KR101144303B1 - Water gathering system in the kitchen sink - Google Patents

Abstract

The sink-mounted intake system according to the present invention includes a supply pipe having a flow path in which water flows in one direction, and a control pipe disposed along the length direction of the supply pipe as described above, and turning at least one or more times to form a coil shape as a whole, and the above-mentioned It is connected between both ends of a control tube and controls the water temperature in the above-mentioned supply pipe by energy supplied from the outside, and is installed between the filter unit and the water direct pipe connected to the above-described supply pipe, It includes a valve unit for controlling the discharge of water through, the outside of the above-described double pipe is insulated, the above-described intake is exposed on the sink, the above-mentioned double pipe and the control unit and the valve unit described above It is built into the sink.

Description

WATER GATHERING SYSTEM IN THE KITCHEN SINK}

The present invention relates to a sink-mounted intake system, and more particularly, to minimize the unnecessary energy consumption for heating and cooling water, and to maintain the clean state of the intake water, as well as to maximize the utilization of space. It's about the system.

Cold and hot water heaters are usually arranged in the living room or kitchen when used in the home, in particular, in the kitchen will be suitable around the sink with a lot of water.

However, due to various kinds of furniture such as kitchen appliances and dining tables, such as gas stoves, it is difficult to secure enough space for the arrangement of the sink. Therefore, problems such as temporary arrangement on the panel near the sink faucet are used. There is this.

On the other hand, since most cold and hot water heaters are simply configured to be heated by cooling or cooling water, it is difficult to maintain a clean state due to debris in the water and water supplied from the water supply pipe in the water tank for a long time of use. have.

In addition, since a typical cold and hot water heater is heated or cooled in a state in which water is accommodated in the tank, it is difficult to take water at a desired temperature even if you want to take cold water or hot water at a time, and the energy consumption is also severe. Many products have limited performance.

The present invention devised to improve the above problems is to provide a sink-mounted intake system that can make the most of the limited space.

In addition, the present invention is to provide a sink built-in water intake system capable of efficient water management while being able to immediately withdraw water of the desired temperature.

In addition, the present invention is to provide a sink-mounted intake system to maintain the clean state of the water to be withdrawn to prevent any problems that may occur hygiene in advance.

In addition, the present invention is to provide a sink built-in water intake system that can maintain a continuous heat insulating performance with a relatively simple structure and easy post-management.

The sink-mounted intake system according to the present invention includes a supply pipe having a flow path in which water flows in one direction, and a control pipe disposed along the length direction of the supply pipe as described above, and turning at least one or more times to form a coil shape as a whole, and the above-mentioned It is connected between both ends of a control tube and controls the water temperature in the above-mentioned supply pipe by energy supplied from the outside, and is installed between the filter unit and the water direct pipe connected to the above-described supply pipe, It includes a valve unit for controlling the discharge of water through, the outside of the above-described double pipe is insulated, the above-described intake is exposed on the sink, the above-mentioned double pipe and the control unit and the valve unit described above The structure built in the sink can be applied.

As described above, the sink-mounted water intake system according to the present invention has the following advantages.

First, it is possible to maximize space utilization by allowing components such as a double pipe, a vacuum insulated tank, a control unit, and a valve unit to be embedded in the sink and removed from the limited installation space around the sink.

In addition, the present invention adopts a configuration in which the control tube and the supply pipe are integrally formed in a coil shape, such as a coil, so that the water of the desired temperature can be immediately taken as a mechanism for heating or cooling the water in the supply pipe through the control pipe. In addition, the control tube and the supply tube close to each other along the formation direction, efficient energy management is possible.

In addition, the present invention can be equipped with a sterilizing lamp in the inlet or outlet of the supply pipe in the double pipe to prevent any problems that may occur in hygiene by maintaining the clean state of the water discharged through the inlet.

In addition, the present invention can maintain a continuous heat insulating performance according to the structure of lowering the thermal conductivity by maintaining a continuous vacuum state by discharging the residual air from the space portion with the body portion consisting of the inner and outer cylinders formed space portion to maintain a vacuum state Of course, the post-management is easy due to the structure of the removable vacuum holding unit.

1 is a cross-sectional conceptual view showing the overall structure of the sink-mounted intake system according to an embodiment of the present invention
FIG. 2 is a plane conceptual view seen from a point A of FIG. 1.
3 is a conceptual view showing another embodiment of the valve unit which is the main part in the sink-mounted intake system according to an embodiment of the present invention;
Figure 4 is a cross-sectional conceptual view showing the overall structure of the sink-mounted intake system according to another embodiment of the present invention
5 is a plane conceptual view seen from a point B of FIG.
6 is a cross-sectional conceptual view showing the overall structure of the sink-mounted intake system according to another embodiment of the present invention.
FIG. 7 is an enlarged cross-sectional conceptual view illustrating a structure of a vacuum insulation tank that is a main part of a sink-mounted intake system according to another embodiment of the present invention in FIG. 6.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

This is for the purpose of describing the present invention in detail so that those skilled in the art can easily practice the present invention, and thus, the technical spirit and scope of the present invention are not limited thereto.

In addition, the sizes and shapes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation, and the terms defined specifically in consideration of the configuration and operation of the present invention may vary depending on the intention or custom of the user, operator And the definitions of these terms should be based on the contents throughout this specification.

1 is a cross-sectional conceptual view showing the overall structure of the sink-mounted water intake system according to an embodiment of the present invention, Figure 2 is a plan view as viewed from the point A of FIG.

As shown in the present invention, it can be seen that the structure includes a double pipe 100, a control unit 300, and a valve unit 400.

The double pipe 100 has a supply pipe 110 having a flow path in which water flows in one direction, and a control pipe 120 disposed along a length direction of the supply pipe 110, and is pivoted at least once to form a coil shape as a whole. As a structure, it can be said that it is a structure for removing the structure of the water tank in which water is accommodated, and immediately taking in a suitable amount of water from the water supply pipe 700 to a desired temperature.

The control unit 300 is connected to both ends of the control tube 120, and includes a series of components for regulating, that is, heating or cooling the water temperature in the supply pipe 110 by energy supplied from the outside.

The valve unit 400 is mounted between the filter unit 600 and the water direct pipe 700 connected to the supply pipe 110 and controls the discharge of water through the intake port 800 through the supply pipe 110. The control method may be manual or automatic.

Here, the outside of the double pipe 100 is insulated by the protection unit (S) including the heat insulating material, the intake port 800 is exposed on the sink 900, the double pipe 100 and the control unit 300 and the valve It can be seen that the unit 400 has a structure built in the sink 900.

Reference numeral 910 (which is the same also in the drawings below) denotes a washing tub provided in the sink 900.

The present invention is applicable by the embodiment as described above, will be described in more detail for the main part of the present invention for a more detailed description.

The supply pipe 110 and the control pipe 120 are integrally cast or extruded as shown in FIGS. 1 and 2, and are formed in a coil shape by turning at least once or more, and the control pipe 120 has a coil shape. Inside the supply pipe 110 is disposed on the outer side of the coil shape, respectively, as described above is provided with a protective portion (S) for protecting the outer surface of the double pipe (100).

Inner and outer surfaces of the protection unit (S) is preferably anodized, anticorrosive coating or anticorrosive resin coating.

When the anticorrosive coating or the anticorrosive resin is applied to the object to be coated, a material such as epoxy or Teflon having excellent heat resistance and impact resistance may be coated on the inner and outer surfaces of the protective part S.

The anodizing treatment protects the inside of the aforementioned metals by making a thin oxide film on the surface of the above-described metals, which are highly reactive with oxygen such as aluminum, titanium, magnesium, and the like, to form an oxide film on their own surface.

The anodizing treatment described above artificially produces an oxide film having a uniform thickness by promoting the oxidation of the surface of the aforementioned metals while allowing the aforementioned metals to function as an anode in a specific solution such as sulfuric acid.

Like the metals described above, metals having a high degree of reaction with oxygen form an oxide film by themselves to protect themselves, but due to its high reactivity, impurities such as iron, silicon, or copper are inevitably included.

When the content of the above-mentioned impurities is high, the metals such as Al ₃ Fe, Al ₆ Fe, Al ₅ FeSi, Al ₂ Cu, etc., are formed between the above-mentioned impurities and the above-described metals (hereinafter, aluminum) during the manufacture of the product using the above-described metals. Compounds (Intermetallics, hereinafter referred to as IMC) are generated, and the aforementioned IMC, unlike aluminum, cannot generate an oxide film by itself.

Here, if the aluminum or aluminum alloy having a high impurity content is left in the air and used as it is, a fatal problem may occur such that the above-mentioned IMC is formed with holes or corroded and stress is concentrated.

Therefore, the above-described anodizing applies the principle that the above-mentioned IMC can also form an oxide film when an IMC that cannot form an oxide film in air is added to a specific solution such as sulfuric acid.

On the other hand, the supply pipe 110 is further provided with a pair of mounting ribs 112 protruding to the outer peripheral surface along the longitudinal direction of the supply pipe 110 on the outer side of the coil shape, seating grooves 112 ′ between the mounting ribs 112. ) Is formed, the temperature sensor (not shown) is fitted to the above-mentioned seating groove 112 'is able to detect the water temperature in the supply pipe (110).

At this time, both ends of the supply pipe 110 may be an inlet or outlet, respectively, more specifically, based on Figure 1, one end of the upper left is the inlet and the other end of the lower right is the outlet, or the other end of the lower right It can be an inlet and one end of the upper left can be an outlet.

The inlet and outlet are connected to the water supply pipe 110 and the intake cock, respectively, so as to be connected to the supply pipe 110 and the water supply pipe 110 and the water intake port 800 as shown in FIG. In order to give a sterilization function to the water in the supply pipe 110, the outer surface and the inner circumferential surface of the) is preferably coated with silver nano or photocatalyst.

And, the connector (C) is equipped with a germicidal lamp (L) for irradiating ultraviolet rays into the supply pipe 110 may further increase the sterilization effect.

In addition, the inner circumferential surface of the supply pipe 110 may be treated with silver nano or photocatalyst coating treatment of the connector C to form a silicon film that is harmless to the human body, or may be inserted into a stainless steel tube to maintain a clean state.

On the other hand, the control unit 300 is provided to adjust the water temperature in the double pipe 100 to the desired temperature as described above, in Figure 1 may be applied to a structure for forming a cooling cycle.

That is, the control unit 300 is connected to one end of the control tube 120, the capillary tube 301 through which the refrigerant flows, the condenser 302 connected to the capillary tube 301, the refrigerant condensation, and the condenser 302 and A structure including a compressor 303 connected to compress the refrigerant may be applied.

Here, one side of the control tube 120 is connected to the capillary tube 301, the other side of the control tube 120 is connected to the compressor 302, respectively, and the condenser 303 is mounted between the capillary tube 301 and the compressor 302. The refrigerant forms a cooling cycle of one-way circulation in which the refrigerant returns to the compressor 303 through the refrigerant return pipe 304 from one side to the other side of the control pipe 120.

At this time, it is preferable that the dryer 305 is mounted between the condenser 303 and the capillary tube 301.

That is, the compressor 302 adiabaticly compresses the refrigerant to convert it into saturated steam of high temperature and high pressure, and the condenser 303 dissipates the refrigerant discharged from the compressor 302 to convert the saturated liquid of low temperature and high pressure into a dryer 305. Removes foreign substances contained in the refrigerant in a saturated liquid state at low temperature and high pressure.

Subsequently, the refrigerant from which the foreign matter is removed is throttled and expanded in the capillary tube 301 to become a low temperature low pressure wet saturation vapor, and vaporizes in the control tube 120 which is an evaporator to absorb latent heat of external air to cool the surrounding air.

 Thereafter, although the refrigerant discharged from the control tube 120 is not particularly shown, the accumulator is separated into a liquid refrigerant and a gaseous refrigerant, and only one gaseous refrigerant is returned to the compressor 302, thereby completing one revolution of the cooling cycle. The cycle is repeated.

On the other hand, the valve unit 400 is provided to manage the water supplied from the water supply pipe 700 and the water discharged from the inlet 800 as described above, as shown in Figure 1 pressure reducing valve 410 and the solenoid valve 420.

The pressure reducing valve 410 is mounted between the water supply pipe 700 and the filter unit 600 and is connected to the double pipe 100 and various pipes due to the water supplied directly from the water supply pipe 700 having a strong water pressure. It is a means to prevent rupture or leakage due to pressure imbalance and to supply the dropped water at an appropriate pressure.

The solenoid valve 420 is mounted between the pressure reducing valve 410 and the filter unit 600. Although not specifically illustrated, the solenoid valve 420 grasps the remaining quantity in the double pipe 100 with the built-in controller and opens it to the filter unit 600 side. The double pipe 100 is supplied with water to be replenished.

In addition, the solenoid valve 420 is not particularly shown, but the pedal switch for opening and closing the intake port 800 by the user's foot or the combination of the sensor and the controller for opening and closing the intake port 800 by detecting the user's movement can be taken. Could be.

Of course, the solenoid valve 420 may be further installed between the filter unit 600 and the inlet side of the supply pipe 110.

In addition, the valve unit 400 may be applied to a structure including a check valve 430 mounted to the intake port 800 together with the pressure reducing valve 410 to manually open and close the discharge of water as shown in FIG.

1 to 3, the control unit 300 is shown as a structure for cooling the refrigerant flows, but is not limited to this supply pipe by connecting a heater or control tube 120 and a steam generator operated by an external power source ( Of course, it is also possible to modify or apply to a structure such as heating the water in 110.

On the other hand, the present invention, as shown in Figures 4 and 5 includes a hot water control unit 310 for the purpose of heating the water control unit 300, and a cold water control unit 320 for cooling the water, the hot water control unit ( The first double pipe 100 ′ and the second double pipe 100 ″ connected to the 310 and the cold water control unit 320 may be applied.

That is, the first double pipe 100 'includes a first supply pipe 110' having a flow path in which water flows in one direction, and a first control pipe 120 'disposed along a length direction of the first supply pipe 110'. Is formed to pivot at least once or more to form a coil shape as a whole.

The second double pipe 100 ″ includes a second supply pipe 110 ″ having a flow path in which water flows in one direction, and a second control pipe 120 ″ disposed along a length direction of the second supply pipe 110 ″. Is formed to pivot at least once or more to form a coil shape as a whole.

As described above, the control unit 300 heats the water in the first double pipe 100 'and cools the water in the second double pipe 100'. The ends of the first and second control pipes 120 'and 120 " And a hot water control unit 310 connected to the first control pipe 120 'to heat the water, and a cold water control unit 320 connected to the second control pipe 120 "to cool the water. ).

In addition, the valve unit 400 is mounted between the filter unit 600 and the water direct pipe 700 connected to the first and second supply pipes 110 ′ and 110 ″, respectively, and the first and second supply pipes 110 ′ and 110. It serves to control the discharge of water through the intake port (800 ', 800 ") provided in the first and second supply pipe (110', 110"), respectively from ").

Here, the outside of the first and second double pipe (100 ', 100 ") is insulated by the protective portion (S', S") including the heat insulating material, the intake port (800 ', 800 ") on the sink 900 Exposed, it can be seen that the first and second double pipes 100 ′ and 100 ″, the control unit 300, and the valve unit 400 are built in the sink 900.

The hot water control unit 310 includes a heater 312 inserted into the first control pipe 120 ′ and heating water with power supplied from the outside.

At this time, the cold water control unit 320 is connected to one end of the second control pipe (120 ″), the capillary tube 321 through which the refrigerant flows, the condenser 322 connected to the capillary tube 321 and the refrigerant condensed, and the condenser And a compressor 323 connected to the 322 to compress the refrigerant, and the other end of the second control pipe 120 ″ and the compressor 323 are connected to the refrigerant return pipe 324 to be connected to the second control pipe 120. The refrigerant flowing through ") is repeated to return to the compressor 323.

More detailed operation mechanism of the cold water control unit 320 is similar to the above-described embodiment, and thus will be omitted for convenience.

In addition, the second double pipe 100 ″ in which water is cooled may be equipped with a germicidal lamp L to sterilize by ultraviolet irradiation to maintain a clean state of the second supply pipe 110 ″.

On the other hand, the valve unit 400 is mounted between the water supply pipe 700 and the filter unit 600, the filter unit 600 and the first and second double pipes 100 ', 100 in a state where the pressure is appropriately dropped. A pressure reducing valve 410 is included to reduce the pressure load by supplying water to ").

A first solenoid valve 421 is mounted between the pressure reducing valve 410 and the filter unit 600, and a second solenoid valve () is disposed between the filter unit 600 and the first supply pipe 110 ′. 422 is mounted, and a third solenoid valve 423 is mounted between the filter unit 600 and the second supply pipe 110 ".

The first solenoid valve 421 is mounted between the pressure reducing valve 410 and the filter unit 600. Although not shown in particular, the first solenoid valve 421 is provided with a built-in controller to store the remaining water in the first and second double pipes 100 'and 100 ". After grasping and opening, water to be supplemented to the first and second double pipes 100 ′ and 100 ″ is supplied to the filter unit 600.

In addition, although the second and third solenoid valves 422 and 423 are not specifically illustrated, a pedal switch for opening and closing the intake ports 800 'and 800 "by the user's foot or the user's movement is sensed by detecting the user's movements. ") Can be taken with a combination of sensors and controllers that open and close the lights.

Meanwhile, the present invention includes a body portion 201 formed of an inner cylinder 210 and an outer cylinder 220 together with a double pipe 100 including a supply pipe 110 and a control pipe 120 as shown in FIGS. 6 and 7. The structure in which the vacuum insulation tank 200 is mounted may be applied.

That is, the double pipe 100 has a supply pipe 110 having a flow path in which water flows in one direction, and a control pipe 120 disposed along the length direction of the supply pipe 110, and is pivoted at least once to form a coil shape as a whole. It is a structure that forms.

The vacuum insulation tank 200 has a body portion 201 formed of an outer cylinder 220 for forming a space V in which a vacuum state is maintained between the outer surface of the inner cylinder 210 in which water is accommodated. The structure is finished with.

When the above-mentioned residual air is discharged to the outer surface of the outer cylinder 220 and the vacuum holding part 500 provided in the lower side of the outer cylinder 220 so that the residual air of the space V may be discharged to the vacuum insulation tank 200. An inner pressure sphere 240 for maintaining the shape of the inner cylinder 210 and the outer cylinder 220 is provided.

The control unit 300 is connected to both ends of the control pipe 120 and the cover 230, respectively, and heats the water in the supply pipe 110 or the inner cylinder 210 by the energy supplied from the outside, the supply pipe 110 or It is a structure that cools the water in the inner cylinder 210.

The valve unit 400 is mounted between the filter unit 600 and the water direct pipe 700 connected to the supply pipe 110 and the inner cylinder 210, respectively, and the supply pipe 110 and the supply pipe 110 and the cover 230 from the supply pipe 110 and the cover 230. It serves to control the discharge of water through the intake port (810, 820) provided in the cover 230, respectively.

The outside of the double pipe 100 is insulated with a protective part (S) including a heat insulating material, the intake ports 810, 820 are exposed on the sink 900, the control with the double pipe 100 and the vacuum insulation tank 200 It can be seen that the unit 300 and the valve unit 400 are built in the sink 900.

In addition, the cover 230 is to close the body portion 201 as described above, as shown in the bone 250 recessed toward the bottom side of the inner cylinder 201 along the edge is formed in a ring shape, bone ( The portion extending from the edge of the 250 is to maintain a tight airtight state by the edge of the body portion 201 and the method of curling, filling or welding of the packing material (not shown).

Here, in FIG. 7, reference numeral 231 denotes a terminal for connecting a power supply to the heater 306 built into the inner cylinder 210, and 233 is for fixing the vacuum insulating tank 200 to the sink 900. Bracket, 234 is an inlet connected to the filter unit 600 and the pipe, 235 is an outlet connected to the inlet 820, 236 is a temperature sensor.

At this time, the upper surface of the cover 230, even if the water leaks based on the bone 250 occurs in the electrical devices such as the terminal 231 and the temperature sensor 236 mounted on the upper surface of the cover 230 It is preferable that the edge of the valley 250 and the edge of the body portion 201 are formed to be equal to or higher than the upper surface of the combined portion so as not to contact each other.

On the other hand, the internal pressure sphere 240 is due to the pressure imbalance of the inside and outside of the space portion (V) in the process of discharging the residual air to maintain the vacuum state of the space (V) through the vacuum holding unit 500 to be described later In addition to the purpose of preventing the shape of the outer cylinder (210, 220) is deformed, it is also provided to improve the structural strength as a whole.

As shown in FIG. 7, the first protruding ring 241 protrudes in a ring shape along at least one outer circumferential surface in the up and down direction to the outer surface of the outer cylinder 220, and the second protruding ring 242 is the center of the bottom surface of the inner cylinder 210. The drain pipe 211 communicated from the lower surface of the outer tube 220 penetrated in the center is provided with at least one protruding concentrically around the drain pipe 211 described above.

The first and second protruding rings 241 and 242 have an outer cylinder due to the higher structural strength of the panel whose substantial area is increased by the corrugated structure, etc., than the smooth and flat panel without the same projecting structure or the corrugated structure per unit area. It is provided in the outer peripheral surface and bottom surface of 220, respectively.

On the other hand, the vacuum holding unit 500 is provided to discharge the remaining air in the space (V) as described above to maintain the space (V) in a vacuum state, the air discharge pipe 510 and the protective cover 520 It includes.

The air discharge pipe 510 is formed on the bottom surface of the outer cylinder 220 and communicates with the space portion V, and the protective cover 520 is detachably coupled to the lower side of the outer cylinder 220 to protect the air discharge pipe 510. Do it.

That is, the vacuum holding part 500 is a key to lowering the thermal conductivity of the body portion 201 as much as possible to maintain a continuous heat insulation effect, and for this purpose, the space part V needs to be close to a vacuum state. have.

Thus, referring to FIG. 7, the protective cover 520 is discharged from the remaining air in the space V through the air discharge pipe 510, and the air discharge pipe 510 is sealed with a separate finisher (not shown). After that, it is preferable to have the following structure to protect the above-described air discharge pipe 510.

Here, the protective cover 520 is a cylinder wall 521 which is detachably coupled to the lower outer surface of the outer cylinder 200, and the drain pipe 211 side communicated from the bottom center of the inner cylinder 210 from the bottom edge of the cylinder wall 521 The bottom surface 523 extending toward the center and penetrating the center thereof, and the contact horn 525 extending from the edge of the center penetrated by the bottom surface 523 toward the bottom of the outer cylinder 220 and in close contact with the bottom of the outer cylinder 220. The structure including) can be applied.

That is, the structure of the above-described protective cover 520 is to discharge the residual air in the space (V) with a vacuum pump or the like through the air discharge pipe 510 when the vacuum state of the space (V) is weakened with long time use. It can be said to be a structure in which detachable coupling is possible when necessary.

At this time, the end edge of the contact horn 525 is preferably fixed in close contact with the contact ring protrusion 223 protruding in a ring shape around the drain pipe 211 from the bottom of the outer cylinder 220.

Looking at the structure of the protective cover 520 in more detail it can be seen that the detachable coupling to the engaging jaw surface 221 formed in the step along the outer surface of the lower side of the outer cylinder (220).

That is, the first locking ring groove 522 recessed along the outer circumferential surface is provided in the tube wall 521 of the protective cover 520, and the first locking ring groove ( The second locking ring groove 222 recessed toward the inner cylinder 210 side is provided at a position corresponding to the 522 so that the first and second locking ring grooves 522 and 222 are coupled to each other to be sealed.

As described above, the present invention can make full use of the limited space, and can immediately take in water at a desired temperature, and can efficiently manage energy. It can be seen that the basic technical idea is to provide a sink-intake intake system that can be prevented as well as maintain a continuous heat insulation performance with a relatively simple structure and is easy to follow-up.

While the present invention has been described in connection with certain exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

Therefore, the true technical protection scope of the present invention will be defined by the following claims.

100 ... double pipe 110 ... supply pipe
112 ... sitting rib 112 '... sitting groove
120 control tube 100 '... 1 double tube
110 '... first supply line 120' ... first control line
100 "... 2nd double pipe 110" ... 2nd supply pipe
120 "... 2nd control tube 200 ... vacuum insulation tank
201.Body 210.Inner tube
211 Drain tube 220
221 ... Jointing jaw surface 222 ... Secondary locking ring groove
223 ... contact ring projection 230 ... cover
Terminal 233 ... Fixing bracket
234 ... water pipe 235 ... water pipe
236 ... temperature sensor 240 ... pressure port
241 ... 1st projection ring 242 ... 2nd projection ring
250 ... Goal 300 ... Control Unit
301 Capillary 302 Condenser
303 Compressor 304 Refrigerant Return Tube
305 ... dryer 306 ... heater
310 ... hot water control unit 312 ... heater
320.Cold water control unit 321 ... Capillary tube
322 ... condenser 323 ... compressor
324 ... refrigerant return tube 325 ... dryer
400 ... Valve unit 410 ... Reducing valve
420 Solenoid Valve 421 Solenoid Valve
422 ... 2nd solenoid valve 423 ... 3rd solenoid valve
500 vacuum holding unit 510 air discharge pipe
520 Protective cover 521 Wall
522.First engaging ring groove 523.Floor side
525 contact horn 600 filter unit
700 ... Water direct pipe 800, 800 ', 800 ", 810, 820 ...
900 sinks, 910 sinks
C ... connector S, S ', S "... protector
V ... space

Claims (17)

A double pipe having a supply pipe having a flow path through which water flows in one direction, and a control pipe disposed along a length direction of the supply pipe and pivoting at least once or more to form a coil shape as a whole;
A control unit connected to both ends of the control tube and configured to adjust a water temperature in the supply tube by energy supplied from the outside; And
And a valve unit mounted between the filter unit connected to the supply pipe and the water direct pipe, and configured to control the discharge of water through the intake port through the supply pipe.
The outside of the double pipe is insulated,
The intake port is exposed on the sink, the double pipe and the control unit and the valve unit is built-in sink sink intake system.
The method of claim 1,
The supply pipe and the control pipe are formed integrally cast or extruded, and at least one or more times to form a coil shape as a whole, the control pipe is disposed inside the coil shape, the supply pipe is disposed outside the coil shape, respectively And, the inner surface and the outer surface of the protection portion for protecting the outer surface of the double pipe is an anodizing treatment, anti-corrosive coating or anti-corrosion resin coating treatment sink built-in water intake system.
The method of claim 1,
The supply pipe is further provided with a pair of seating ribs protruding on the outer peripheral surface in the longitudinal direction of the supply pipe to face the control pipe,
A sinking intake system having a sinking groove in which a temperature sensor is mounted between the seating ribs.
The method of claim 1,
Both ends of the supply pipe is an inlet or outlet, respectively, and the inlet and outlet are connected to the supply pipe and the water inlet pipe and the inlet to be connected to the water inlet pipe and the inlet respectively,
The outer surface and the inner circumferential surface of the connector is coated with silver nano or photocatalyst,
The connector is equipped with a sink intake system is equipped with a germicidal lamp for irradiating ultraviolet rays inside the supply pipe.
A first supply pipe having a flow path through which water flows in one direction, and a first control pipe disposed along a length direction of the first supply pipe, the first double pipe forming an overall coil shape by turning at least once;
A second double pipe formed with a second supply pipe having a flow path through which water flows in one direction, and a second control pipe disposed along a length direction of the second supply pipe and pivoting at least once or more to form a coil shape as a whole;
A control unit connected to both ends of the first and second control tubes, respectively, for heating water in the first supply pipe by energy supplied from the outside and cooling the water in the second supply pipe; And
A valve unit mounted between the filter unit and the water direct pipe connected to the first and second supply pipes, respectively, and controlling the discharge of water from the first and second supply pipes through the intake ports provided in the first and second supply pipes, respectively. Include,
The outside of the first and second double pipe is insulated,
The intake port is exposed on the sink, the first, second double pipe and the control unit and the valve unit is built-in sink sink intake system.
The method of claim 1,
The control unit,
A capillary tube connected to one end of the control tube and a refrigerant flowing therein;
A condenser connected to the capillary tube to condense refrigerant;
A compressor connected to the condenser to compress the refrigerant;
The other end of the control tube and the compressor is connected to the pipe is a sink built-in water intake system for repeating the circulation of the refrigerant flowing through the control tube to the compressor.
The method of claim 5, wherein
The control unit,
A hot water control unit connected to the first control pipe to heat water;
And a cold water control unit connected to the second control pipe to cool the water.
The method of claim 7, wherein
The hot water control unit,
And a heater inserted into the first control tube and configured to heat water with power supplied from the outside.
The method of claim 7, wherein
The cold water control unit,
A capillary tube connected to one end of the second control tube and a refrigerant flowing therein;
A condenser connected to the capillary tube to condense refrigerant;
A compressor connected to the condenser to compress the refrigerant;
The other end of the second control pipe and the compressor is connected to the pipe is a sink built-in water intake system for repeating the circulation of the refrigerant flowing through the second control pipe to the compressor.
The method of claim 1,
The valve unit,
A pressure reducing valve mounted between the water feed pipe and the filter unit;
And a solenoid valve mounted between the pressure reducing valve and the filter unit.
The method of claim 1,
The valve unit,
A pressure reducing valve mounted between the water feed pipe and the filter unit;
And a check valve mounted to the intake port and including a check valve for manually opening and closing water discharge.
The method of claim 5, wherein
The valve unit,
A pressure reducing valve mounted between the water feed pipe and the filter unit;
A first solenoid valve mounted between the pressure reducing valve and the filter unit;
A second solenoid valve mounted between the filter unit and the first supply pipe;
And a third solenoid valve mounted between the filter unit and the second supply pipe.
A double pipe having a supply pipe having a flow path through which water flows in one direction, and a control pipe disposed along a length direction of the supply pipe and pivoting at least once or more to form a coil shape as a whole;
A vacuum holding part provided at a lower side of the outer cylinder so that a body part formed of an outer cylinder forming a space portion in which a vacuum state is maintained between the outer surface of the inner cylinder in which water is accommodated is covered with a cover, and the remaining air of the space portion is discharged; A vacuum insulated tank provided with an inner pressure port for maintaining the shape of the inner cylinder and the outer cylinder when the residual air is discharged to an outer surface of the outer cylinder;
A control unit connected to both ends of the control pipe and the cover, respectively, for heating water in the supply pipe or the inner cylinder by energy supplied from the outside, and cooling the water in the supply pipe or the inner cylinder; And
And a valve unit mounted between the supply pipe and the filter unit connected to the inner cylinder and the water direct pipe, respectively, and controlling the discharge of water from the supply pipe and the cover through water inlets provided on the supply pipe and the cover, respectively.
The outside of the double pipe is insulated,
The intake port is exposed on the sink, the double tube and the vacuum insulation tank, the control unit and the valve unit is built-in sink sink intake system.
The method of claim 13,
The pressure resistant sphere,
A first projection ring protruding in a ring shape along at least one outer circumferential surface in an up and down direction to an outer surface of the outer cylinder;
The drain pipe communicated from the center of the bottom surface of the inner cylinder is provided on the bottom surface of the outer cylinder penetrating the center, the sink-intake intake system comprising a second projection ring protruding at least one concentrically around the drain tube .
The method of claim 13,
The vacuum holding unit,
An air discharge pipe formed on a bottom surface of the outer cylinder to communicate with the space part;
A sink integrated water intake system including a protective cover that is detachably coupled to the lower side of the outer cylinder to protect the air discharge pipe.
The method of claim 15,
The protective cover,
A cylinder wall detachably coupled to an outer surface of a lower side of the outer cylinder;
A bottom surface extending from the bottom edge of the tube wall toward the drain pipe side communicating from the center of the bottom surface of the inner cylinder and penetrating the center thereof;
A contact horn extending from the penetrating central edge of the bottom surface toward the bottom of the outer cylinder and in close contact with the bottom of the outer cylinder;
An end edge of the contact horn is fixed in close contact with the contact ring projection protruding in a ring shape around the drain pipe from the bottom of the outer cylinder.
The method of claim 15,
The protective cover,
Detachable and coupled to the engaging jaw surface formed in the step along the outer surface of the lower side of the outer cylinder,
The protective cover is provided with a first locking ring groove recessed along the outer circumferential surface toward the coupling jaw surface side,
The engaging jaw surface is provided with a second locking ring recess recessed toward the inner cylinder side at a position corresponding to the first locking ring groove,
Vacuum insulation tank that the first and second locking ring groove is coupled to each other and sealed.

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