KR102352084B1 - Cooling-water heater - Google Patents

Abstract

The present invention relates to a cooling water heater, comprising: a body having an inlet pipe through which cooling water is introduced and an outlet pipe through which cooling water is discharged and disposed at an upper side thereof; a housing having a hollow interior and being coupled to the body to seal the hollow interior; an induction coil provided inside sealed by the body and the housing; a first heating element spaced apart from the inside of the induction coil, the first heating element being formed in a cylindrical shape and having open ends facing up and down; and a second heating element spaced apart from the induction coil and disposed in a cylindrical shape with both open ends facing up and down; and, after the coolant introduced into the inlet pipe flows in a downward direction so as to contact the inner and outer surfaces of the first heating element together, a U-turn from the bottom surface of the housing to the inner and outer surfaces of the second heating element The cooling water flow path is formed so that it flows upward so as to be in contact with the side surfaces and discharged to the outlet pipe, thereby improving the flow of the cooling water passing around the heating element, thereby reducing the pressure drop due to the flow of the cooling water, and heat exchange efficiency between the cooling water and the heating element It relates to a coolant heater that can improve the

Description

Cooling-water heater {Cooling-water heater}

The present invention relates to a cooling water heater, and in a cooling water heater for heating cooling water using a heating element generated by an induction coil, by improving the flow of cooling water passing around the heating element, the pressure drop due to the flow of the cooling water can be reduced, and the cooling water It relates to a cooling water heater capable of improving heat exchange efficiency between and a heating element.

A vehicle powered by an engine powered by gasoline or diesel as an energy source is currently the most common type of vehicle. As a bar that is gradually emerging, electric vehicles, hybrid vehicles, fuel cell vehicles, etc. are being put to practical use or under development.

However, in electric vehicles, hybrid vehicles, and fuel cell vehicles, a heating system using coolant cannot be applied or is difficult to apply, unlike conventional vehicles using an engine using petroleum as an energy source. That is, in the case of a conventional vehicle using an engine that uses petroleum as an energy source as a driving source, the engine generates a lot of heat, a coolant circulation system for cooling the engine is provided, and the heat absorbed by the coolant from the engine is heated to the room. to be used for However, since as much heat as generated from the engine is not generated from the driving sources of electric vehicles, hybrid vehicles, and fuel cell vehicles, there is a limit to using such a conventional heating method.

Accordingly, in electric vehicles, hybrid cars, and fuel cell vehicles, various studies have been made, such as adding a heat pump to the air conditioning system to use it as a heat source, or providing a separate heat source such as an electric heater. have. Among them, the electric heater is widely used because it can heat the cooling water more easily without significantly affecting the air conditioning system.

Here, the electric heater includes an air heating type heater that directly heats air blown into the interior of the vehicle, and a cooling water heating type heater (or cooling water heater) of a type that heats cooling water.

In a conventional induction type coolant heater that is used in a dual fuel cell vehicle to heat coolant, the high frequency generator 30 is electrically connected to the fuel cell stack 10 that generates power as shown in FIGS. 1 and 2 , and the high frequency generator (30) is formed in the form of a coil wound on the outside of the cooling water flow pipe (2) made of a magnetic metal material, and by using the power of the fuel cell stack (10) to flow an alternating current to the induction coil (31) by a changed magnetic field An eddy current is generated in the cooling water flow pipe 2, so that the cooling water flow pipe 2 can be heated by Joule heat, so that the cooling water passing through the inside of the cooling water flow pipe 2 can be heated.

However, in the conventional induction type cooling water heater, the cooling water flows only through the inside of the cooling water flow pipe and heat exchanges, and the cooling water flow pipe, which is a heating element that can be induction heated, is disposed only inside the induction coil, so the heating efficiency and heat exchange efficiency are low. have.

KR 2011-0075118 A1 (2011.07.06)

The present invention has been devised to solve the above problems, and an object of the present invention is to improve the flow of cooling water passing around the heating element in a cooling water heater that heats cooling water using a heating element generated by an induction coil. To provide a cooling water heater capable of reducing pressure drop due to the flow of cooling water and improving heat exchange efficiency between cooling water and a heating element.

The coolant heater 1000 of the present invention for achieving the above object includes a body 100 having an inlet pipe 110 through which coolant is introduced and an outlet pipe 120 through which coolant is discharged, which is disposed on the upper side; a housing 200 having a hollow inside and being coupled to the body 100 so that the hollow inside is sealed; an induction coil 300 provided inside sealed by the body 100 and the housing 200; a first heating element 400 spaced apart from the inside of the induction coil 300 and formed in a cylindrical shape so that both ends thereof face up and down; and a second heating element 500 spaced apart from the induction coil 300 and formed in a cylindrical shape so that both ends thereof face up and down; After the cooling water introduced into the inlet pipe 110 flows downward to contact the inner and outer surfaces of the first heating element 400 together, a U-turn is performed on the bottom surface of the housing 200 to It is characterized in that the cooling water flow path is formed so as to flow upward to contact the inner and outer surfaces of the second heating element 500 and to be discharged to the outlet pipe 120 .

In addition, the inlet pipe 110 and the outlet pipe 120, the body 100 is formed in a horizontal direction, so that the vertical central axis of the body 100 and the horizontal central axis of the inlet pipe 110 do not meet each other It is formed and characterized in that it is formed so that the vertical central axis of the body 100 and the horizontal central axis of the outlet pipe 120 do not meet each other.

In addition, the cooling water introduced through the inlet pipe 110 is rotated about the vertical central axis of the body 100 and flows into the lower housing 200 to generate a vortex, the body 100 . It is characterized in that the swirl forming portion is formed along the circumferential direction in the radial central portion of the.

In addition, the body 100 is connected to the inlet pipe 110, a horizontal inflow passage 111 is formed along the circumferential direction in the horizontal direction, and is formed vertically through the horizontal inflow passage 111 and the first 1 A vertical inflow passage 112 is formed so that the inside and outside of the heating element 400 communicate together, and the body 100 is connected to the outlet pipe 120 in the horizontal direction along the circumferential direction. It is characterized in that the discharge passage 121 and the vertical discharge passage 122 are formed through the vertical direction so that the horizontal discharge passage 121 and the inner and outer sides of the second heating element 500 communicate with each other. do.

In addition, it is characterized in that the discharge guide portion 123 is formed along the circumferential direction on the upper side of the horizontal discharge passage 121 is inclined upward toward the outlet pipe 120 is formed.

In addition, the center of the bottom surface of the housing 200 is convexly formed to protrude upward toward the center of the first heating element 400, and the periphery of the bottom surface of the housing 200 is formed in a round shape. .

In addition, the induction coil 300 further comprises a cylindrical formed bobbin 600 wound on the outside, the bobbin 600 has an open upper end coupled to the body 100, the upper periphery is sealed, The open lower end of the bobbin 600 is formed to be spaced apart from the bottom surface of the housing 200 so that the coolant can pass between the lower end of the bobbin 600 and the bottom surface of the housing 200. .

In addition, a plurality of support parts 610 formed in a radial direction and spaced apart from each other in the circumferential direction are formed at the lower end of the bobbin 600, so that the upper end of the bobbin 600 is coupled to the body 100 and the lower support portion ( 610 is supported on the bottom surface of the housing 200 , and the first heating element 400 and the second heating element 500 are fixedly fixed between the body 100 and the support part 610 .

In addition, coupling grooves 611 are formed in the support part 610 , and the lower ends of the first heating element 400 and the second heating element 500 are coupled to be inserted into the coupling groove 611 .

In addition, it is arranged to surround the induction coil (300), characterized in that it further comprises a coil cover (620) coupled to the bobbin (600).

In addition, the induction coil 300 is characterized in that the outer peripheral surface of the wire is a waterproof coil with insulation coating.

The cooling water heater of the present invention has the advantage of improving the flow of cooling water passing around the heating element, thereby reducing the pressure drop due to the flow of the cooling water, and improving the heat exchange efficiency between the cooling water and the heating element.

1 and 2 are schematic and cross-sectional views showing a conventional coolant heater.
3 and 4 are an assembled perspective view and an exploded perspective view showing the coolant heater of the present invention.
5 is a front cross-sectional view showing the coolant heater of the present invention.
6 and 7 are a perspective view and a plan view of the body according to the present invention viewed from the lower side.
8 is a perspective view showing a state in which the bobbin cover is coupled to the lower side of the body in FIG.

Hereinafter, the cooling water heater of the present invention having the configuration as described above will be described in detail with reference to the accompanying drawings.

3 is an assembled perspective view and an exploded perspective view showing the cooling water heater of the present invention, FIG. 5 is a front cross-sectional view showing the cooling water heater of the present invention, and FIGS. , FIG. 8 is a perspective view showing a state in which the bobbin cover is coupled to the lower side of the body in FIG. 6 .

As shown, the coolant heater 1000 of the present invention includes: a body 100 in which an inlet pipe 110 through which coolant is introduced and an outlet pipe 120 through which coolant is discharged are formed and disposed on the upper side; a housing 200 having a hollow inside and being coupled to the body 100 so that the hollow inside is sealed; an induction coil 300 provided inside sealed by the body 100 and the housing 200; a first heating element 400 spaced apart from the inside of the induction coil 300 and formed in a cylindrical shape so that both ends thereof face up and down; and a second heating element 500 spaced apart from the induction coil 300 and formed in a cylindrical shape so that both ends thereof face up and down; After the cooling water introduced into the inlet pipe 110 flows downward to contact the inner and outer surfaces of the first heating element 400 together, a U-turn is performed on the bottom surface of the housing 200 to A cooling water flow path may be formed so that it flows in an upward direction so as to be in contact with the inner and outer surfaces of the second heating element 500 and is discharged to the outlet pipe 120 .

First, the body 100 is a part that forms the outer shape of the coolant heater according to the present invention, and a flow path through which coolant is introduced and discharged is formed. That is, the inlet pipe 110 may be formed in the body 100 so that the coolant flows in, and the outlet pipe 120 may be formed so that the coolant is discharged, and the body 100 is connected to the inlet pipe 110 and the body 100 ) is formed to pass through, and also the discharge flow path is formed to pass through the body 100 so that the discharge flow path can be connected to the outlet pipe 120 .

The housing 200 together with the body 100 forms the outer shape of the coolant heater according to the present invention, so that the body 100 and the housing 200 are combined to seal the hollow inside of the housing 200 . can be formed. In this case, the body 100 may be disposed on the upper side and the housing 200 may be vertically coupled with the housing 200 disposed on the lower side. In addition, the housing 200 may have a hollow interior and an open upper side so that the open upper periphery of the housing 200 coupled to the body 100 may be sealed, and accordingly, the inlet and outlet channels formed in the body 100 . may communicate with the hollow interior of the housing 200 . In addition, a sealing member may be interposed on the surface where the body 100 and the housing 200 are contacted and coupled to seal the contact surface.

The induction coil 300 may be provided inside the housing 200 sealed by the coupling of the body 100 and the housing 200 . Here, the induction coil 300 is wound a plurality of times in the circumferential direction to form a coil spring in close contact in the vertical direction, and may be formed in a spiral shape around the vertical direction. Thus, the induction coil 300 may have a cylindrical shape, and may be disposed so that both open sides face up and down. In addition, the induction coil 300 may be formed such that extension lines extending upward from the wound portion of the coil are drawn out through the body 100, and the extension lines are formed on one side of the body 100. Control unit 700 can be electrically connected to

In addition, the induction coil 300 may have an upper end coupled to the body 100 so that the combined upper periphery may be sealed, and the lower end of the induction coil 300 may be supported to be spaced apart from the bottom surface of the housing 200 . At this time, the upper end of the induction coil 300 is disposed to partition between the inflow passage and the exhaust passage formed in the body 100 , so that the coolant introduced through the inflow passage does not pass to the upper end of the induction coil 300 , and the induction The cooling water may be configured to pass only through the lower end of the coil 300 . That is, when viewed from the top, the inflow channels connected to the inlet pipe 110 of the body 100 are formed inside the induction coil 300 in a radial direction, and the discharge channels connected to the outlet pipe 120 are radially induction Cooling water formed on the outside of the coil 300 and introduced into the inlet pipe 110 flows downward while passing through the inside of the induction coil 300, makes a U-turn at the lower end of the induction coil 300, and then the induction coil 300. It is configured to flow upward while passing through the outside of the outlet pipe 120 to be discharged.

Here, the first heating element 400 and the second heating element 500 capable of induction heating by the induction coil 300 may be provided inside the housing 200 . In this case, the first heating element 400 may be provided to be spaced apart from the inside of the induction coil 300 , and the second heating element 500 may be provided to be spaced apart from the outside of the induction coil 300 . In addition, the first heating element 400 and the second heating element 500 are formed of a cylindrical metal or a magnetic material, and when an alternating current flows through the induction coil 300 , the first heating element 400 and the second heating element 500 . An eddy current may be generated to heat the first heating element 400 and the second heating element 500 .

In addition, the first heating element 400 may be disposed to be spaced apart from the inside of the induction coil 300 , and may be disposed so that both ends of the cylindrical open end face up and down. At this time, the upper end of the first heating element 400 may be coupled to the body 100 and connected to the inflow passage connected to the inlet pipe 110 , and the introduced cooling water may flow inside and outside the first heating element 400 together. So that the first heating element 400 may be connected to the inflow passage.

In addition, the second heating element 500 may be disposed to be spaced apart from the outside of the induction coil 300 , and may be disposed so that both ends of the cylindrical shape are opened in the vertical direction. At this time, the upper end of the second heating element 500 may be coupled to the body 100 and connected to the discharge passage connected to the outlet pipe 120 , and the cooling water flows to the inside and the outside of the second heating element 500 together and then discharged. The second heating element 500 may be connected to the discharge flow path so that it can be merged in the flow path and discharged through the outlet pipe 120 .

Thus, the cooling water introduced into the inlet pipe 110 passes through the inflow passage and flows downward along the inside of the induction coil 300 , so that the cooling water comes into contact with the inner and outer surfaces of the first heating element 400 . While flowing in the downward direction, it is possible to primarily heat exchange with the coolant at the inside and outside of the first heating element 400 to be heated. And the cooling water flowing downward and passing around the first heating element 400 makes a U-turn based on the lower end of the induction coil 300 to change the flow in the upward direction, and the cooling water flowing in the upward direction is the second heating element 500 . While flowing in the upward direction so as to be in contact with the inner and outer surfaces of the second heating element 500, heat exchange with the cooling water may be secondarily generated on the inside and outside of the heated second heating element 500 at the same time. Thereafter, the cooling water may be discharged to the outside through the outlet pipe 120 through the discharge passage.

As described above, in the cooling water heater of the present invention, the flow of cooling water passing around the heating element is improved according to the configuration of the cooling water flow path as described above, thereby reducing the pressure drop due to the flow of the cooling water, and improving the heat exchange efficiency between the cooling water and the heating element. There are advantages that can be

In addition, as shown, the inlet pipe 110 and the outlet pipe 120 are formed in a horizontal direction perpendicular to the vertical central axis of the body 100, the vertical central axis of the body 100 and the inlet pipe 110 ) may be eccentrically formed so that the horizontal central axis of the body 100 does not meet each other, and the vertical central axis of the body 100 and the horizontal central axis of the outlet pipe 120 do not meet each other. At this time, in the inflow path connected to the inlet pipe 110 , the introduced cooling water flows into the lower housing 200 while rotating about the vertical central axis to generate a vortex in the radial direction of the body 100 . A swirl forming portion may be formed along the circumferential direction to have a sufficient space in the central portion.

Thus, more effective heat exchange occurs between the cooling water and the heating elements by causing a vortex to be generated in the incoming cooling water and the discharged cooling water, thereby improving heat exchange efficiency.

Here, the swirl forming part is an inlet pipe 110 formed so that the horizontal central axis does not meet the vertical central axis of the body 100, a connection passage connecting the inlet pipe 110 and the horizontal inflow passage 111, and The horizontal direction may include a horizontal inflow passage 111 . In addition, the swirl forming part may be formed in various shapes so that a vortex may occur while the coolant introduced in the horizontal direction flows downward in the vertical direction. In addition, in the discharge flow path connected to the outlet pipe 120 , the cooling water discharged from the inside of the housing 200 rotates and passes through the upper discharge flow path to be discharged through the outlet pipe 120 in the circumferential direction. It may be formed to be long.

In addition, the body 100 is connected to the inlet pipe 110, a horizontal inflow passage 111 is formed along the circumferential direction in the horizontal direction, and is formed vertically through the horizontal inflow passage 111 and the first 1 A vertical inflow passage 112 is formed so that the inside and outside of the heating element 400 communicate together, and the body 100 is connected to the outlet pipe 120 in the horizontal direction along the circumferential direction. The discharge passage 121 and the vertical discharge passage 122 may be formed to penetrate in the vertical direction so that the horizontal discharge passage 121 and the inner and outer sides of the second heating element 500 communicate with each other.

That is, a vortex is generated in the body 100 while the coolant introduced through the inlet pipe 110 is rotated to easily flow into the interior of the housing 200, and the horizontal inflow passage 111 along the circumferential direction in the horizontal direction. is formed and the vertical inflow passage 112 in the vertical direction is formed so as to be connected to the horizontal inflow passage 111. As the cooling water flows along the horizontal inflow passage 111 and rotates, it flows in the downward direction and flows spirally. while being able to pass through the inside and outside of the first heat generating agent 400 together. In addition, a vertical discharge flow path 122 is formed in the body 100 so that the coolant flowing upward while passing both the inside and the outside of the second heating element 500 is rotated in the circumferential direction to flow spirally. The horizontal discharge flow path 121 is formed along the circumferential direction in the horizontal direction so as to be connected to the vertical discharge flow path 122 , and may be connected to the outlet pipe 120 .

In addition, a discharge guide portion 123 formed along the circumferential direction and inclined upward toward the outlet pipe 120 may be formed on the upper side of the horizontal discharge passage 121 .

That is, the spiral discharge guide part 123 formed along the circumferential direction in an inclined shape is formed on the upper side of the horizontal discharge flow path 121, and the cooling water flowing upward and passing around the second heating element 500, It can be made to flow easily in the form of a spiral that flows upward while being rotated.

In addition, the center of the bottom surface of the housing 200 may be convexly formed to protrude upward toward the center of the first heating element 400 , and the circumference of the bottom surface of the housing 200 may be formed in a round shape.

That is, as shown in FIG. 5 , the cooling water that has passed around the first heating element 400 while flowing downward makes a U-turn at the lower end of the induction coil 300 to easily change the flow direction to the upper side, the bottom surface of the housing 200 . The central portion may be formed in a shape protruding convexly upward and may be formed in a round shape in which the circumference of the bottom surface is curved.

In addition, the induction coil 300 is made to further include a cylindrical bobbin 600 wound on the outside, the open top of the bobbin 600 is coupled to the body 100, the upper periphery is sealed, the The open lower end of the bobbin 600 may be formed to be spaced apart from the bottom surface of the housing 200 so that cooling water may pass between the lower end of the bobbin 600 and the bottom surface of the housing 200 .

That is, by winding the induction coil 300 around the cylindrical bobbin 600 , the induction coil 300 can be arranged in a desired shape at a desired position inside the housing 200 so that it can be easily fixed. In addition, the upper end of the bobbin 600 may be coupled to the body 100 so that the bobbin 600 is disposed between the inflow passage and the exhaust passage when viewed from the upper side. In addition, the upper end of the cylindrical bobbin 600 is coupled to the body 100 so that the upper periphery is sealed, and the lower end of the bobbin 600 is spaced apart from the bottom surface of the housing 200 to form a cooling passage, the inlet pipe 110 ), the coolant introduced through the inner side of the bobbin 600 passes in the downward direction, makes a U-turn at the lower end of the bobbin 600 , and then passes through the outer side of the bobbin 600 upwards and the coolant is discharged through the outlet pipe 120 . flow can be formed.

In addition, a plurality of support parts 610 formed in a radial direction and spaced apart from each other in the circumferential direction are formed at the lower end of the bobbin 600, so that the upper end of the bobbin 600 is coupled to the body 100 and the lower support portion ( 610 is supported on the bottom surface of the housing 200 , and the first heating element 400 and the second heating element 500 may be fixed in close contact with the body 100 and the support part 610 .

That is, as shown, the lower side of the bobbin 600 may be supported on the bottom surface of the housing 200 by the support parts 610 radially formed at the lower end of the bobbin 600 , and also between the support parts 610 . Since the space may be formed as a flow path through which the cooling water may pass, the cooling water may be easily U-turned at the lower end of the bobbin 600 . At this time, the support parts 610 may be formed in various shapes, but as shown, they are formed in a vertical plate shape, protrude downward from the lower end of the cylindrical bobbin 600, and extend radially inwardly and outwardly. Positioning of 600 may be easily fixed.

In this case, coupling grooves 611 are formed in the support part 610 , and the lower ends of the first heating element 400 and the second heating element 500 may be coupled to be inserted into the coupling groove 611 .

That is, a plurality of coupling grooves 611 are formed in a concave shape on the upper side of the support parts 610, so that the lower ends of the first heating element 400 and the second heating element 500 having different diameters correspond to the coupling grooves 611. ) by being inserted and coupled to the first heating element 400 and the second heating element 500 can be easily fixed, the first heating element 400 and the bobbin 600 can be coupled to have a constant distance, and the second The heating element 500 and the bobbin 600 may be coupled to have a constant interval. In this case, the support part 610 may be formed integrally with the bobbin 600 or may be formed as a separate type and coupled thereto.

In addition, the coil cover 620 is disposed to surround the induction coil 300 and coupled to the bobbin 600 may be further included.

That is, the bobbin 600 is disposed inside the induction coil 300 and the coil cover 620 is disposed outside the induction coil 300 , so that the induction coil 300 is a first heating element 400 or a second heating element. By preventing direct contact with the 500 , it is possible to prevent damage to the induction coil 300 and a short circuit.

In addition, a bobbin cover 630 coupled to the upper side of the bobbin 600 may be further included.

That is, after assembling or inserting the first heating element 400, the induction coil 300, the coil cover 620 and the second heating element 500 into the bobbin 600, the bobbin cover ( 630), the first heating element 400, the induction coil 300, the coil cover 620 and the second heating element 500 are fixed between the support part 610 and the bobbin cover 630 on the lower side of the bobbin 600. can be In addition, the bobbin cover 630 may have a vertical inflow passage 112 and a vertical discharge passage 122 formed therein. At this time, only the horizontal inflow passage 111 and the horizontal discharge passage 121 are formed in the body 100, and the vertical inflow passage 112 and the vertical discharge passage 122 are formed in the bobbin cover 630, A bobbin cover 630 may be coupled to the lower end of the body 100 . Thus, by allowing the bobbin cover 630 to be coupled to the body 100 , the vertical inflow passage 112 connected to the horizontal inflow passage 111 and the vertical discharge passage 122 connected to the horizontal discharge passage 121 . ) can be easily formed.

Also, the induction coil 300 may be a waterproof coil in which an outer circumferential surface of the wire is coated with insulation. That is, since the induction coil 300 flows through current, the outer circumferential surface of the wire is formed of a waterproof coil with an insulation coating, so that even when the induction coil 300 comes into contact with the coolant, a short circuit does not occur. It does not need to be molded to contact or sealed to facilitate construction and placement.

And as shown, the control unit 700 may be formed on the upper side of the body 100 . At this time, the control unit 700 may have a control case 710 coupled to the body 100 or may be formed integrally with the body 100, and the control case 710 may have a hollow interior and an open top. The substrate 720 and the electronic device 730 may be provided and fixed therein, and the upper cover 740 may be coupled to the open upper side of the control case 710 . In addition, the electronic elements 730 are coupled to be in close contact with the bottom surface of the control case 710 so that the electronic elements 730 that generate a lot of heat exchange heat with the cooling water passing through the body 100 so that the electronic elements 730 are not overheated. can prevent it

The present invention is not limited to the above-described embodiments, and the scope of application is varied, and anyone with ordinary knowledge in the field to which the present invention pertains without departing from the gist of the present invention as claimed in the claims It goes without saying that various modifications are possible.

1000: coolant heater
100: body
110: inlet pipe 111: horizontal inflow path
112: vertical inflow path
120: outlet pipe 121: horizontal discharge flow path
122: vertical discharge flow path 123: discharge guide part
200: housing
300: induction coil
400: first heating element
500: second heating element
600: bobbin
610: support 611: coupling groove
620: coil cover 630: bobbin cover
700: control unit
710: control case 720: board
730: electronic device 740: upper cover

Claims (8)

a body 100 having an inlet pipe 110 through which the cooling water is introduced and an outlet pipe 120 through which the cooling water is discharged, which is disposed on the upper side;
a housing 200 having a hollow inside and being coupled to the body 100 so that the hollow inside is sealed;
an induction coil 300 provided inside sealed by the body 100 and the housing 200;
a first heating element 400 spaced apart from the inside of the induction coil 300 and formed in a cylindrical shape so that both ends thereof face up and down; and
a second heating element 500 spaced apart from the induction coil 300, formed in a cylindrical shape, and disposed so that both ends thereof face up and down; includes,
After the coolant introduced into the inlet pipe 110 flows downward to contact the inner and outer surfaces of the first heating element 400 together, it makes a U-turn on the bottom surface of the housing 200 to make a U-turn to the second heating element. The cooling water heater, characterized in that the cooling water flow path is formed so as to flow in the upward direction so as to be in contact with the inner and outer surfaces of the 500 and discharged to the outlet pipe (120).
According to claim 1,
The inlet pipe 110 and the outlet pipe 120 are formed in a horizontal direction of the body 100, so that the vertical central axis of the body 100 and the horizontal central axis of the inlet pipe 110 do not meet each other, The cooling water heater, characterized in that the vertical central axis of the body (100) and the horizontal central axis of the outlet pipe (120) do not meet each other.
According to claim 1,
Radius of the body 100 so that the coolant introduced through the inlet pipe 110 flows into the lower housing 200 while rotating about the vertical central axis of the body 100 to generate a vortex Cooling water heater, characterized in that the swirl forming portion is formed along the circumferential direction in the central portion of the direction.
According to claim 1,
The body 100 has a horizontal inflow passage 111 that is connected to the inlet pipe 110 and is formed along the circumferential direction in the horizontal direction, and is vertically penetrating through the horizontal inflow passage 111 and the first heating element. A vertical inflow passage 112 is formed so that the inner and outer sides of the 400 communicate with each other,
The body 100 has a horizontal discharge flow path 121 that is connected to the outlet pipe 120 and is formed along the circumferential direction in the horizontal direction, and is formed vertically through the horizontal discharge flow path 121 and the second heating element. A cooling water heater, characterized in that a vertical discharge flow path (122) is formed so that the inside and outside of the 500 communicate together.
5. The method of claim 4,
The cooling water heater according to claim 1, wherein a discharge guide portion 123 formed along the circumferential direction and inclined upward toward the outlet pipe 120 is formed on the upper side of the horizontal discharge passage 121.
According to claim 1,
The center of the bottom surface of the housing 200 is convexly formed to protrude upward toward the center of the first heating element 400, and the circumference of the bottom surface of the housing 200 is formed in a round shape. .
According to claim 1,
The induction coil 300 is formed so that the upper end is coupled to the body 100, the combined upper circumference is sealed, and the lower end is spaced apart from the bottom surface of the housing 200,
The cooling water heater, characterized in that the upper end of the first heating element (400) and the second heating element (500) is coupled to the body (100) and the lower end is formed to be spaced apart from the bottom surface of the housing (200).
8. The method of claim 7,
The induction coil 300 is made to further include a cylindrical bobbin 600 wound on the outside,
The open upper end of the bobbin 600 is coupled to the body 100 to seal the upper end thereof, and the open lower end of the bobbin 600 is formed to be spaced apart from the bottom surface of the housing 200 to form the bobbin 600 . Cooling water heater, characterized in that it is formed so that the coolant can pass between the lower end of the housing and the bottom surface of the housing (200).

Images