KR19980069531A - Heat exchanger of water distributor - Google Patents

Abstract

The heat exchanger of the water distributor of the present invention, wherein the cold water tank 450 and the cold sink 491 is the first and second cold water tank (650), 750 and the first and second cold sink (891) (991) And a first coupling screw 493a coupled to each other, and the thermoelectric element 492 and the heat sink 495 disposed on the lower surface of the second cold sink 991 have a plurality of second coupling screws. Coupled with the second cold sink 991 via the (493b), the second fastening screw (493b) when the thermoelectric element 492, the heat sink 495 and the second cold sink (991) is assembled. Since the distance L is preset by the fastening groove 991b formed in the second cold sink 991, even if the same pressure is not applied to each of the second fastening screws 493b, the second cold water container 750 The spacing (H) between the bottom surface of the heat sink and the top surface of the heat sink 495 is always constantly assembled, as well as preventing deformation and breakage of the thermoelectric element 492, as well as the fastening screw. The assembly of the thermoelectric element 492, the heat sink 495, and the second cold sink 991, which are coupled through the 493, is divided into three parts to increase productivity.

Description

Heat exchanger of water distributor

The present invention relates to a water distributor in which various harmful substances contained in raw water such as tap water are purified and purified by reverse osmosis, and the purified water is then cooled and heated by means of cooling and heating. In particular, the present invention relates to a heat exchanger of a water distributor, in which a thermoelectric element is not damaged or a unique property (characteristic) is changed when the heat exchanger is combined.

The general water distributor removes foreign substances contained in the raw water by passing the raw water supplied from the tap water into a separate filtering means.

Such a water distributor may be classified into natural filtration, direct filtration, ion exchange resin, and reverse osmosis according to the method of water purification. Among these, the reverse osmosis water distributor may apply artificial pressure by applying a predetermined pressure to the raw water. Water purification is performed by passing through the membrane, which is an ordinary osmotic membrane, to remove heavy metals, bacteria, carcinogens, etc., and to pass only pure water and dissolved oxygen.It is used for cutting-edge scientific industry or cleaning of high-precision electronic parts or medical use. Recently, due to serious environmental pollution, it is widely used in home and business water distributors for drinking water.

Accordingly, in view of the above, the reverse osmosis water distributor has been proposed by the present applicant to Korean Patent Application No. 96-16753 (filed date: May 17, 1996).

That is, the conventional water distributor, as shown in Figures 1 to 3, the front panel 11, the rear panel 12, both side panels 13, the upper panel 14, the lower side of the main body 10 Panel 15 is assembled to each other.

At this time, the outer middle height of the front panel 11 is provided with a drip tray 16 to collect the residual water falling from the intake valve to be described later and to drain the collected residual water manually or automatically.

In addition, a first partition member 20 is installed in the horizontal direction so that a space E having a predetermined area is formed on an upper side with respect to a predetermined height inside the main body 10, and the first partition member 20 and the lower portion are provided. The second partition member 21 is provided in the longitudinal direction so that a space F of a predetermined area is formed on the rear side with respect to the panel 15, and the first partition member 20 and the lower panel 15 are provided. The third partition member 22 is installed in the horizontal direction at a predetermined height of the front side of the second partition member 21 so that the space G of one front area is formed at the front upper and lower portions, respectively. It is.

At this time, in the space (E) is provided with a water storage tank 30 for storing a constant amount of constant water on the upper surface via the first partition member 20, the operation of the product on the front panel (11) The control pad 40 to which the main PCB 41 (Main Printed Circuit Board) which can be selectively operated is attached is provided.

The space F is provided with a plurality of filtration means 60 so as to be supported by the first and second filter fixing brackets 50 and 51 at a predetermined height on the rear surface of the second partition member 21 so as to be interchangeable. In addition, a pressure pump 70 is installed at one side of the upper surface of the lower panel 15.

That is, as shown in Figure 4, the plurality of filtering means 60 is installed through the first filter fixing bracket 50 is contained in the raw water when the raw water supplied from the tap (not shown) is passed through A first filter fixing bracket 50 to remove foreign substances such as chlorine components contained in the raw water when the raw water supplied from the sedimentation filter 61 and the raw water supplied from the sedimentation filter 61 pass through the filter. A first filter to remove various heavy metals and carcinogens contained in the raw water when the raw water supplied through the pretreatment filter 62 and the pressurized pump 70 from the pretreatment filter 62 to the pressurized pump 70 passes. Contained in the raw water when the first and second membrane filters 63 and 64 installed through the fixing bracket 50 and the raw water simultaneously supplied from the first and second membrane filters 63 and 64 pass. First filter fixing bracket 50 to remove the smell and toxic gas components Second filter fixing bracket to sterilize harmful bacteria contained in the raw water when the raw water supplied from the after-treatment filter 65 and the raw water supplied from the post-treatment filter 65 passes, and is supplied to the purified water storage container 30 ( 51) is composed of a sterilizing filter 66 installed through the medium.

At this time, the precipitation filter 61, the pretreatment filter 62, the first and second membrane filters 63 and 64, the after-treatment filter 65, the sterilization filter 66 and the pressure pump 70 are the raw water They are interconnected by connecting hoses 67 for guiding the flow.

In addition, a concentrated water pipe 68 is connected to one lower side of the first and second membrane filters 63 and 64 to discharge the concentrated water generated while passing through the inside thereof.

On the other hand, the third partition member in the space (G) to receive and store the purified water stored in the purified water storage tank 30 in a predetermined capacity through the first and second purified water pipes (31, 32), respectively ( The hot water tank 80 and the cold water tank 90 are provided on the upper surface of 22).

Here, a sterilization lamp 130 is disposed in the vertical direction in the cold water container 90 to sterilize the storage water by ultraviolet light and to suppress bacterial contamination of the purified water that has been left for a long time.

At this time, as shown in FIG. 3, the first water purification pipe 31 is connected to one side of the bottom surface of the water storage container 30 and the bottom thereof is connected to the bottom surface of the hot water tank 80. The upper end of the second water purification pipe 32 is connected to the other side of the bottom surface of the purified water storage container 30, and the lower end thereof is connected to the upper surface of the cold water container 90.

In addition, the hot water tank 80 has a heater member 81 for heating the purified water stored therein while being heated to receive power, the outer peripheral side of the cold water tank 90 receives the liquid refrigerant in the cold water tank 90 Cooling coil 91 is wound in a spiral to heat-exchange the purified water in the spiral, and hot and cold water tanks 80, 90 to discharge the hot and cold water in the hot water and cold water tanks 80, 90, respectively. The hot water and cold water mounting valves 100 and 101 which are connected to the water discharge pipes 82 and 92 respectively installed at the top of the bottom) and protrude outwards through the front panel 11 are installed.

On the other hand, the cold water container (90) is coupled to the heat exchanger 110 to cool the heat exchanger inside the cold water tank 90, the lower panel 15, the lower panel 15 that is the lower portion of the heat exchanger (110). The blowing unit 120 is formed of a motor 121 that is driven by receiving power and a fan 122 that is rotated by receiving a driving force of the motor 471.

Here, the conventional coupling structure of the heat exchanger 110, as shown in Figure 5, the cold sink 111 exposed through the bottom of the cold water so as to contact the purified water stored in the cold water tank (111; Cold Sink) And, the thermoelectric element 112 is disposed so as to be in close contact with the lower surface of the cold sink 111 as well as the grease (Grease) is applied to both end surfaces in order to increase the heat transfer efficiency, and the lower surface of the thermoelectric element 112 The heat sink 115 (Heat Sink) is fixed to the appropriate amount of pressure through the interval adjusting member 114 equipped with a plurality of fastening screws 113 and the cushion on the lower surface of the cold water container 90 to be in close contact with consist of.

At this time, the upper side of the cold sink 111 and the lower side of the heat sink 115 are formed with a plurality of cutout grooves (111a) (115a) in the horizontal direction to increase the heat transfer area, respectively.

That is, a plurality of fastening holes (not shown) are formed in communication with each other so that the fastening screw 113 can be inserted into the cold water container 90 and the cold sink 111, respectively, and the heat sink 115 A plurality of through holes (not shown) are formed in the cutout groove 115a of the cut hole 115a to control the thermoelectric element 112 and the gap between the cold sink 111 and the heat sink 115. After arranging the member 114 and tightening the end of the fastening screw 113 by placing it in the through hole of the heat sink 115, the fastening screw 113 is a cold water container 90 and a cold sink ( The heat sink 115 is coupled by being fixed through the fastening hole of the 111.

However, according to the coupling structure of the conventional heat exchanger, since the gap adjusting member 114 provided with the cushion is disposed between the cold water tank 90 and the heat sink 115, the same pressure is applied to each of the fastening screws 113. If this action is not applied, the distance h between the bottom surface of the cold water container 90 and the top surface of the heat sink 115 is not always assembled uniformly, and the fastening screw 113 is not an appropriate pressure but an excessive pressure. When tightened to the thermoelectric element 112, the intrinsic properties (unique characteristics) of the change, as well as the thermal element 112 is severely damaged there is a problem that the heat transfer is not made.

Therefore, the present invention has been made to solve the above problems, the cold water tank and the cold sink made of a single unit is separated into the first and second cold water tank and the first and second cold sink is coupled through the fastening means, of course, The heat elements located between the second cold sink and the heat sink are assembled by the appropriate pressure of the fastening screws by the screw holes formed in the second cold water container and the fastening grooves formed in the second cold sink. Even if the same pressure is not applied, the distance between the bottom surface of the cold water tank and the top surface of the heat sink is always assembled by the gap adjusting member, thereby preventing the change and damage of the intrinsic properties of the thermoelectric element. It is an object of the present invention to provide a heat exchanger for a water distributor.

The present invention for achieving the above object, the cold water container and the cold sink made of a single unit is separated into the first and second cold water container and the first and second cold sink is coupled via a fastening screw as well as the first cold sink Fastening grooves are formed in the left and right sides of the lower surface, respectively, and screw holes are formed in the left and right predetermined portions of the second cold sink, and a plurality of fastening grooves are formed between the screw holes, and the lower surface of the second cold water container. First screw holes are formed in the left and right sides, and a plurality of second screw holes are formed between the first screw holes.

In addition, a thermoelectric element is disposed on a lower surface of the second cold sink, and a heat sink in which a plurality of through holes is formed is disposed on a lower surface of the thermoelectric element, and the heat sink has a plurality of fastening screws. It is a structure combined with a cold sink.

1 is a perspective view showing a conventional water distributor,

2 is a cross-sectional view showing a conventional water distributor side;

Figure 3 is a cross-sectional view showing a conventional water distributor,

Figure 4 is a flow chart showing the arrangement of the conventional filtering means and the pressure pump,

5 is a schematic cross-sectional view showing a state in which a heat exchanger is coupled as a conventional structure;

6 is a perspective view showing a water distributor of the present invention;

7 is a perspective view showing the inside of the water distributor of the present invention,

8 is an exploded perspective view showing the interior of the water distributor of the present invention;

9 is a schematic cross-sectional view showing a state in which a heat exchanger is coupled according to the present invention.

Explanation of symbols on the main parts of the drawings

450-Cold Water Bottles490-Heat Exchangers

491-Cold Sinks 492-Thermoelectric Devices

493a-1st tightening screw 493b-2nd tightening screw

495-Heat Sink 495a-Through Hole

495b, 891b-Notch Groove650-First Cold Water Bottle

750-Second Cold Water Bottle 751-First Passing Hole

752-2nd through hole 891-1st cold sink

891a, 991b-Fastening Groove 991-Second Cold Sink

991a-Hollow Hole

H-gap between the bottom surface of the second cold water tank and the top surface of the heat sink

L-tightening distance of 2nd tightening screw

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings, FIGS. 6 to 9.

As shown in FIGS. 6 to 8, the water distributor of the present invention guides the introduction of external air into a predetermined position in the interior of the main body 200 at the same time, and at the same time, a plurality of parts may be mounted on the upper surface thereof. The lower panel 210 is installed so that the front panel 220, the rear panel 230, the first and second side panels 240, 250, and the upper panel on both sides of the lower panel 210. The first and second support frames 260 and 270 are vertically installed at the same predetermined height so that the 190 is installed by a plurality of locking methods and fastening methods, respectively. Intermediate panel 280 by the fastening method so as to form the upper and lower spaces (K) (L) of a predetermined area on the upper and lower sides of the main body 200 at an intermediate height with respect to the support frame 270, respectively. It is installed.

That is, in the lower panel 210, the bell mouse 211 is bent vertically to a certain height upward so as to guide the flow of air to one place when the outside air flows into the inside of the main body 200 at the bottom center thereof. Is formed, the inner peripheral surface of the bell mouse 211 is seated and screwed in the air blowing means to be described later, the bottom edge of the sterilizing filter, pressure pump, drainage switching means, transformers, etc. to be described later is a constant that does not leak and immersion Seated to the height and joined.

The front panel 220 is formed with a convex surface 221 integrally formed so that the control pad 290 and the main PCB 300 is coupled to the upper side, the center of the lower side in close contact with the pressing force to the container, etc. When the intake port described later is turned on electronically, the passage is opened and water (for example, cold water, hot water, and purified water) is taken in or the pressure is released. When the intake port is turned off, the passage is closed to stop the intake of water. Push button 310 is installed so as to be resilient, and the bottom of the water collecting container 320 is detachably installed so as to drain the water flowing down through the intake port to be described later and immediately drain to the outside.

At this time, the front side of the convex surface 221 is a through-hole of a predetermined area on the upper and lower sides respectively so that the light emitted from the main PCB 300 is limited to a predetermined portion of the control pad 290 is emitted to the outside 222 is formed, and the plurality of snap holes 223 and screw holes 224 are formed in the left and right sides of the through holes 222 so that the control pad 290 is coupled by a locking method and a fastening method, respectively. In the center of the lower surface of the convex surface 221, a through hole (not shown) is formed so that the lower end of the intake hose to be described later penetrates to the outside.

The control pad 290 is integrally injection-molded with the display cover portion 291 and the button cover portion 292 to cover the front side of the display unit 301 and the button unit 302 of the main PCB 300 have.

In this case, the light emitted from the display unit 301 and the button unit 292 on the back surface of the display cover unit 291 and the button cover unit 292 is a transparent portion 293 which is a limited part of the control pad 290. A dark colored object (not shown) is coated to prevent light from being emitted by the opaque portion 294, which is emitted from the outside, as well as the remaining portion, and the button cover portion 292 has the button portion ( A portion of the 302 protrudes to the outside so that a plurality of button protrusion grooves 295 are formed through a predetermined interval so that the consumer can press.

On the other hand, in the upper space (K) is purified water storage tank 330 that can store a constant amount of water in the center thereof is seated on the upper surface of the intermediate panel 280 is coupled by a screw method, the one side is supplied Filtration means 350 to filter and filter various foreign substances contained in raw water is installed to replace the filter fixing bracket 340 is fastened and assembled to the second support frame 270 and the intermediate panel 280. On the other side, the hot water is supplied with the purified water stored in the purified water storage container 330 and stored in a predetermined capacity, and at the same time heat-exchanged purified water by hot heat of a heater (not shown) accommodated therein to a hot temperature. The cylinder 360 is seated on the upper surface of the intermediate panel 280 is screwed.

At this time, the purified water storage container 330 is composed of a body 331 of a predetermined area with an upper opening, and a lid 332 covering the upper opening of the body 331.

That is, in the body 331, the purified water filtered by the filtering means 350 at the upper end of the side is introduced into the body 331 through the first connection hose 370 or a predetermined inside of the body 331. The through hole 333 is formed so that the water over the water level is drained through the second connection hose 371, and the water purification inside the body 331 is described below through the third connection hose 372 at the front lower end thereof. A first outlet 334 is formed to flow out through the intake to the outside, the lower end of the rear so that the purified water inside the body 331 is introduced into the hot water tank 360 through the fourth connection hose 373. A second outlet 335 is formed, and a third outlet 336 is formed in the center of the bottom surface of the second outlet 335 so that the purified water inside the body 331 flows into the cold water tank described later.

The lid 332 is provided at one side thereof with a water level detecting means 380 in a vertical direction to detect the water level state of the purified water stored in the body 331 in a multi-step, the other side by the ultraviolet light The sterilization lamp 390 is installed in the vertical direction to suppress the secondary bacterial contamination of the purified water that has been left for a long time and at the same time as the second sterilization treatment of the purified water stored in the reservoir 330 and the cold water tank 450, the sterilization lamp 390 is installed to be inserted into the cold water tank 450 to be described later through the purified water storage tank 330.

The filter fixing bracket 340 is bent in a L-shape when viewed from the front, as well as the upper end is screwed to the front and rear surface of the upper end of the second support frame 270, the lower end of the intermediate panel 280 It is screwed on one side of).

The filtering means 350 is installed to be replaced on the bottom of the upper surface of the filter fixing bracket 340 so as to remove suspended substances such as green debris contained in the raw water when the raw water supplied from the tap water (not shown) is passed. Precipitation filter 351 and a pretreatment filter 352 that are replaceably installed on the bottom surface of the filter fixing bracket 340 so as to remove foreign substances such as chlorine components contained in the raw water when the raw water supplied from the precipitation filter 351 passes. And a filter fixing bracket to remove various heavy metals and carcinogens contained in the raw water when the raw water is passed from the pretreatment filter 352 to the pressure pump 400 installed on one side of the upper surface of the lower panel 210. Reverse osmosis filter (353) installed on the bottom surface of the top plate 340 and the filter to remove the odor and toxic gas components contained in the raw water when the raw water supplied from the reverse osmosis filter (353) is passed through The post-treatment filter 354 installed to be replaced on the bottom of the upper bracket 340 and sterilize harmful bacteria contained in the raw water when the raw water supplied from the post-treatment filter 354 passes through the water purification reservoir 330. It is composed of a sterilization filter 355 installed on one side of the upper surface of the lower panel 210 to be supplied.

At this time, the precipitation filter 351, the pretreatment filter 352, the reverse osmosis filter 353, the post-treatment filter 354, the sterilization filter 355 and the pressure pump 400 is a fifth connection for guiding the flow of raw water They are interconnected by hoses 374.

In addition, a concentrated water pipe 410 is connected to one lower side of the reverse osmosis filter 353 so that the concentrated water generated while passing therein is discharged to the outside.

On the other hand, the upper side of the lower space (L) is supplied with the purified water stored in the purified water storage container 330 and stored at a predetermined capacity and at the same time to heat the purified water to a cold temperature by a heat exchanger to be described later of the intermediate panel 280 Cold water tank 450 in the center of the lower surface is tightly attached to be suspended to a predetermined height, the lower side through the lower panel 210 through the sterilization filter 355, the pressure pump 400, drain switching means 460 , The blowing means 470 and the transformer 480 are respectively provided at predetermined positions.

At this time, the cold water tank 450 is coupled to the heat exchange means 490 for cold heat exchange of the purified water inside the cold water tank at the lower side, the switching mode power unit 500 (Switching Mode Power) is installed on the outer side wall In addition, a concentrated water quantity control valve 510 is installed at an outer sidewall edge thereof, and a temperature sensing rod 520 is installed at an upper side thereof so as to be accommodated inside a cold water tank so as to sense the temperature of the upper and lower water levels of the cold water.

The drain switching means 460 is a valve body 461 and the front and rear end is seated on the upper end of the two seating ribs 212 protruding upward on one side of the upper surface of the lower panel 210, and the valve body 461 Pressing the center of the valve body 461 in the lower direction through the top of the both ends of the fixing bracket 462 is screwed to the upper surface of the lower panel 210.

The blowing means 470 is a motor 471 driven by receiving power, a fan 472 rotated by receiving the driving force of the motor 471, and a bell mouse 211 formed in the lower panel 210. It is composed of a bracket (473) to be seated on the inner peripheral surface of the) to support the motor 471.

The heat exchange means 490 is in close contact with the cold sink 491 (Cold Sink) exposed to the outside through the bottom so as to contact the purified water stored in the cold water tank 450, and close to the lower surface of the cold sink 491 A plurality of fastening screws 493 and a sleeve 494 to the lower surface of the cold water container 450 to closely contact the thermoelectric element 492 and the lower surface of the thermoelectric element 492. It consists of a heat sink 495 fixed at an appropriate amount of pressure.

Here, when the heat exchanger 490 is described in more detail, as shown in FIG. 9, the predetermined portions of the cold water tank 450 and the cold sink 491 formed as one unit are the first and second cold water tanks 650. A lower surface of the first cold sink 891 is coupled to the first fastening screw 493a by being cut along the horizontal axis to be divided into 750 and the first and second cold sinks 891 and 991. Fastening grooves 891a equipped with screw portions having predetermined lengths are formed in the left and right sides, and hollow holes 991a communicating with the respective fastening grooves 891a are formed in the left and right predetermined portions of the second cold sink 991. A plurality of fastening grooves 991b with screw portions are formed between the hollow holes 991a, and the hollow holes 991a and the left and right sides of the lower surface of the second cold water tank 750 are formed. First through holes 751 are formed to communicate with each other, and between the first through holes 751. The second through hole 752 is formed to communicate with each of the fastening grooves 991b.

In addition, a thermoelectric element 492 is disposed on a lower surface of the second cold sink 991 penetrating the bottom surface of the second cold water container 750, and each of the first and second elements is disposed on the lower surface of the thermoelectric element 492. The heat sink 495 in which the plurality of through holes 495a are formed to communicate with the two hollow holes 752 is disposed.

In addition, the heat sink 495 is coupled to the second cold sink 991 at an appropriate amount of pressure by a plurality of second fastening screws 493b.

In this case, a plurality of cutout grooves 491b and 495b are formed in an upper side of the first cold sink 891 and a lower side of the heat sink 495 in the horizontal direction to increase the heat transfer area.

Accordingly, the second cold sink 991 is disposed on the inner bottom surface of the second cold water container 750, and the thermoelectric element 492 is disposed on the bottom surface of the second cold sink 491. When the heat sink 495 is disposed on the lower surface of the 492, and the end of the second fastening screw 493b is inserted into the through hole 495a and tightened, the second fastening screw 493b is Through the through hole 495a and the second hollow hole 752, the heat sink 495 and the second cold sink 991 are firmly fastened to the fastening groove 991b of the second cold sink 991. To be combined.

As described above, the thermoelectric element 492, the heat sink 495, and the second cold sink 991 of which the primary assembly is completed are disposed on the lower surfaces of the first cold water container 650 and the first cold sink 891. After positioning, when the end of the first fastening screw 493a is inserted into the first through hole 751 and tightened, the first fastening screw 493a is provided with the first through hole 751 and the hollow hole. The second cold water container 750 and the second cold sink 991 are firmly coupled to the first cold sink 891 by being fastened to the fastening groove 891b of the zecold sink 891 by passing through 991a. Thus, the assembly of the entire heat exchanger 490 is completed.

Here, the assembly of the thermoelectric element 492, the heat sink 495, and the second cold sink 991 coupled through the second fastening screw 493b is a fastening formed on the second cold sink 991. Since the fastening distance L of the second fastening screw 493b is preset by the groove 991b, even if the same pressure is not applied to each of the second fastening screws 493b, the second cold water tank 750 The gap H between the bottom surface of the bottom surface and the top surface of the heat sink 495 is always assembled to prevent deformation and breakage of the thermoelectric element 492 when the heat exchanger 490 is coupled.

In addition, the thermoelectric element 492, the heat sink 495, and the second cold sink 991, which are coupled through the second fastening screw 493b, are assembled at an appropriate pressure by a professional company in charge of assembly only. Because of this, the division of work is made more divided and productivity is increased.

On the other hand, the front of the intermediate panel 280, the first to third electronics for controlling the water flowing out from the purified water reservoir 330, the hot water tank 360, the cold water tank 450 in accordance with the electronic signal, respectively The valve fixing brackets 281 are integrally bent and formed to be perpendicular to the vertical direction so that the valves 530, 531, and 532 are fixed, and the first to third solenoid valves 530, 531, 532 At one end, the water flowing out through the outlet (not shown) of the second outlet 334 and the hot water and cold water tanks 360 and 450 of the purified water storage container 330 is first to third solenoid valves 530. Water discharge hoses 540, 541 and 542 are connected to each other so as to pass through 531 and 532, and the other ends of the first to third solenoid valves 530, 531 and 532 are respectively Water intake hose 550 to discharge the water flowing into the first to third solenoid valves 530, 531, 532 from the purified water reservoir 330, the hot water tank 360, and the cold water tank 450. Is connected.

Next, the operation and effect of the present invention configured as described above will be described.

First, after connecting the product to the water tap (not shown), when the water tap is turned on, the plurality of filtering means 350 by the constant water pressure and the pressure of the operation of the pressure pump 400 is applied to the raw water tap water It is purified by flowing through.

That is, when raw water passes through the settling filter 351 from the tap water, suspended substances such as green residues contained in the raw water are removed, and when passing through the pretreatment filter 352 after passing through the settling filter 351. Foreign substances such as chlorine components contained in the raw water are removed, and various heavy metals and carcinogens contained in the raw water are removed when passing through the reverse osmosis filter 353 after passing through the pretreatment filter 352.

Then, after passing through the reverse osmosis filter 353 and passing through the post-treatment filter 354, the odor and toxic gas components contained in the raw water are removed. After passing through the post-treatment filter 354, the sterilization filter 355 is removed. As the harmful bacteria contained in the raw water pass through the first sterilization process through the first connection hose 370 connected to the upper height of the purified water storage container 330, the raw bacteria are supplied into the purified water storage container 330 as shown in FIG. 8. do.

In addition, some of the purified water supplied into the purified water storage tank 330 through the fourth connection hose 373 connecting the rear side of the purified water storage tank 330 and the rear side of the hot water tank 360 to the water tank up to a predetermined capacity which becomes the full water level ( 360 is supplied to, and some of the purified water continues to be supplied to a certain level of water level through the upper side of the cold water tank 450 interconnected with the third outlet 336 formed on the bottom of the purified water storage tank 330, these purified water Raw water supply is blocked according to the multi-stage detection signal of the water level detection means 380 mounted on one side of the lid 331 of the water storage container 330 when the storage container 330 and the hot and cold water containers 360 and 450 become full water levels. At the same time the operation of the pressure pump 400 is stopped.

At this time, when the water level inside the purified water storage tank 330, the hot water and cold water tanks 360, 450 is lowered, the multi-level water level detection of the water level detecting means 380 is made and the control pad 290 of the front panel 220 Displayed on the display unit 301 of the main PCB 300 through the transparent portion 293 formed therein, thereby the consumer to check the consumption of water stored in the purified water storage tank 330, hot water and cold water tanks 360, 450 It becomes possible.

On the other hand, the sterilization lamp 390 installed on the lid 332 of the purified water storage container 330 has a predetermined height into the inside of the cold water tank 450 through the third outlet 336 formed at the bottom of the purified water storage container 330. Installed vertically until the second time sterilization of the bacteria contained in the purified water stored in the purified water storage tank 330 and the cold water tank 450 at the same time.

That is, the ultraviolet light emitted from the germicidal lamp 390 is irradiated to the purified water filled with a predetermined capacity in the purified water storage tank 330 and the cold water tank 450 so that the purified water stored in the purified water storage tank 330 is not discharged to the outside for a long time. It effectively prevents the growth of microorganisms that can occur when left untreated, thereby preventing secondary bacterial contamination.

On the other hand, when a heater member (not shown) installed in the hot water tank 360 for hot water supply is operated, the heater member is heated to a set temperature according to the applied current supply to heat the purified water stored in the hot water tank 360. Heat exchange.

Then, when the blower means 470 and the thermoelectric element 492 of the heat exchanger 490 are operated to supply the cold water, the motor 471 of the blower means 470 is driven by receiving power to operate the fan 472. The outside air is introduced into the main body 200 through the passage of the bell mouse 211 formed at the center of the lower panel 210 by the blowing force by the rotation of the fan 472. The heat sink 495 of the means 490 is hit directly.

At this time, the heat sink 495 is cooled by the blowing wind and cools to discharge heat conducted to the cold sink 491 accommodated in the cold water tank 450 according to the electronic characteristics of the thermoelectric element 492 to the outside. By repeating the cycle, the purified water stored in the cold water tank 450 is coldly heat exchanged to a low temperature.

On the other hand, when the user wants to receive the hot water and cold water stored in the purified water storage container 330, hot water and cold water containers 360, 450 in a container (not shown), such as a cup, first, the control pad 290 of the front panel 220 At the same time, press the power button (not shown) projecting on the bottom and press the water purification button (not shown), and then position the lower portion of the front panel 220 while placing it on the intake hose 550 of a container such as a cup. Push toward the push button 310 protruding in the center.

At this time, when the push button 310 inputs data to the microcomputer (not shown) on the signal connected to the movable contact (not shown) and the fixed contact in the push button 310 by the movement to the rear side, the micom The first solenoid valve 530 is turned on according to a programmed input to open the intake passage by determining the data, and the purified water stored in the purified water storage vessel 330 is opened by the opening of the intake passage. ) Flows along the water discharge hose 540 connecting the first solenoid valve 530 and along the water intake hose 550 connected to the first solenoid valve 530 and is discharged into the container such as the cup described above. Withdrawal is possible.

Then, the water collected in the drip tray 320 during the intake is drained to the outside of the product along the drainage pipe (not shown) connecting between the drip tray 320 and the drain switching means 460.

As described above, according to the water distributor according to the present invention, the assembling distance of the fastening screw at the time of assembling the thermoelectric element, the heat sink, and the second cold sink is preset by the fastening groove formed in the second cold sink. Even if the same pressure is not applied to the fastening screw, the distance between the bottom surface of the second cold water container and the upper surface of the heat sink is always constantly assembled, which prevents deformation and breakage of the thermoelectric element, and also mediates the fastening screw. The assembly of the thermoelectric element, the heat sink, and the second cold sink, which are coupled to each other, has an effect of increasing the productivity.

Claims (3)

Cold sinks to be disposed on the inner bottom to contact the purified water stored in the cold water tank, thermoelectric elements to be disposed on the lower surface of the cold sink, heat sinks to be coupled to the cold water tank as well as to be disposed on the lower surface of the thermoelectric elements. In the heat exchanger of the water distributor, A predetermined portion of the cold water container and the cold sink is cut out in the horizontal axis direction to be disposed in the first cold water container, the second cold water container to be disposed in the first cold water container, and the second cold water container to be in contact with the stored purified water. The first cold sink, the second cold sink which is in close contact with the first cold sink as well as to be disposed inside the second cold water container, and the second cold water container, the second cold sink and the first cold sink at the same time The heat exchanger of the water distributor comprising a first fastening screw to be coupled to, and a second fastening screw to be coupled to the heat sink, the second cold water tank and the second cold sink at the same time. According to claim 1, wherein the left and right sides of the lower surface of the first cold sink is formed with a fastening groove having a thread of a predetermined length, the hollow hole is formed in the left and right predetermined portions of the second cold sink to communicate with the fastening groove. In addition, a fastening groove with a screw portion is formed between the hollow holes, and a first through hole formed to communicate with the hollow hole is formed at left and right sides of the lower surface of the second cold water container, and between the first through holes. Heat exchanger of the water distributor, characterized in that the second passage hole is formed to communicate with the fastening groove. The method of claim 1, wherein the coupling distance of the second fastening screw by the fastening groove formed in the second cold sink to prevent the deformation and damage of the thermoelectric device when the thermoelectric element, the heat sink and the second cold sink is coupled Heat exchanger of the water distributor, characterized in that predetermined.