KR101633320B1 - Low power instantaneous water heater - Google Patents

Abstract

The present invention relates to an ultra low power instantaneous water heater, comprising: a main body forming an accommodation space for accommodating water and forming an inlet through which water flows into the accommodation space and an outlet through which water flows in the accommodation space; A heat generating lamp unit installed in the accommodation space and generating electricity by receiving electricity; A heat transfer unit wound around the heat generating lamp unit and transferring the heat energy to the water; And a coating part coated on an outer surface of the heat transfer part and absorbing the heat energy on one surface and emitting the heat energy on the other surface.
Thereby, the efficiency of transferring the thermal energy to water is greatly improved, thereby providing an ultra low power instantaneous water heater which can supply hot water immediately.

Description

Low power instantaneous water heater {LOW POWER INSTANTANEOUS WATER HEATER}

The present invention relates to an ultra low power instantaneous water heater, and more particularly, to an ultra low power instantaneous water heater, in which a coating portion including ceramics (SiO _2, etc.) is coated on the outer surface of a heat transfer portion wound on a heat lamp portion, To an ultra-low power instantaneous water heater in which the efficiency with which water is transferred to the water is greatly improved.

An instantaneous water heater is a device that warms water by supplying water at the same time as the water flows into the pipe, and there are an electric instantaneous water heater using electricity and a gas instant water heater using gas.

The instantaneous water heater supplies electricity to a heating element, that is, a heating coil to generate thermal energy, and by heating the water using the generated thermal energy, it supplies necessary hot water.

When such a conventional instantaneous water heater is used, a large energy loss occurs in the heat conduction process in which the heat energy generated in the heat generating coil is transmitted to the water, and therefore, there is a problem that a huge amount of electricity must be used for supplying hot water.

 Further, in the case of using a conventional instantaneous water heater, since the thermal conductivity of the heat generating coil is very low, water takes a long time to absorb heat from the heat generating coil. Accordingly, there is a problem in that hot water can not be immediately provided when hot water is required in a state where the instantaneous water heater is not operated.

Therefore, as to improve the conventional problems purpose is this of the present invention, by coating the coating section, or the like ceramic (Ceramics, SiO _2, etc.) to the outer heat transfer member which is wound around the heating lamp unit, generated in the heating lamp unit The present invention provides an ultra low power instantaneous water heater in which efficiency of transferring heat energy to water is greatly improved.

According to an aspect of the present invention, there is provided a water purifier comprising: a main body forming an accommodation space in which water is accommodated and forming an inlet through which water flows into the accommodation space and an outlet through which water flows in the accommodation space; A heat generating lamp unit installed in the accommodation space and generating electricity by receiving electricity; And a coating unit that is wound on the heat generating lamp unit and transfers the heat energy to the water, a coating unit that is coated on the outer surface of the heat transfer unit and absorbs the heat energy to one surface and emits the heat energy to the other surface. It is accomplished by a water heater.

Further, the temperature of the water can be controlled by the current supplied to the heat generating lamp unit.

According to another aspect of the present invention, there is provided a method for controlling a temperature of an object to be heated, comprising: a temperature sensor for sensing temperature of the water to generate temperature information; And a control unit for controlling the display unit.

According to another aspect of the present invention, there is provided a lighting apparatus including a timer for generating time information by measuring a time at which electricity is supplied to the heat lamp unit, wherein the controller receives the time information, , The electricity supplied to the heat lamp unit can be cut off.

In addition, the present invention may further include a finishing unit, which is made of an insulating and heat-dissipating material, and closes a connection point between the main body and the heat generating lamp unit.

Also, the heat generating lamp unit may include a case part, which is made of carbon fiber, and includes a coil part that generates heat by receiving electricity and a quartz, and that accommodates the coil part so that the coil part and the water are not in contact with each other; . ≪ / RTI >

In addition, the coating portion may include ceramics (SiO ₂ ).

INDUSTRIAL APPLICABILITY According to the present invention, the efficiency with which thermal energy is transferred to water is greatly improved, so that hot water can be supplied immediately.

In addition, since the efficiency with which heat energy is transferred to water is greatly improved, the consumed power can be greatly reduced.

Further, the coating part coated on the outer surface of the heat transfer part does not generate a film (water film) generated on the surface of the heat transfer part.

Further, according to the heat transfer portion (modified example, stencil wipe type), the sectional area in which the water accommodated in the accommodation space and the heat transfer portion (modification example, stencil type) are contacted greatly increases, The heat transfer efficiency from the stencil type to the water contained in the accommodation space is greatly improved.

In addition, by using the temperature sensor, the timer, and the control unit, a safety accident caused by overheating of the water can be prevented.

In addition, since the structure is simple and mass production is possible, the production cost can be reduced.

FIG. 1 is an overall configuration diagram of an ultra low power instantaneous water heater according to an embodiment of the present invention,
FIG. 2 is a perspective view of a body portion, an exothermic lamp portion, a heat transfer portion, a coating portion, and a finishing portion of the ultra low power instantaneous water heater of FIG. 1,
Fig. 3 is an exploded perspective view of the main body, the heat generating lamp, the heat transfer part, the coating part and the finishing part of the ultra-low power instantaneous water heater of Fig. 1,
FIG. 4 is a schematic view of a heat transfer part and a coating part of the ultra-low power instantaneous water heater of FIG. 1,
FIG. 5 is a cross-sectional view of a heat transfer part and a coating part of the ultra-low power instantaneous water heater of FIG. 1,
FIG. 6 is a flowchart illustrating a control process of the controller for preventing overheating of the ultra low power instantaneous water heater of FIG. 1;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, an ultra low power instantaneous water heater according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 is a perspective view of a main body, an exothermic lamp, a heat transfer part, a coating part, and a finishing part of the ultra-low power instantaneous water heater of FIG. 1, and FIG. FIG. 3 is an exploded perspective view of a body portion, an exothermic lamp portion, a heat transfer portion, a coating portion, and a finishing portion of the ultra-low power instantaneous water heater of FIG.

1 to 3, an ultra-low power instantaneous water heater 100 according to an embodiment of the present invention includes a main body 110, a heat generating lamp 120, a heat transfer part 130, a coating part 140 A temperature sensor 150, a timer 160, a controller 170, and a finishing unit 180.

The body portion 110 forms an accommodation space s in which water is received from the outside so that an inlet i through which water flows into the accommodation space s and an outlet through which the water flows out from the accommodation space s o) are formed.

The heat storage lamp unit 120, the heat transfer unit 130 and the coating unit 140 are disposed in the accommodation space s and the heat energy generated in the heat lamp unit 120 is transferred to the heat transfer unit 130 and the coating unit 140 To the water contained in the accommodation space (s).

A finishing portion 180 is provided at both ends of the main body 110 to close the connection point between the heat generating lamp portion 120 and the main body 110 to thereby allow water to leak from the accommodating space s And the heat energy of the accommodation space (s) is prevented from being released to the outside.

The heat generating lamp unit 120 is installed in the accommodation space s and includes a coil part 121 and a case part 122 by generating electricity by receiving electricity from the power source p.

The coil part 121 is made of carbon fiber by receiving electricity from the power source p to generate heat energy and is accommodated in the case part 122 to avoid contact with water in the accommodation space s.

When a voltage is applied to both ends of the coil part 121, thermal energy is generated by the resistance of the coil as a current flows through the coil. The generated heat energy is transmitted through the case part 122 to the water accommodated in the accommodating space (s) . Thereby, the water is heated.

The current flowing through the coil part 121 may be adjusted by adjusting the voltage applied to both ends of the coil part 121. The current flowing through the coil part 121 may be adjusted by adjusting the voltage applied to both ends of the coil part 121, The amount is determined. That is, the magnitude of the current flowing in the coil portion 121 and the amount of the thermal energy generated in the coil portion 121 are proportional to each other. Further, the temperature of the water to be heated is in proportion to the amount of heat energy.

Therefore, the temperature of the water to be heated can be controlled by the electric current supplied to the coil portion 121. [ By controlling the current flowing through the coil part 121, the temperature of the water can be easily controlled.

The case portion 122 receives the coil portion 121 so that the coil portion 121 is not in contact with water in the accommodation space s.

Since the case 122 is required to transmit the heat generated in the coil 121 to the receiving space s, it is preferable that the case 122 is made of quartz or the like having high heat resistance and high thermal conductivity.

FIG. 4 is a schematic view of a heat transfer part and a coating part of the ultra low power instantaneous water heater of FIG. 1, and FIG. 5 is a cross-sectional view of a heat transfer part and a coating part of the ultra low power instantaneous water heater of FIG.

As shown in FIGS. 2 (a), 3 (a), 4, and 5, the heat transfer unit 130 transfers the heat energy generated by the heat generating lamp unit 120 by water, And is wound around an exothermic lamp part 120.

The heat transfer part 130 is generally provided as a coil, like the heat lamp part 120 described above. Since the heat transfer part 130 is wound around the heat transfer part 130 to fill the accommodation space s, the heat energy generated by the heat transfer part 130 can be uniformly transferred to the water contained in the accommodation space s.

As shown in FIGS. 2 (b) and 3 (b), on the other hand, the heat transfer portion (modified example) 130a is provided in the form of a stencil wipe and can be filled in the accommodation space s. Here, the stenewheel means a structure in the form of a net structure provided with a stainless steel material.

The heat transfer portion (modification 130a) provided in the form of the stencil wool greatly increases the cross-sectional area of contact between the water accommodated in the accommodation space s and the heat transfer portion (modification example) 130a, The heat transfer efficiency to the water accommodated in the accommodation space s is significantly improved in the first embodiment (modification example 130a).

As shown in FIGS. 4 and 5, the coating part 140 is coated on the outer surface of the heat transfer part 130 by absorbing the heat energy on one side and discharging it on the other side.

The coating portion 140 is formed of a heat dissipation material including ceramics (e.g., SiO ₂ ). The heat dissipation material absorbs heat energy on one side and emits it to the other side. Generally, it is provided in a nano scale liquid phase and coated on the surface to be coated to a thickness of about 20 to 25. The above-mentioned heat radiating material has a very excellent heat dissipation performance and does not generate a film on the surface even if it comes into contact with water for a long time.

The coating part 140 is coated on one side of the heat transfer part 130 to absorb thermal energy in the vicinity of the other side of the heat transfer part 130 into the heat transfer part 130 and to transfer the absorbed heat energy to the surface of the heat transfer part 130 And discharges the heat to the space near one surface of the heat transfer part 130.

As a result, the heat energy transfer rate from the heat generating lamp unit 120 to the water is greatly increased, so that the time taken for heating the water contained in the receiving space s is shortened.

The temperature sensor 150 senses the temperature of the water flowing in the outlet o and generates temperature information so that the temperature sensor 150 is installed on the outlet o and is electrically connected to the controller 170. [

The generated temperature information is transmitted to the controller 170. When the temperature of the water is greater than a preset temperature value in the controller 170 using the temperature information, Thereby preventing the heat generating lamp unit 120 from abnormally overheating.

The timer 160 is electrically connected to the power source p and the control unit 170 by measuring the time that electricity is supplied to the heat generating lamp unit 120 to generate time information.

The generated time information is transmitted to the control unit 170. The control unit 170 uses the time information to calculate the time at which the electricity of the power source p is supplied to the heat generating lamp unit 120, The power supplied to the heat generating lamp unit 120 is cut off, thereby preventing the heat generating lamp unit 120 from being abnormally overheated.

The controller 170 cuts off electricity supplied from the power source p to the heat generating lamp unit 120 when the heat generating lamp unit 120 is excessively overheated to cause a safety problem, p, the temperature sensor 150, and the timer 160, as shown in FIG.

The control unit 170 receives the temperature information generated from the temperature sensor 150. When the temperature value of the water obtained from the temperature information is greater than a preset temperature value, Thereby preventing the heat generating lamp unit 120 from abnormally overheating.

When the value of the time at which the electricity of the power source p obtained from the time information is supplied to the heat generating lamp unit 120 is larger than the value of the predetermined time by receiving the time information generated from the timer 160, The power supplied to the heat generating lamp unit 120 is cut off, thereby preventing the heat generating lamp unit 120 from abnormally overheating.

The finishing unit 180 is installed at the connection point by closing the connection point between the main body 110 and the heat generating lamp unit 120. [

By this closing portion 180, the insulation of the connection point is secured, and the leakage of water in the accommodation space s and the heat energy of the accommodation space s are prevented from being released to the outside.

The finishing portion 180 may be formed of graphite having a great effect on insulation, heat dissipation, and waterproofing. However, the finishing portion 180 is not necessarily limited to the graphite. The finishing portion 180 may include a connection point between the main body portion 110 and the heat generating lamp portion 120 It may be provided as long as it can be closed, isolated, heat-dissipated, or waterproofed.

Therefore, according to the ultra-low power instantaneous water heater 100 according to the embodiment of the present invention, the efficiency of transferring the thermal energy to water is greatly improved, so that hot water can be supplied to the user immediately. In addition, since the efficiency with which heat energy is transferred to water is greatly improved, the consumed power can be greatly reduced.

Hereinafter, the operation of the ultra low power instantaneous water heater according to one embodiment of the present invention will be described in detail.

When the user opens the water supply valve to use the water, the water pressure of the pipe changes. At this time, the water pressure sensor w senses the water pressure and transmits the electric signal to the controller 170.

The control unit 170 then transmits a signal to the power source p and the power source p receiving the signal supplies electricity to the heat generating lamp unit 120 and the solenoid valve v.

Thereby, the solenoid valve v is opened, and the water supply to the inlet i is started through the opened solenoid valve v. At the same time, heat energy is generated in the heat generating lamp unit 120, and then water introduced into the inlet (i) and received in the receiving space (s) is heated by receiving the above-mentioned heat energy.

Therefore, according to the operation of the ultra-low power instantaneous water heater 100 according to the embodiment of the present invention, the user can easily operate the ultra low power instantaneous water heater by simply opening the water supply valve without depressing another operation button .

On the other hand, it is also possible to provide a separate manual button connected to the power source (p) on the water valve side so that the user can press the manual button to heat the heat lamp part 120 to supply hot water.

Hereinafter, a process for preventing overheating of the ultra-low power instantaneous water heater 100 according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 6 is a flowchart illustrating a control procedure of the controller 170 for preventing overheating of the ultra-low power instantaneous water heater of FIG.

6, when a power source p is applied to the ultra-low power instantaneous water heater 100 according to an embodiment of the present invention, the temperature sensor 150 and the timer 160 are operated.

The temperature sensor 150 senses the temperature of the water flowing out from the outlet o to generate temperature information. The timer 160 measures time from when the power source p is applied to generate time information. The generated temperature information and time information are transmitted to the controller 170.

The control unit 170 extracts the temperature value of the water from the received temperature information and extracts the measured time value from the received time information.

When the extracted water temperature value is smaller than the predetermined limit temperature value, the ultra-low power instantaneous water heater 100 according to the embodiment of the present invention continues to operate.

If the extracted water temperature value is larger than the predetermined limit temperature value, the controller 170 compares the measured time value with the predetermined time value.

As a result of the comparison, when the measured time value is greater than the preset time value, the controller 170 cuts off the power supplied to the heat generating lamp unit 120 so that the power saving light moment according to an embodiment of the present invention Thereby stopping the operation of the water heater 100.

By this operation of the control unit, it is prevented that the heat generating lamp unit 120 is abnormally overheated, so that a safety accident that can be caused by overheating of the heat generating lamp unit 120 can be prevented in advance.

The scope of the present invention is not limited to the above-described embodiments, but may be embodied in various forms of embodiments within the scope of the appended claims. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims.

100: an ultra low power instantaneous water heater according to an embodiment of the present invention
110: main body part 120: heat generating lamp part
121: coil part 122: case part
130: heat transfer part 130a: heat transfer part (modification example)
140: Coating portion 140a: Coating portion (modified example)
150: Temperature sensor 160: Timer
170: control unit 180:
s: accommodation space i: inlet
o: outlet p: power source
w: Water pressure sensor v: Solenoid valve

Claims (7)

A main body forming an accommodation space for accommodating water and forming an inlet through which water flows into the accommodation space and an outlet through which water flows in the accommodation space;
A heat generating lamp unit installed in the accommodation space and generating electricity by receiving electricity;
A heat transfer unit wound around the heat generating lamp unit and transferring the heat energy to the water;
And a coating part coated on an outer surface of the heat transfer part and absorbing the heat energy to one surface and emitting the heat energy to the other surface,
The temperature of the water being controlled by a current supplied to the heat lamp unit and generating temperature information by sensing the temperature of the water; Further comprising a control unit for interrupting electricity supplied to the heat lamp unit,
And a timer for generating time information by measuring a time when electricity is supplied to the heat lamp unit,
Wherein the control unit cuts off electricity supplied to the heat lamp unit when the time information is received and the time information is longer than a predetermined time. delete delete delete The method according to claim 1,
Further comprising a finishing unit which is provided as an insulating and heat dissipating material and closes a connection point between the main body and the heat generating lamp unit. 6. The method according to claim 1 or 5,
The heat generating lamp unit includes:
And a case part which is made of carbon fiber and which is made of quartz and which receives the electricity and generates heat, and a case part which accommodates the coil part so that the coil part and the water are not in contact with each other Electric power instantaneous water heater. The method according to claim 6,
Characterized in that the coating part comprises ceramics (SiO ₂ ).

Images