 240 is made of a transparent glass or plastic material, and transmits the ultraviolet light output from the ultraviolet lamp 230 to the water outlet nozzle 210. In addition, the water passing through the water outlet nozzle 210 is blocked from splashing with the UV lamp 230.

For example, the protective window 240 may be formed of a quartz material.

In the case of quartz (SiO2 99.9%), the light transmission ratio (透光率) reaches 96%. Therefore, when the protective window 240 is formed of a quartz material, it is possible to prevent water flowing inside the water discharge module 200 from splashing on the ultraviolet lamp 230, and also to prevent ultraviolet rays emitted from the ultraviolet lamp 230. It can be delivered to the water extraction nozzle 210 near 100% without loss. Therefore, it is possible to increase the sterilization efficiency of the water discharge nozzle 210 by ultraviolet rays emitted from the ultraviolet lamp 230.

The light source 250 irradiates light to the inside or outside of the water outlet nozzle 210 depending on whether the UV lamp 230 is on or off.

For example, when the UV lamp 230 is turned on, the light source 250 is turned on and irradiates light to the inside or outside of the water outlet nozzle 210. In addition, when the ultraviolet lamp 230 is turned off, the light source 250 is also turned off.

Conversely, when the ultraviolet lamp 230 is turned on, the light source 250 is turned off, and when the ultraviolet lamp 230 is turned off, it is possible that the light source is turned on.

The purpose of the light source 250 is to inform the user of the sterilization of ultraviolet rays. Accordingly, the light output from the light source 250 is bright enough to be identified by the user when it is exposed to the outside of the water discharge module 200 in parallel with the water discharge nozzle 210 after being output from the light source 250 Should have

With the configuration of the light source 250, the user sees the light exposed outside the water discharge module 200 in parallel with the water discharge nozzle 210 from the outside of the water purifier, and determines whether the water discharge nozzle 210 is sterilized by ultraviolet rays. It can be checked visually.

The light source 250 may be provided as an LED. In addition, the LED may be mounted on the light source PCB 270. The light source PCB 270 may be provided on the top or one side of the water outlet nozzle 210, fixed to the water outlet nozzle 210, or fixed to the upper frame 290, inside the case 220 It can be fixed.

In addition, an upper frame 290 on which the UV lamp 230 is seated may be provided on an upper portion of the water discharge nozzle 210.

If the UV lamp 230 is provided with a UV LED, the upper frame 290 may be provided with a storage groove 291 in which the UV LED PCB 280 is seated.

In addition, an opening 293 may be formed in the upper frame 290 such that the UV LED mounted on the bottom surface of the UV LED PCB 280 is exposed toward the water outlet nozzle 210.

Therefore, the ultraviolet light emitted from the UV LED is irradiated to the water outlet nozzle 210 through the opening 293, so that the ultraviolet light sterilization of the water outlet nozzle 210 may proceed.

In addition, the ultraviolet light emitted from the ultraviolet lamp 230 is not exposed to the outside of the water outlet nozzle 210, but is irradiated only inside the water outlet nozzle 210.

That is, the ultraviolet ray emitted from the UV lamp 230 may have a boundary at the bottom of the water outlet nozzle 210.

It is known that the cumulative exposure of ultraviolet rays allowed to human skin during the day is 3 mJ/cm2.

If the ultraviolet light emitted from the ultraviolet lamp 230 is exposed outside the water outlet nozzle 210, it may have a bad effect on the user.

Therefore, the output of the ultraviolet lamp 230 or the height of the ultraviolet lamp 230 is adjusted so that the boundary of the ultraviolet rays emitted from the ultraviolet lamp 230 is located at the bottom of the water outlet nozzle 210, or the height of the ultraviolet lamp 230 is adjusted. ) And the spacing of the water extraction nozzle 210.

When the ultraviolet light emitted from the ultraviolet lamp 230 is not exposed to the outside of the water discharge nozzle 210 as described above, even if a user exposes a finger to the water discharge nozzle 210 of the water purifier, it may not be injured.

In addition, a diffusion member 260 of a light transmissive material is provided between the extraction nozzle 210 and the case 220, and the light output from the light source 250 is discharged through the diffusion member 260 ( 210).

In this embodiment, the diffusion member 260 may be provided in a ring (ring) form.

In detail, the case 220 forms an installation hole 221 through which the water outlet nozzle 210 passes. At this time, a clearance is formed between the outlet nozzle 210 and the installation hole 221, and a diffusion member 260 may be fitted into the clearance.

As described above, since the diffusion member 260 is provided with a light transmissive material, light output from the light source 250 installed inside the case 220 may be exposed outside the case 220 through the diffusion member 260. Therefore, the user can recognize the light output from the light source 250 from the outside of the water purifier.

In this case, the diffusion member 260 may simply pass the light output from the light source 250 as well as diffuse it. That is, the diffusion member 260 may function as a diffuser for LED lighting.

As described above, the light output from the light source 250 is output in the form of a ring along the circumference of the outlet nozzle 210 through the ring-shaped diffusion member 260 provided to surround the outer circumferential surface of the outlet nozzle 210. Once, the user can intuitively confirm that the entire area of the water outlet nozzle 210 is being sterilized by ultraviolet light. In addition, the light output from the light source 250 may also be used as illumination for illuminating the cup placed on the tray 300.

As a modified example, the light source 250 may be mounted outside the case 220.

In addition, the light source 250 is provided with an LED, and the bottom surface 270a may be mounted on the bottom surface 270a of the light source PCB 270 inclined to face the water outlet nozzle.

As described above, when the LED is mounted on the bottom surface 270a of the light source PCB 270, the light output from the LED is blocked by the light source PCB 270 to the upper portion, and can be focused and output only to the lower portion. In addition, since the bottom surface 270a of the light source PCB 270 is inclined to face the diffusion member 260, the light output from the LED mounted on the bottom surface 270a of the light source PCB 270 is a diffusion member ( 260), and may be exposed outside the case 220 through the diffusion member 260.

Also, a plurality of light sources 250 may be provided, and at least two colors may be output.

As described above, when a plurality of light sources 250 are provided, the intensity of the light sources 250 may be adjusted according to the situation.

In addition, when the light source 250 outputs a plurality of colors, the colors of the light source 250 may be adjusted according to various situations.

For example, the light source 250 may include a first LED 251 outputting blue and a second LED 252 outputting white.

When a plurality of light sources 250 are provided as described above, different colors of light may be output according to the situation to inform the user.

First, in the state in which ultraviolet sterilization of the water discharge nozzle 210 is in progress, the first LED 251 is turned on, and blue light may be output to the water discharge nozzle 210. Therefore, the user can see the blue light from the outside of the water purifier, and confirm that ultraviolet sterilization of the water discharge nozzle 210 is in progress.

In addition, the second LED 252 is turned on when the water is discharged from the water discharge nozzle 210 by the operation of the water discharge button 420, and white light can be output to the periphery of the water discharge nozzle 210. Therefore, the user can check how much water is filled in the cup placed on the tray 300 under the condition that the field of view is not secured. It can also be used as mood lighting.

A seating portion 214 on which the protective window 240 is seated is formed on an upper portion of the outlet nozzle 210, and a sealing made of an elastic material for sealing between the protective window 240 and the seating portion 214 The member 215 may be provided. For example, the sealing member 215 may be made of silicon. With the configuration of the sealing member 215, water passing through the water discharge nozzle 210 can be prevented from leaking between the seating portion 214 and the protective window 240.

In addition, an operation unit 410 may be provided on an upper surface of the water extraction module 200, and a water extraction button 420 may be provided on the front surface of the water extraction module 200.

As described above, in order for the operation unit 410 to be provided on the upper surface of the water discharge module 200, a storage space in which the operation unit 410 is accommodated may be formed on the upper surface of the case 220.

According to the present invention, the operation unit 410 is provided on the upper surface of the water extraction module 200, so that a tall adult user can easily control the overall operation of the water purifier 10. On the other hand, in the case of a small child user, it is impossible to recognize the operation unit 410 provided on the upper surface of the water extraction module 200, and even if it is recognized, it cannot be easily operated, so that hot water is discharged by pressing the operation unit 410 at random. This can prevent safety accidents such as burning hands.

On the other hand, the water extraction button 420 is provided on the front of the water extraction module 200, so that an adult user as well as a small child user can recognize the water discharge button 420, and if you want water extraction, the water extraction button 420 can be easily By maneuvering, it is possible to proceed with water extraction.

For example, the operation unit 410 is provided with a touch panel, a capacity button 411 for selecting the water discharge capacity, a hot water button, and further, a hot water button 412 for selecting the temperature of the hot water to be discharged, for selecting water purification It may include a water purification button 413, a cold water button 414 for selecting cold water, a continuous button 415 for selecting continuous water, and a sterilization button 416 for turning UV sterilization on and off.

6 is a cross-sectional view of a water extraction module that is a part of the present invention.

Referring to FIG. 6, the water extraction module 200 transmits cold water or purified water flowing through the first hose 610 and hot water flowing through the second hose 620 to the water outlet nozzle 210. The protection window 240 may further include a chamber 201 provided on the lower side.

For example, the chamber 201 may be formed on the water outlet nozzle 210. Therefore, cold water or purified water introduced through the first hose 610 and hot water introduced through the second hose 620 are all joined in the chamber 201 or even after passing through the chamber 201, even if they are not joined. It can escape to the outside of the water outlet nozzle 210.

In addition, the water outlet nozzle 200, a hollow 202 through which water is discharged is formed inside, the upper end of the inner member 211 connected to the protective window 240, and the outer side of the inner member 211 It may include an outer member 212 connected to the bottom and exposed to the outside of the case 220.

At this time, a chamber 201 in communication with the hollow 202 may be formed on an upper portion of the inner member 211. The chamber 201 has a larger diameter than the hollow 202 beam.

In addition, a plurality of ribs 203 protruding toward the center on the inner surface may be formed in the hollow 202 along the exit direction. The rib 203 catches the shape of a stream of water and improves vortices.

In addition, the inner member 211 includes a first connector 211a into which a first hose 610 for supplying cold water or purified water is inserted, and a second connector 211b into which a second hose 620 for supplying hot water is inserted. ), and the first connector 211a and the second connector 211b may communicate with the hollow 202. Accordingly, cold water or purified water transferred to the first hose 610 and hot water transferred to the second hose 620 may be supplied to the chamber 201 side.

In addition, the first connector 211a and the second connector 211b are provided with a hollow packing part 213 having elasticity, so that the first hose 610 and the second hose 620 are provided with the packing part 213. ). For example, the packing part 213 may be formed of a silicon material.

Further, a protrusion 213a may be formed on the inner peripheral surface along the circumferential direction on the packing portion. For example, the protrusion 213a may be provided in the form of a ring.

With the configuration of the packing 213 in which the protrusion 213a is formed as described above, the first hose 610 and the second hose 620 are more securely fixed to the first connector 211a and the second connector 211b. It can be prevented from leaking between the first connector 211a and the first hose 610 and the second connector 211b and the second hose 620.

In addition, the outer member 212 may be formed of a stainless material.

When the outer member 212 exposed to the outside of the case 220 is formed of a stainless material as described above, it is hygienic because it does not rust and can prevent damage and deformation occurring during frequent use. In addition, it is possible to add an elegant image and a luxurious image to the water purifier 10.

In addition, the inner member 211 and the outer member 212 may be integrally injection molded.

Here, the outer member 212 is provided with a metal material, the inner member 211 and the outer member 212 may be integrally formed by an insert injection method. Therefore, the bonding force between the inner member 211 and the outer member 212 is increased, and leakage can be prevented. In addition, it may be easier to manufacture than the conventional assembly method.

At this time, in order to increase the bonding force between the inner member 211 and the outer member 212, the inner member 211 is formed with a projection 211c on the outer circumferential surface, and the outer member 212 has the projection 211c on the inner circumferential surface. A groove portion to be fitted may be formed.

7 is a rear perspective view of the water extraction module, which is a component of the present invention.

6 to 7, a pair of through holes 292 in which the first hose 610 and the second hose 620 are fitted may be formed in the upper frame 290. At this time, the through hole 292 is in communication with the first connector 211a and the second connector 211b. Therefore, the first hose 610 and the second hose 620 that have passed through the through hole 292 may be fitted to the first connector 211a and the second connector 211b.

With the configuration of the upper frame 290 as described above, after the first hose 610 and the second hose 620 are first inserted into the through hole 292, the first connector 211a and the second connector 211b It can be fitted in, it can be secured the support force of the first hose 610 and the second hose 620.

8 is a view showing an example of on and off signals input to the ultraviolet lamp. And, Figure 9 is a table comparing the sterilization performance according to the ultraviolet irradiation time.

Referring to FIG. 8, the ultraviolet lamp 230 may intermittently irradiate ultraviolet light.

The ultraviolet lamp 230 may continuously emit ultraviolet rays, but may repeatedly sterilize the outlet nozzle 210 while repeatedly turning on and off.

As described above, when the ultraviolet lamp 230 intermittently outputs ultraviolet light, power consumption can be reduced while ensuring sterilization performance of the water-extraction nozzle 210 by the ultraviolet light.

For example, the UV lamp 230 may be turned on for 5 minutes and off for 55 minutes.

Referring to FIG. 9, it is possible to confirm the sterilization performance according to the irradiation time of the UV LED (1 mV), and when the UV LED (1 mV) is turned on for 5 minutes and irradiated with ultraviolet light, it can be confirmed that 99.96% of sterilization is achieved.

Therefore, when the ultraviolet light is irradiated for only 5 minutes, the sterilizing power of 99.9% or more can be maintained, and thus the ultraviolet lamp 230 is turned on for only 5 minutes per hour.

Hereinafter, the ultraviolet sterilization method of the water purifier as described above will be described.

Referring to (a) of FIG. 8, when the power of the water purifier is turned on, a timer is operated to detect on and off times of the ultraviolet lamp 230.

At this time, the UV lamp 230 is turned on for 5 minutes and is set to repeat the operation for 55 minutes.

After power is applied to the water purifier, when the off time of the UV lamp 230 detected by the timer reaches 55 minutes, the UV lamp 230 is turned on. That is, while the ultraviolet lamp 230 is turned on, sterilization of the water discharge nozzle 210 is performed. As described above, while the UV lamp 230 is turned on, the light source 250 outputs blue light to visually inform the user that UV sterilization is in progress.

Then, when the on time of the UV lamp 230 detected by the timer reaches 5 minutes, the UV lamp 230 is turned off. That is, the ultraviolet lamp 230 is turned off. In addition, the light source 250 is also turned off.

Thereafter, the process of turning off the UV lamp 230 for 55 minutes and turning on the UV lamp 230 for 5 minutes are repeated.

However, as shown in (b) of FIG. 8, when the ultraviolet lamp 230 is turned on, when water is taken out from the water outlet nozzle 210, the ultraviolet lamp 230 is turned off. At this time, the blue light of the light source 250 is also turned off.

In addition, the blue light of the light source 250 is also turned off when the ultraviolet lamp 230 is turned off due to a failure or the like.

Therefore, the user can visually confirm that ultraviolet sterilization is not performed from the outside and take immediate action. In addition, in a situation in which ultraviolet sterilization is not in progress, the user may not mistake that ultraviolet sterilization is in progress. That is, it is possible to prevent the situation of deceiving the user.

In addition, when the ultraviolet lamp 230 is turned off, when water is taken out from the water outlet nozzle 210, the light source 250 may output white light toward the cup placed on the tray 300.

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

10 is a circuit diagram schematically showing a water flow path of the water purifier. And, Figure 11 is a block diagram showing the flow of the control signal of the water purifier.

As shown in the figure, the water supply pipe 191 of the water purifier 10 is connected to the water supply to receive raw water. The inlet pipe 191 is connected to the pressure reducing valve 192, and the raw water passing through the pressure reducing valve 192 is decompressed to a pressure set for the operation of the water purifier 10.

Then, the decompressed raw water flows to the filter 120 side along a pipe connecting the pressure reducing valve 192 and the filter 120. The raw water that passes through the filter 120 is debris removed to be purified. And, by the opening of the water supply valve 193, purified water passes through the water supply valve 193 along the piping and sequentially flows through the flow sensor 194.

At this time, the water supply valve 193 and the flow sensor 194 may be connected to the main PC ratio 510, and the opening degree of the water supply valve 193 may be adjusted according to a signal transmitted from the main PC ratio 510. do. In addition, the flow rate sensed by the flow sensor 194 may be transmitted to the main PC ratio 510 and used as data necessary for controlling the water purifier.

The purified water passing through the flow sensor 194 may be branched to the cold purified water side 195a and the hot water side 195b through the branch pipe 195.

First, the purified water flowing into the pipes of the cold purified water side 195a is branched to the cold water side 196a and the purified water side 196b again by the T connector 196, respectively, and the cold water outlet valve 197 and the purified water outlet valve 198, respectively. Is connected to. The purified water outlet valve 198 and the cold water outlet valve 197 may be connected to the main PCB 510 to determine opening and closing. That is, the purified water outlet valve 198 and the cold water outlet valve 197 may be selected by the user's setting, and the selected valve may be opened through the operation of the outlet button 420 to extract water.

Meanwhile, the water that has passed through the cold water outlet valve 197 passes through the cooling coil inside the cooling tank 150. Water flowing along the cooling coil is cooled by heat exchange with cooling water inside the cooling tank 150, and for this purpose, the cooling water is cooled to maintain a set temperature.

A compressor 141 connected to the main PC ratio 510 is driven to cool the cooling water. The operation of the compressor 141 may be determined by the cold water temperature sensor 152 provided inside the cooling tank 150. Therefore, the cooling water may always maintain a set temperature, and for this purpose, the driving of the compressor 141 may be controlled. The compressor 141 is an inverter compressor, the frequency is adjusted in response to the required load, the cooling capacity can be adjusted. That is, the compressor 141 can be driven by inverter control and can cool the cooling water with optimum efficiency.

Meanwhile, the compressor 141 may set the operation to a forced OFF state by a user operating the operation unit 410. When the winter time or the power saving is required when consumption of cold water is low, or when the use of cold water is not desired, the compressor 141 may be forced to remain in an off state.

In addition, the main PCB 510 controls the driving of the compressor 141 as well as the driving of the cooling fan 143. In addition, the main PCB 510 may control driving of the stirrer motor 153 provided inside the cooling tank 150. The motor 153 is driven to increase the efficiency of heat exchange between cooling water and cold water passing through the cooling coil, and is controlled by the main PC ratio 510. The stirrer is rotated by the driving of the motor 153, and the cooling water can be forced to be convected inside the cooling tank 150, and consequently, effectively cools the purified water inside the cooling coil.

Cold water passing through the cooling tank 150 flows into the water outlet pipe 182 through the T connector 181, and cold water passing through the water outlet pipe 182 can be taken out through the water outlet nozzle 280. .

Meanwhile, when the purified water outlet valve 198 is opened, purified water passing through the purified water outlet valve 198 flows into the outlet pipe 182 through the T connector 181, and the outlet pipe 182 After passing through, it can be taken out through the water discharge nozzle 280.

On the other hand, if the user chooses to take out the hot water, purified water may flow to the hot water side 195b of the branch pipe 195. The flow control valve 199 is opened by the control of the main fish ratio 510, and water flowing through the flow control valve 199 is adjusted to a proper flow rate for heating of hot water. That is, the amount of purified water supplied to the hot water tank 161 is controlled so that water can be heated to a temperature set by the induction heating assembly 160.

The purified water passing through the flow control valve 199 passes through the hot water tank 161. And, it can be heated to a temperature set in the process of passing the hot water tank 161. The hot water tank 161 may be heated by an induction heating method, and for this purpose, the output of the magnetic force of the working coil may be controlled by the control of the induction heating PCB ratio 520.

In order to drive the induction heating assembly 160, a high voltage is required compared to the main PCB 510, and power is supplied from a power supply PCB 530 connected to a power line for supply of the high voltage. The power supply PCB ratio 530 supplies suitable power depending on whether the induction heating assembly 160 is driven, and also supplies power suitable for the main PCB ratio 510.

Water inside the hot water tank 161 may be heated to a set temperature by driving the induction heating assembly 160. The hot water outlet valve 183 may be provided with a hot water temperature sensor. The hot water temperature sensor senses the temperature of the hot water flowing out of the hot water tank 161 and transmits it to the main PCB 510. In addition, in the main PCB 510, the output of the working coil can be adjusted based on input hot water temperature data.

In addition, the temperature of the hot water tank 161 itself may be sensed by the tank temperature sensor 162 provided outside the hot water tank 161. When the tank temperature sensor 161 rises above a set temperature and there is a fear that a fire may occur, a signal may be transmitted to the main PC ratio 510 to short the fuse 184. On the other hand, an overload protection (OLP) 147 may be connected to the main PC ratio 510, and the OLP 147 may cut off the power supply when the compressor 141 is overloaded, so that the compressor 141 To protect.

When the fuse 184 is short-circuited due to an abnormal operation of the induction heating assembly 160, power supplied from the power supply PCB 530 to the induction heating PCB 520 is cut off, so that the induction heating assembly 160 ) To prevent overheating and damage.

The hot water heated by passing through the hot water tank 161 by the hot water outlet valve 183 flows to the outlet nozzle 280 through the hot water pipe 185 and can be taken out.

Meanwhile, when water is taken out by the operation of the water discharge button 420, the LED of the operation unit 410 may be lit by the control of the display PCB 430.

The operation unit 410 may be provided with a hot water button, a water purification button, and a cold water button. At this time, in the case of the hot water button, the temperature of the temperature may be set. In addition, a capacity selection button for setting the water discharge capacity and a continuous button for selecting the continuous water discharge may also be provided. In addition, a lock button for temporarily blocking operation of the operation unit 410 may be provided, and a sterilization button for turning UV sterilization on and off may be provided.

For reference, when a UV sterilization command is input through a sterilization button, ultraviolet sterilization of the water outlet nozzle 210 is performed.

In detail, when the power of the water purifier is turned on, when the sterilization button 416 is pressed, the main PCB 510 turns on the UV lamp 230 through the UV LED PCB 280, and the water extraction nozzle 210 UV sterilization proceeds. In addition, the main PCB 510 turns on the light source 250 through the light source PCB 270, so that the ultraviolet lamp 230 and the light source 250 are turned on at the same time. For example, the blue light may be output from the light source 250, and the user may recognize the blue light from the outside of the water purifier and visually confirm that ultraviolet sterilization is in progress.

Thereafter, when the UV lamp 230 is turned off by an operation of a timer or a user's operation (a water discharge command or a sterilization off command), the light source 250 is also turned off. Therefore, the user can visually confirm that ultraviolet sterilization does not proceed from the outside.

According to the present invention, according to the operation of the water outlet button 420, when water is taken out from the water outlet nozzle 210, the ultraviolet lamp 230 is turned off, so that the power supplied to the ultraviolet lamp 230 is turned off. It may include a control unit (not shown) to block.

In addition, when an exit command is input through the exit button 420, the light source 250 outputs white light, and the output light is exposed around the exit nozzle 210 to open the cup placed on the tray 300. Can shine.

In addition, the operating state or degree of operation of the water purifier 10 may be displayed by being transmitted to a terminal such as a user's mobile phone through a wireless communication module (wifi, 450). In addition, information and an operation signal may be transmitted to the wireless communication module (wifi, 450) through the terminal, and the water purifier 10 may be driven using the transmitted information.

For example, the user can check information such as the life of the filter 120 and the usage pattern of the water purifier 10 through an app installed on the mobile phone, and a power saving mode that turns off the cold water mode of the water purifier 10 through the app. It is possible to set the operation of the other water purifier 10, such as setting.

On the other hand, during the use of the water purifier 10, the cooling water inside the cooling tank 150 may be drained and new cooling water may be filled.

10: water purifier
100: water purifier body
110: housing
120: filter
200: water extraction module
300: tray
410: operation unit
420: Water button

Claims (20)

case;
It is provided on the outside of the case, the water extraction button is input from the user the water discharge command;
At least a portion is exposed to the lower portion of the case, a hollow extending in the vertical direction is formed, the water outlet nozzle for supplying water to the outside of the case;
A UV LED PCB provided inside the case and disposed above the water outlet nozzle;
An ultraviolet lamp which is installed on the bottom of the UV LED PCB and emits ultraviolet rays inside the water outlet nozzle;
A protective window of a light-transmitting material installed between the lower side of the ultraviolet lamp and the hollow;
A light source installed in the case spaced apart from the UV LED PCB and irradiating light;
When power is supplied to the UV lamp, the water discharge module including a control unit that supplies power to the light source to indicate that the UV lamp is in an operating state. According to claim 1,
The upper portion of the water outlet nozzle, a chamber is formed to transfer the cold water or purified water or hot water introduced through a separate hose to the hollow, and the protection window is an outlet module disposed on the upper side of the chamber. According to claim 2,
The chamber, the outlet module is provided on the upper side of the outlet nozzle to communicate with the hollow. According to claim 2,
The chamber, the outflow module having a diameter larger than the hollow of the outflow nozzle. According to claim 1,
The water outlet nozzle is:
An inner member having the hollow formed therein and an upper end connected to the protective window;
A water outlet module including an outer member connected to an outer lower end of the inner member and exposed to the outside of the case. According to claim 1,
On the upper portion of the water outlet nozzle, a seating portion on which the protection window is seated is formed, and between the protection window and the seating portion, a sealing member made of an elastic material for sealing is provided. According to claim 1,
In the hollow, a plurality of ribs protruding from the inner surface toward the center are formed along the exit direction. According to claim 1,
The UV lamp is a water discharge module that emits ultraviolet light from the upper side to the lower side in parallel with the water discharge nozzle. The method of claim 8,
The UV light emitted from the UV lamp is not exposed to the outside of the water discharge nozzle, and the water discharge module is irradiated only inside the water discharge nozzle. The method of claim 8,
The UV light emitted from the UV lamp is irradiated only up to the bottom of the water outlet nozzle. According to claim 1,
The control unit, according to the operation of the water discharge button, when water is taken out from the water discharge nozzle, the UV lamp is turned off (off), the water discharge module to cut off the power supplied to the UV lamp. According to claim 1,
A light-transmitting material diffusion member is provided around the water discharge nozzle, and the light output from the light source is exposed to the outside of the water discharge nozzle through the diffusion member. The method of claim 12,
The diffusion member, the water discharge module is provided in a ring (ring) form to surround the circumference of the water discharge nozzle. According to claim 1,
The light source is provided with an LED, and the water discharge module is mounted on the bottom surface of the light source PCB disposed at an angle so that the bottom faces the water discharge nozzle. According to claim 1,
The light source is provided with a plurality, the water discharge module provided to output at least two colors. The method of claim 15,
The light source includes a first LED and a second LED, which output light of different colors,
When the ultraviolet sterilization of the water outlet nozzle proceeds, the first LED is turned on,
When the water discharge proceeds from the water discharge nozzle, the water discharge module, the second LED is turned on. According to claim 1,
The ultraviolet lamp,
A water discharge module that sterilizes from the top to the bottom of the inner surface of the water discharge nozzle. According to claim 1,
The UV lamp is a water discharge module provided with a UV LED. According to claim 1,
The protective window is a water extraction module formed of a quartz material. According to claim 1,
The ultraviolet lamp, the water discharge module intermittently irradiating ultraviolet rays.

Images