KR101491930B1 - A fluid heater device - Google Patents

Abstract

The present invention relates to an induction heating type fluid heater which is configured to cover the outer circumference of a heat exchange unit forming a pipe channel in which fluid flows, and includes a winding unit heating the heat exchange unit in an electromagnetic induction heating method, thereby heating fluid by directly heating a heat exchanger while not being sealed to form a medium in a main body as in the prior art. A fluid heater (100) heating fluid to maintain a temperature equal to or greater than a predetermined temperature includes a main body (110); a heat exchange unit (120) disposed inside the main body (110) and forming a pipe channel guiding the fluid flow; and a winding unit (130) which comes in close contact with the heat exchange unit (120) to heat the heat exchange unit (120) by the electromagnetic induction heating method in order to heat the fluid passing the heat exchange unit (120).

Description

[0001] The present invention relates to an induction heating type fluid heater device,

The present invention relates to an induction heating type fluid heater device and more particularly to an induction heating type fluid heater device including a winding portion configured to surround an outer circumference of a heat exchange portion forming a channel through which fluid flows and to heat the heat exchange portion by an electromagnetic induction heating method, The present invention relates to an induction heating type fluid heater device that can heat a fluid by directly heating a heat exchanger without hermeticity for forming a medium in a body as in the prior art.

Generally, it is the most important factor to maintain the paint quality by keeping the viscosity of the painted paint in the painting process of industrial products such as mobile phones and heavy equipment constant. Especially, in outdoor and indoor work environments where temperature is low as in winter, it is necessary to maintain the paint temperature (23 ~ 25 ℃) supplied to the nozzle constantly to maintain a constant paint quality, Can be saved.

Accordingly, the temperature of the paint supplied to the nozzle is kept constant by connecting the heat exchanger before supplying the paint stored in the painting paint storage tank to the nozzle by the pump.

However, in the conventional heat exchanger, the heat exchanger and the heating portion of the medium filled in the heat exchanger are completely hermetically sealed, and the structure of the heat exchanger is complicated by a safety circuit against pressure increase after heating. In addition, since the safety circuit (temperature control circuit, pressure control circuit) is installed in a completely sealed state for safety, it is difficult to repair the system if a failure occurs, and furthermore, the failure of the safety circuit causes a fatal accident There is a risk to be able to. In addition, the conventional product is configured to be mounted on the wall, and it is not easy to work the fixing bolt on the side wall, and the heating part is located on the upper part and is placed on the floor.

1, a heat exchanger of Korean Registered Utility Model No. 353225 (a name: a heat exchanger), as an example of a solution for solving the above-mentioned problems, includes a base portion 20 for providing a seating surface to be seated on the ground And a heat exchange unit 10 connected to the base unit 20 and performing heat exchange.

The base unit 20 is provided with a temperature control knob 21 for controlling the temperature of the medium 15 in the heat exchanging unit 10 and a power switch 23 and a power lamp 22.

The heat exchanging unit 10 includes an inlet pipe 7 for receiving paint from a paint storage tank and a heat exchanging pipe 17 for communicating with an outlet pipe 5 for supplying paint to the nozzle in a zigzag manner, The heat exchange pipe 17 is surrounded by a medium 15 such as water, antifreeze or oil. A heater 13 for heating the medium 15 is installed at the center of the heat exchange pipe 17.

Thus, in the conventional heat exchanger, the heat exchange pipe 17 surrounded by the medium 15 heated by the heater 13 performs the heat exchange action with the medium 15, and the fluid passing through the heat exchange pipe 17 Exchanges heat with the heat exchange pipe 17 so that the fluid passing through the heat exchange pipe 17 is maintained at a constant temperature so that the fluid is heated by a bathing method using a medium instead of directly heating to change the properties of the fluid Always keep the temperature constant.

However, in the conventional hot water type heat exchanger, the medium 15 is used to heat exchange with the fluid passing through the heat exchange pipe 17 in a heat conduction manner, so that the medium filled in the heat exchange portion 10 is discharged to the outside There is a problem that the watertightness must be maintained so as to prevent leakage.

In addition, the medium 15 is heated by the heater 13 provided at the center of the heat exchange pipe 17 and the heat exchange pipe 17 is heated through the heated medium 15, 17, a large amount of power is consumed in order to maintain the heating temperature of the fluid through the heater 13, and heat loss occurs during various steps, resulting in a decrease in thermal efficiency There is a problem that the heating time becomes very long.

The heat exchange pipe 17 is formed in a spiral zigzag shape at regular intervals so as to facilitate the heat conduction through the medium 15 heated by the heater 13, There is a problem in that the height of the heat exchanging unit 10 is increased as the height is raised.

In addition, when foreign matter penetrates into the inside of the heat exchanging unit 10, the medium 15 filled in the heat exchanging unit 10 is contaminated, so that heat conduction by the contaminated medium 15 is not smooth, There is a problem in that the efficiency of the exchange of the contaminated medium 15 is not smooth and the heat efficiency is lowered.

In addition, the heater 13 has a power density of about 7 W / cm < ² > or less as a sheath heater, shortening the service life thereof and preventing the heat exchange pipe 17 from being completely submerged in the medium 15, If the exposed portion of the heat exchange pipe 17 occurs for various reasons, it may be oxidized to a high temperature to cause a short circuit or a risk of electric shock.

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-mentioned problems. It is an object of the present invention to provide a heat exchanger, which includes a winding part configured to surround an outer circumference of a heat exchange part forming a channel through which fluid flows, The present invention is to provide an induction heating type fluid heater device that can heat a fluid by a direct heating method without having hermeticity for forming a medium in a main body.

Another object of the present invention is to optimize the size of the heat exchanging part by providing a heat exchanging part having an inlet and an outlet and formed in a spiral shape between the inlet and the outlet, Thereby improving the space usability of the fluid heater device.

It is a further object of the present invention to provide a coiled portion composed of a coating layer to surround the outer circumference of a heat exchange portion, a coil layer to heat the heat exchange portion by an electromagnetic induction heating method, and a heat insulating layer to prevent heat exchange with the heated heat exchange portion from the outside, And to improve the heat exchange efficiency according to the winding portion.

According to an aspect of the present invention, there is provided a fluid heater apparatus for heating a fluid to maintain a fluid at a predetermined temperature or a predetermined temperature, the fluid heater apparatus comprising: a main body; A heat exchanger provided inside the body and forming a conduit for guiding the flow of the fluid; And a winding part which is in close contact with the heat exchange part and heats the heat exchange part by an electromagnetic induction heating method to heat the fluid passing through the heat exchange part.

In the present invention, the main body is provided with a circuit section for controlling the apparatus; A heat radiating plate for radiating heat generated in the circuit unit is formed at one side of the heat exchanging unit; The heat generated by the circuit unit is dissipated by the heat dissipation plate, and the fluid passing through the heat exchange unit is heated, thereby improving heat exchange efficiency.

In the present invention, it is preferable that the main body further includes a switching element provided at one side of the heat exchanging part and generating heat according to a control signal of the circuit part to heat the fluid flowing through the heat exchanging part.

In the present invention, the heat exchanging portion includes: an inlet through which the fluid enters; An outlet through which the fluid is discharged; And a spiral portion provided between the inlet and the outlet and configured to be spirally formed by a plurality of windings to maximize the residence time so as to improve heat exchange efficiency of the fluid.

In the present invention, it is preferable that the spiral portions are formed so as to be brought into close contact with each other without being spaced apart from each other, so that heat exchange is performed also by mutually adjacent pipes.

In the present invention, the winding portion may include: a coating layer that is wrapped around the heat exchange portion so as to be spaced apart from the heat exchange portion; And a coil layer which is heated by electromagnetic induction in the heat exchanging part by an alternating current.

In the present invention, it is preferable that the winding portion further includes a heat insulating layer formed on the outer periphery of the coil layer to prevent a heat loss from occurring due to heat exchange with the outside of the heat exchanging portion heated by the coil layer .

In the present invention, it is preferable that the winding portion is configured so as to be wrapped in the entire width direction along the circumference of the helical heat exchange portion.

In the present invention, the coil layer may include: a bobbin provided on an outer periphery or an inner periphery of the heat exchange section; And a coil wound around the bobbin to induce a magnetic field to induction-heat the heat exchanger.

According to the present invention, since the winding portion that surrounds the outer periphery of the heat exchanging portion forming the channel through which the fluid flows and which heats the heat exchanging portion by the electromagnetic induction heating method is provided, There is an effect that the fluid can be heated by the direct heating method in the heat exchanger.

The present invention also provides a heat exchange unit having an inlet and an outlet and formed in a spiral shape between the inlet and the outlet so that the spirals do not have a constant interval and are in close contact with each other, thereby optimizing the size of the heat exchange unit, .

In addition, by providing the coil portion including the coat layer for surrounding the outer circumference of the heat exchange portion, the coil layer for heating the heat exchange portion by the electromagnetic induction heating method, and the heat insulating layer for preventing heat exchange with the heated heat exchange portion from the outside, And the efficiency is improved.

1 is a partial cutaway view of a conventional heat exchanger;
2 is a perspective view of a fluid heater device according to a first embodiment of the present invention;
3 is an exploded perspective view of a heat exchanger according to a first embodiment of the present invention;
4 is a cross-sectional view of a fluid heater device according to a first embodiment of the present invention.
5 is an exploded perspective view of a heat exchanger and a coil layer according to a second embodiment of the present invention.
FIG. 6 is a schematic cross-sectional view of a heat exchanger and a coil layer according to an embodiment of the present invention. FIG.
7 is a schematic cross-sectional view of a heat exchanger and a coil layer according to a third embodiment of the present invention.

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

≪ Embodiment 1 >

2 to 4, the fluid heater device 100 of the first embodiment includes a main body 110, a heat exchanging part 120 provided inside the main body 110, and a heat exchanging part And a winding unit 130 that heats the electrodes 120. The fluid heater device 100 is also provided with a temperature sensor 140 for specifying the temperature of the fluid heated through the heat exchanging part 120.

The main body 110 is a means for protecting the heat exchange unit 120.

The main body 110 is also provided with various switches such as a power switch 114 and a temperature control switch (or a temperature control knob 116). Further, a circuit portion 112 constituting the above-described various switches and control circuits is built in the inside of the main body 110.

The main body 110 is provided with a switching device 120 which is provided at one side of the heat exchanging part 120 and which is adapted to heat the heat exchanging part 120 by radiating a predetermined temperature heat in accordance with a control signal of the circuit part 112, (113).

The heat exchanging part 120 is provided inside the main body 110 to raise the fluid at a predetermined temperature or maintain a predetermined temperature.

3, the heat exchange unit 120 includes an inlet 122 through which the fluid enters, an outlet 124 through which the fluid is discharged, and an outlet 124 through which the fluid < RTI ID = 0.0 > And a spiral portion 126 for holding the spiral portion 126 at a predetermined temperature. In other words, the inlet 122 is formed at the lower end of the spiral portion 126, and the outlet 124 is formed at the upper end of the spiral portion 126, so that the fluid entering through the inlet 122 is moved upward while heat exchange is performed.

A heat dissipating plate 123 for dissipating heat generated in the circuit unit 112 of the main body 110 is formed at one side of the inlet 122. Thus, heat is exchanged with the fluid entering through the inlet 122 by preheating the inlet 122 by waste heat dissipating through the heat sink 123. Accordingly, the fluid entering the inlet 122 is subjected to the primary heat exchange by the heat sink 123.

The spiral portion 126 is formed in a spiral shape so as to be in close contact with the spiral portion 126 without spacing, thereby improving space utilization. That is, in the conventional case, the spirals are formed so as to have a certain interval in order to facilitate the heat exchange by the medium. However, in the case of the present invention, the spirals are formed without spacing, ) Is minimized and space utilization is improved.

The heat exchanging unit 120 is preferably made of a metal material containing a resistance component (magnetic material) so as to be heated by an induction heater (IH) method.

The winding unit 130 is provided in the heat exchanging unit 120 to heat the fluid passing through the heat exchanging unit 120 by heat. In this case, it is preferable that the winding unit 130 is configured to heat the fluid by heating the heat exchange unit 120 by an electromagnetic induction heating method.

The winding section 130 is composed of a coating layer 132, a coil layer 134, and a heat insulating layer 136 as shown in Fig.

The coating layer 132 is maintained between the spiral portion 126 of the heat exchanging portion 120 and the coil layer 134 so as to be spaced apart from each other by a predetermined distance so as to smoothly induce electromagnetic induction at the spiral portion 126 .

The coating layer 132 is made of a material that does not interfere with the occurrence of electromagnetic induction at the spiral portion 126 by the coil layer 134. In this case, the coating layer 132 is made of cloth, woven fabric, silicone, or the like.

The coil layer 134 is a means for receiving an alternating current and heating the heat exchanging part 120 by an electromagnetic induction heating method.

The heat insulating layer 136 prevents heat loss due to heat exchange caused by the convection phenomenon of the heat generated in the heat exchanging part 120 heated by the coil layer 134, .

The winding portion 130 may be formed so that the coating layer 132, the coil layer 134 and the heat insulating layer 136 are integrally formed or the heat exchanging portion 120 is formed in a state where the respective layers are separated, .

The winding unit 130 is configured to surround the outer periphery of the spiral portion 126 of the heat exchange unit 120. In this case, as shown in FIG. 3, the winding part 130 is preferably configured so as to surround the entire width direction along the circumference of the spiral part 126.

This is because the spiral portion 126 in the vertical direction is heated by the electromagnetic induction heating method by the coil layer 134 of the winding portion 130 wound along the width direction of the spiral portion 126, So that heat exchange efficiency can be improved by mutual heat exchange with the piping of the helix portion 126 by surface contact by close contact.

The temperature sensor 140 is a sensor for measuring the temperature of the fluid heated through the heat exchanging unit 120. It is preferable that the temperature sensor 140 is configured at one side of the outlet 124 of the heat exchanging unit 120 so as to quickly respond to the heating temperature of the fluid.

The operation state of the induction heating type fluid heater apparatus constructed as described above will be described below.

The winding part 130 is wound along the circumference of the spiral part 126 of the heat exchange part 120 and the heat radiation plate 123 is fixed to one side of the inlet 122 of the heat exchange part 120 . The heat sink 123 is connected to a circuit unit 112 provided inside the main body 110 to protect the circuit unit 112 by radiating heat generated from the circuit unit 112.

Subsequently, an AC current is applied to the coil layer 134 of the winding part 130 when the power switch 114 of the main body 110 is turned on and the temperature control switch 116 is adjusted .

An alternating magnetic field whose direction changes according to time is formed while passing through the coil layer 134. A swirling current (i.e., eddy current) is generated inside the heat exchanging part 120 formed of a resistance material by electromagnetic induction phenomenon, Lt; / RTI > Therefore, the heat exchanging unit 120 is heated by the heat generated by the spiral current.

The fluid entering through the inlet 122 of the heat exchanging unit 120 is heated by the electromagnetic induction heating method of the coil layer 134 to heat the helix 126 of the heat exchanging unit 120 So that the temperature rises to a certain temperature.

In addition, the spiral portion 126 is formed in a state in which the spiral portion 126 is in close contact with the spiral portion 126 without being spaced apart from each other, thereby improving the heat exchange efficiency as the pipes of the neighboring spiral portion 126 mutually exchange heat.

The switching element 113 for power control of the fluid heater device 100 also raises a constant temperature in accordance with the control signal of the circuit part 112 to heat the heat exchanging part 120. At this time, the power control switching element 113 is configured at one side of the inlet 122 of the heat exchanging unit 120 so as to heat the fluid before being heated. More preferably, the power control switching element 113 is attached to the heat sink 123 formed at the inlet 122 of the heat exchanger 120, and the waste heat due to the heat radiation of the heat sink 123, By heating the fluid entering through the inlet 122 by the heat generated by the heat source 113, the power efficiency used to heat the fluid is improved.

Therefore, the induction heating type fluid heater device of the present invention is not limited to the hermeticity of the device for maintaining the watertightness of the main body in which the medium is accommodated, by heat exchange of the fluid passing through the heat exchanging part by the electromagnetic induction heating method, The negative pipes are arranged to be in close contact with each other, thereby improving the space usability in which the volume of the apparatus can be minimized.

In addition, by providing a heat radiating plate for radiating heat generated in the circuit portion formed in the main body on one side of the inlet of the heat exchanging portion, the heat is heated by the heat radiation of the heat radiating plate to improve heat exchange efficiency and minimize energy consumption.

Meanwhile, the fluid heater device is not limited to maintaining the viscosity of the painted paint at a constant level, but may be used to maintain the drug at a predetermined temperature during pouring into the pouch pack. Any fluid may be used as long as it heats the fluid to maintain the temperature above or above a certain temperature.

≪ Embodiment 2 >

The same reference numerals are used for the same components as those in the first embodiment, and a detailed description thereof will be omitted.

As shown in Figs. 5 and 6, the induction heating type fluid heater apparatus 100 of the second embodiment includes a main body 110, a heat exchanging unit 120, and a winding unit 130, The heating unit 130 includes a coil layer 134 for heating the heat exchanging unit 120 by an induction heating method and a heat insulating layer 130 formed on the outer circumference of the heat exchanging unit 120 to prevent heat exchange with the outside 136).

The coil layer 134 includes a bobbin 1342 positioned inside the heat exchange unit 120 and a coil 1344 wound around the bobbin 1342.

The bobbin 1342 is provided inside the spiral part 126 of the heat exchanging part 120 to support the coil 1344.

The coil 1344 is wound around the bobbin 1342 and positioned inside the spiral portion 126 of the heat exchange unit 120. Accordingly, the fluid flowing through the heat exchanging unit 120 is induced by the magnetic field generated by the coil 1344.

The heat insulating layer 136 is provided on the outer circumference of the heat exchanging part 120 so that the heat of the fluid flowing inside the heat exchanging part 120 heated by the coil layer 134 is dissipated by heat exchange with the outside It blocks things. In this case, the heat insulating layer 136 is preferably configured such that the spiral portion 126 and the coil layer 134 of the heat exchanging portion 120 are wound as shown in FIG. Of course, the present invention is not limited thereto, and any structure may be used as long as the heat of the heat exchanging unit 120 is blocked from heat exchange with the outside.

≪ Third Embodiment >

The same reference numerals as those of the first and second embodiments are used, and a detailed description thereof will be omitted.

The coil layer 134 of the third embodiment is provided outside the heat exchanging part 120 as shown in Fig. At this time, the heat insulating layer 136 is formed inside the heat exchanging part 120 to prevent heat exchange with the outside.

That is, the coil layer 134 is in a state in which the bobbin 1342 is positioned outside the spiral portion 126 of the heat exchange unit 120 and the coil 1344 is wound around the outer circumference of the bobbin 1342 .

The coil layer 134 of the first embodiment is wound directly on the heat exchanging part 120 and the coil layer 134 of the second embodiment is wound on the heat exchanging part 120 using the bobbin 1342. [ And the coil layer 134 of the third embodiment is located outside the heat exchanging part 120 by using the bobbin 1342. The coil layer 134 may be variously changed depending on the shape of the heat exchanging part 120, .

The above description is only one embodiment for implementing the induction heating type fluid heater device, and the present invention is not limited to the above embodiment. It will be understood by those skilled in the art that various changes may be made without departing from the spirit of the invention.

100: fluid heater device 110: body
112: circuit part 120: heat exchange part
122: inlet 123: heat sink
124: outlet 126:
130: Winding part 132: Coating layer
134: coil layer 1342: bobbin
1344: coil 136: insulating layer

Claims (9)

A fluid heater apparatus (100) for heating a paint in a tank for storing paint and maintaining it at a predetermined temperature so as not to change the properties of the fluid,
A body 110;
A heat exchange unit 120 provided inside the main body 110 and forming a channel for guiding the flow of the fluid; And
And a winding part (130) closely attached to the heat exchanging part (120) and heating the heat exchanging part (120) by an electromagnetic induction heating method to heat the fluid passing through the heat exchanging part (120);
The body 110 is provided with a circuit unit 112 for controlling the apparatus;
A heat sink 123 for dissipating heat generated in the circuit unit 112 is formed at one side of the heat exchanging unit 120;
The heat generated by the circuit unit 112 is dissipated by the heat dissipating plate 123 and the fluid passing through the heat exchanging unit 120 is heated to improve heat exchange efficiency;
The heat exchanging unit 120 includes an inlet 122 through which fluid enters;
An outlet 124 through which the fluid is discharged; And
And a spiral portion 126 provided between the inlet 122 and the outlet 124 and spirally formed by a plurality of windings so as to be in close contact with each other so as to maximize the residence time of the fluid to improve the heat exchange efficiency, ;
The winding part (130) includes a coating layer (132) configured to surround the spiral part (126) along the entire circumference of the spiral part (126). And
A coil layer 134 formed on the coating layer 132 and heated by electromagnetic induction to the heat exchanging part 120 by an alternating current;
Wherein the fluid heater device comprises:
delete [3] The apparatus of claim 1,
A switching element 113 provided at one side of the heat exchanging part 120 and generating heat according to a control signal of the circuit part 112 to heat a fluid flowing through the heat exchanging part 120;
Further comprising: a fluid heater for heating the fluid.
delete delete delete [2] The apparatus of claim 1,
A heat insulating layer 136 formed on the outer periphery of the coil layer 134 to prevent heat loss from being generated due to heat exchange between the heat exchanging part 120 heated by the coil layer 134 and the outside;
Wherein the fluid heater device further comprises:
delete The coil according to claim 1, wherein the coil layer (134)
A bobbin 1342 provided at an outer circumference or an inner circumference of the heat exchange unit 120; And
A coil 1344 wound around the bobbin 1342 to generate a magnetic field to induction-heat the heat exchange unit 120;
Wherein the fluid heater device further comprises:

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