KR102483576B1 - Ion heater for fluid heating - Google Patents

Abstract

The present invention relates to an ion heater for heating a fluid, and more particularly, to an ion heater for heating a fluid by ionizing a fluid through electrical and thermal vibrations.
In the ion heater for heating fluid according to an embodiment of the present invention, an inlet through which fluid is supplied is installed on one side of the lower part, an outlet through which fluid is discharged is installed on one side of the upper part, and a predetermined space through which the fluid flows is formed therein. A body portion, a support portion installed under the body portion to support the body portion, a plurality of metal rods extending through the support portion and extending to the top of the body portion, and installed inside the body portion, the plurality of metal rods and A plurality of metal diaphragms connected to each other and disposed at a predetermined interval, vibrating when power is supplied to generate bubbles according to ionization in the fluid to heat the fluid, and a current supply unit connected to a metal rod protruding from the lower part of the support to supply current include

Description

Ion heater for fluid heating {Ion heater for fluid heating}

The present invention relates to an ion heater for heating a fluid, and more particularly, to an ion heater for heating a fluid by ionizing the fluid through electrical and thermal vibration inside a plurality of diaphragms.

Unless otherwise indicated herein, material described in this section is not prior art to the claims in this application, and inclusion in this section is not an admission that it is prior art.

A hot water system used in industry, industry, or home uses a heating method by a boiler, and a pipe is installed on the indoor floor, and heat is supplied while water heated by the boiler circulates through the pipe. These boilers are classified into oil boilers, gas boilers, electric boilers, etc. according to the energy source used, and classified into heat pump type or heat heating type boilers according to the heating method. Recently, energy-saving boilers that can increase thermal efficiency or save hot water costs through an efficient heating method are continuously being developed.

Among them, the heat-heating boiler is a method in which a heating element directly heats a medium (typically water) to be heated. The heating element includes a sheath heater or a PTC, which is a kind of semiconductor element. Here, the sheath heater is made by enclosing a heating wire together with an insulator in a pipe made of stainless steel, etc. It is widely used for direct heating. The heating element of the heat heating type boiler as described above is called a rod-shaped heater and is called a heater rod, and heat is generated according to electrical resistance generated by supplying current to a heating wire installed inside the heater rod to heat water.

However, in the case of the heating method using the heater rod as described above, firstly supplying current to the heater rod to heat the heater rod itself, and then heating the water by the heater rod, so that heat is generated rather than directly heating the water. There is a disadvantage of low efficiency, which results in economic loss.

1. Korean Patent Publication No. 10-2016-0035904 (published on April 1, 2016)

The present invention relates to an ion heater for heating a fluid by ionizing a fluid through a metal vibrator having a polygonal truncated pyramid shape to generate electrical and thermal vibrations to heat the fluid.

In addition, it is not limited to the technical problems as described above, and it is obvious that other technical problems may be derived from the following description.

In the ion heater for heating fluid according to an embodiment of the present invention, an inlet through which fluid is supplied is installed on one side of the lower part, an outlet through which fluid is discharged is installed on one side of the upper part, and a predetermined space through which the fluid flows is formed therein. A body portion, a support portion installed under the body portion to support the body portion, a plurality of metal rods extending through the support portion and extending to the top of the body portion, and installed inside the body portion, the plurality of metal rods and A plurality of metal diaphragms connected to each other and disposed at a predetermined interval, vibrating when power is supplied to generate bubbles according to ionization in the fluid to heat the fluid, and a current supply unit connected to a metal rod protruding from the lower part of the support to supply current include

In the present invention, the metal diaphragm has a triangular truncated or quadrangular truncated shape with upper and lower portions open and a diameter narrowing toward the upper portion.

In the present invention, a fixing flange is formed to protrude from the lower portion of the metal diaphragm and is fixed to a predetermined position of the metal rod passing through.

In the present invention, the metal diaphragm is formed of a quadrangular pyramid, the fixing flange is installed on each side of the lower part of the quadrangular pyramid, and the plurality of metal diaphragms are arranged in an even number and arranged in a row, and the fixing flange is spaced at 180° intervals. are intersected

In the present invention, the metal diaphragm is made of a triangular prism, the fixing flange is installed on each side of the lower part of the triangular prism, and the metal diaphragm is made up of a plurality of pieces and is arranged in a row, and the fixing flange is arranged at an interval of 120 °. do.

In the present invention, an anti-vibration pad is installed in connection with the metal rod at the top or bottom of the metal diaphragm and is closely accommodated in the main body to block vibration of the metal rod.

In the present invention, the anti-vibration pad includes a first anti-vibration pad installed between the inlet part and the metal diaphragm, and a second anti-vibration pad installed between the outlet part and the metal diaphragm.

In the present invention, an open hole is formed at the center of the first anti-vibration pad and the second anti-vibration pad, and the first open hole of the first anti-vibration pad has a smaller diameter than the second open hole of the second anti-vibration pad. can have

In the present invention, in the metal diaphragm formed of a quadrangular prism, the length of one side of the upper quadrangle forming the upper opening of the quadrangular prism is made of (1/5.5 * length of one side of the lower quadrangle forming the lower opening), The length of the side hypotenuse is (2/3 * the length of one side of the lower quadrangle), and the interval between the plurality of metal diaphragms is (1/5.5 * the length of one side of the lower quadrangle).

In the present invention, in the metal diaphragm formed of a triangular pyramid, the length of the opposite side of the upper opening of the triangular pyramid is (1/5.5 * length of the opposite side of the lower opening), and the length of the side hypotenuse is (2/3 * lower opening) length of the opposite side), and the interval between the plurality of metal oscillation plates is made of (1/5.5 * length of the opposite side of the lower opening).

In an ion heater for heating fluid according to another embodiment of the present invention, an inlet through which fluid is supplied is installed on one side of the lower part, an outlet through which fluid is discharged is installed on one side of the upper part, and a predetermined space in which fluid flows therein. A body portion formed thereon, a support portion installed on the upper portion of the body portion and coupled to the body portion, a plurality of metal rods extending through the support portion and extending to the lower portion of the body portion, and installed inside the body portion, and the plurality of Connected to two metal rods and arranged at a predetermined interval, connected to a plurality of metal diaphragms that heat the fluid by generating bubbles due to ionization in the fluid by vibrating when power is supplied, and a metal rod protruding from the upper part of the support to supply current It includes a current supply unit.

In the present invention, the metal diaphragm has a triangular truncated or quadrangular truncated shape with upper and lower portions open and a diameter narrowing toward the upper portion.

In the present invention, a fixing flange is formed to protrude from the lower portion of the metal diaphragm and is fixed to a predetermined position of the metal rod passing through.

In the present invention, the support portion protrudes at a predetermined height from both sides, and includes a lower protrusion support portion and an upper protrusion support portion having a smaller diameter than the support portion, and a screw thread is formed along the outer surface of the lower protrusion support portion and the upper protrusion support portion, The upper protruding support portion is screwed to the body portion, and further includes a cover portion screwed to the lower protruding support portion.

In the present invention, a lower protruding support part and an upper protruding support part protruding from one side of the support part at a predetermined height and having a smaller diameter than the support part, and one end of the body part protrudes outward for a predetermined length to enter the upper protrusion support part. coupled, and further comprising a lower ring surrounding the outer surface of the lower protruding support portion, wherein the lower ring, the support portion, and the outer portion of the body portion are integrally coupled.

In the present invention, it is installed on one side of the side of the main body and further includes a thermometer for measuring the temperature of the fluid inside and a control unit for controlling the temperature of the fluid inside the main body.

According to an embodiment of the present invention, the fluid is heated by electrical vibration and thermal vibration by ionizing the fluid through a metal vibrator having a polygonal truncated pyramid shape, rather than a heating method using a heater rod, so that the fluid is heated without a separate heating element. It has the advantage of being heated.

In addition, according to the embodiment of the present invention, as the fluid itself is heated, there is an advantage in that heat generation efficiency is higher than that of the conventional heater rod method and energy can be saved.

In addition, according to an embodiment of the present invention, a resonance phenomenon occurs between a plurality of metal diaphragms, and as the fluid is ionized, more heat than input energy can be output.

In addition, according to the embodiment of the present invention, the current supply unit may be made of an inverse structure connected to the metal rod not only from the bottom but also from the top, so there is an advantage that selective use is possible according to need.

In addition, according to the embodiment of the present invention, since the metal rods are configured in various embodiments such as 4, 6, 9, etc., there is an advantage in that the heating effect of the fluid from the current supply unit connected thereto can be further increased.

The effects of the present invention are not limited to the above effects, and should be understood to include all effects that can be inferred from the detailed description of the present invention or the configuration of the invention described in the claims.

1 is an exploded perspective view of an ion heater for heating fluid according to an embodiment of the present invention.
2 is a schematic diagram of a state in which water molecules are ionized between metal diaphragms and a metal diaphragm composed of a quadrangular prism and a triangular prism in an ion heater for fluid heating according to an embodiment of the present invention.
Figure 3 is an exploded perspective view of an ion heater for heating fluid according to another embodiment of the present invention.
Figure 4 is an exploded perspective view of an ion heater for fluid heating according to another embodiment of the present invention.
Figure 5 is an exploded perspective view of an ion heater for fluid heating according to another embodiment of the present invention.
Figure 6 is an exploded perspective view of an ion heater for fluid heating according to another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, look at the configuration, operation and effect of the ion heater for heating fluid according to a preferred embodiment. For reference, in the drawings below, each component is omitted or schematically illustrated for convenience and clarity, and the size of each component does not reflect the actual size. In addition, like reference numerals refer to like components throughout the specification, and reference numerals for like components in individual drawings will be omitted.

1 shows an exploded perspective view of an ion heater for heating fluid according to an embodiment of the present invention, and FIG. 3 shows an exploded perspective view of an ion heater for heating fluid according to another embodiment of the present invention.

In the ion heater for heating fluid according to an embodiment of the present invention, the inlet 11 through which fluid is supplied is installed on one side of the lower part, and the outlet 13 through which fluid is discharged is installed on one side of the upper part, and the fluid inside is installed on one side of the lower part. A main body portion 10 in which a predetermined space in which a flow is formed, a support portion 20 installed below the body portion 10 to support the body portion 10, and a main body through the support portion 20 A plurality of metal rods 21 extending to the top of the unit 10 and installed inside the main body 10, connected to the plurality of metal rods 21 and spaced apart at predetermined intervals, vibrating when power is supplied It includes a plurality of metal diaphragms 30 that generate bubbles according to ionization in the fluid to heat the fluid, and a current supply unit 40 that supplies current by being connected to a metal rod 21 that has passed through the lower portion of the support unit 20. .

The body portion 10 extends in a vertical direction and may have a cylindrical shape in which a predetermined space is formed therein, and is configured such that a fluid such as water can flow in and out of the inside. An inlet 11 is installed so that fluid can be continuously supplied from one lower side of the main body 10, and then a discharge unit formed on one upper side of the main body 10 is heated through the metal diaphragm 30. As it is discharged through (13), the fluid circulates. The discharge part 13 is formed on the upper side in FIG. 1, but is not limited thereto and may be formed on the upper side.

Next, a support part 20 installed under the main body part 10 to support the main body part 10 may be further included. The support part 20 may be formed in a disk shape having a larger diameter than the diameter of the main body part 10, and serves to support the main body part 10 from the lower part. In addition, the support part 20 may have a plurality of openings through which a plurality of metal rods 21 pass through, which is preferably formed at a position where it can be inserted into the fixing flange 31 of the metal diaphragm 30 to be described later. Do.

In the present invention, a first leg portion 80 extending from the outer portion of the lower surface of the support portion 20 is included, but the diameter of the first leg portion 80 increases toward the lower portion.

In order to compensate for the fact that it cannot be stably supported from the ground by the metal rod 21 penetrating the support part 20, the first leg part 80 extending from the lower surface of the support part 20 to the ground can include more. The first leg portion 80 is preferably composed of three or more along the outer circumference, and is made to increase in diameter toward the bottom so that the ion heater for heating the fluid can be supported more stably.

FIG. 2 shows a state diagram in which water molecules are ionized between metal diaphragms in an ion heater for heating fluid according to an embodiment of the present invention and a schematic diagram of a metal diaphragm composed of a quadrangular prism and a triangular prism.

Next, a plurality of metal diaphragms 30 installed inside the main body 10, connected to the plurality of metal rods 21 and spaced apart from each other by a predetermined interval, and metal rods passing through the lower part of the support part 20 A current supply unit 40 connected to (21) to supply current may be further included.

The metal diaphragm 30 may have a structure in which a plurality, preferably 4, 6, or 9 are arranged side by side at a predetermined interval, and connected to the metal rod 21 to be supported inside the main body 10. can The current supply unit 40 is composed of a + electrode and a - electrode to supply current from an external power source, and is connected to the metal bar 21 to supply current.

The supply of current can be single-phase or three-phase, and in the case of single-phase, four support parts 20 can be used, and it is preferable that at least four metal diaphragms 30 are used as a basic configuration, and depending on the temperature, 2 It can also be incremented by an even number. In addition, in the case of three-phase, 6 or 9 supporters 20 may be used, and it is preferable that at least 6 metal diaphragms 30 are used, and 9, 12, 15, etc. may be increased by 3 depending on the temperature. there is. As an example thereof, as shown in FIG. 6, nine metal diaphragms 30 having a triangular truncated shape are arranged side by side at a predetermined interval, and as the number of these metal diaphragms 30 increases, the fluid The heating effect can be increased. Therefore, current is supplied to the metal diaphragm 30 through the metal rod 21 connected to the current supply unit 40, and the plurality of metal diaphragms 30 are spaced apart from each other at a predetermined interval. As water is ionized into positive ions and negative ions and moves between the metal vibrating plates 30 dozens of times per second, heat is generated through mutual friction between water molecules. A more detailed description of this is as follows.

First, alternating current (AC) or direct current (DC) exists as a method of supplying current through the current supply unit 40 . First of all, in the case of supplying current in an alternating current (AC) method, the voltage may vary in the range of 100 to 420V, and AC power supplied to homes in Korea is usually 220V and 60Hz. Here, in the case of 60Hz, the fluid is ionized while the current direction is changed 60 times per second, so that the metal diaphragm 30 generates electrical vibration to heat the fluid, and in the case of 50Hz, the ionized water is 50 times per second. As the molecules move between the metal diaphragms 30, the fluid is heated. In addition, when current is supplied in a direct current (DC) method, as the current value increases, the wavelength increases and the amount of ions generated by ionization of water molecules may further increase.

The principle of the metal diaphragm 30 is that as current is supplied, the water supplied therein is rapidly electrolyzed, expanding at high pressure into oxygen and hydrogen bubbles, causing high-temperature vortex cavitation (vortex cavitation), and recombine again to change into water and electrically As vibration and thermal vibration occur, more heat (approximately 120 to 150% more heat) than the initial input energy is output. When the metal diaphragm 30 as described above is used, water itself becomes a medium and heat is generated, compared to a conventional method of heating using a medium called a heater rod (a method of heating water with indirect heat by directly heating a metal resistor). Compared to the heating method used in conventional ion electric boilers (a method in which electricity is directly supplied to water with electrodes, electrolytic water is ionized and heat is generated through mutual friction between water molecules), electrolytic water is not required and supply Since the water itself generates heat, it is more efficient, and even when there is no water inside the heating device, there is an advantage that there is no risk of fire because the water itself serves as a medium. In other words, as the water itself generates heat without a separate heating medium, the heating efficiency can be increased by outputting a much higher heat output than the heating efficiency of the ion electric boiler, and the annual operating cost can be reduced by 30 compared to many heater rod electric boilers of the same class. It has the advantage of being able to save ~50% or more. In addition, although problems such as destruction or corrosion due to hardening may occur as the heater rod is continuously used inside the boiler, it has the advantage that it can be used semi-permanently without the above problems.

In the present invention, the metal diaphragm 30 has a triangular truncated pyramid shape or quadrangular truncated pyramid shape with upper and lower portions open and a diameter narrowing toward the upper portion.

The metal diaphragm 30 is composed of a plurality of pieces, and the water is heated by an ionization process occurring between them. It can be easily introduced, and the heated water can be easily discharged to the top.

In the present invention, in the metal diaphragm 30 made of a quadrangular truncated pyramid, the length of one side of the upper quadrangle forming the upper opening of the quadrangular prism is (1/5.5 * the length of one side of the lower quadrangular forming the lower opening) The length of the side hypotenuse is (2/3 * the length of one side of the lower quadrangle), and the interval between the plurality of metal diaphragms is (1/5.5 * the length of one side of the lower quadrangle) , In the present invention, in the metal diaphragm 30 made of a triangular frustum, the length of the opposite side of the upper opening of the triangular frustum is (1/5.5 * length of the opposite side of the lower opening), and the length of the side hypotenuse is (2/ 3 * the length of the opposite side of the lower opening), and the interval between the plurality of metal oscillation plates is made of (1/5.5 * the length of the opposite side of the lower opening). As described above, by manufacturing a plurality of metal diaphragms 30 composed of quadrangular pyramids and triangular pyramids to configure one set, optimum efficiency can be obtained when heat is generated.

Here, the fixing flange 31 may be formed on one side of the lower portion of the metal diaphragm 30 made of a triangular pyramid or quadrangular pyramid, and in the case of a triangular pyramid, six to nine metal diaphragms 30 are spaced apart at predetermined intervals. it is desirable Accordingly, compared to a metal diaphragm formed of a flat plate, a larger surface area can be obtained based on the same main body 10, and the effect of generating vibration is maximized. It has the advantage of being able to rapidly diffuse heat without requiring much power from the pump.

In the present invention, a fixing flange 31 is formed to protrude from the lower side of the metal diaphragm 30 and is fixed to a predetermined position of the metal rod passing through.

The fixing flange 31 is configured to interconnect the metal rod 21 and the metal diaphragm 30, and may be formed on each lower side of the metal diaphragm 30 based on the central axis. Therefore, the two or three fixing flanges 31 formed on the metal diaphragm 30 are inserted into the metal rod 21 and spaced apart at predetermined intervals, so that the second metal diaphragm 30 is inserted into the metal rod 21 and lined up. It has a structure of a plurality of metal diaphragms 30 disposed thereon. Here, the fixing flanges 31 may be intersecting at intervals of 180°. More specifically, among the metal diaphragms 30, the first metal diaphragm 30 is disposed, and the next metal diaphragm 30 is at a different position from the fixing flange 31 of the first metal diaphragm 30, Preferably, the metal diaphragm 30 may be installed so as to be disposed at a perpendicular position. Accordingly, when the current supply unit 40 is connected to the two metal rods 21, current can be supplied to the entire metal diaphragm 30, thereby heating the fluid, and the metal diaphragm 30 is provided in plurality, preferably. More specifically, it is possible to increase the effect of heating water by using 4 or 6 ion heaters.

An ion heater for heating a fluid according to another embodiment of the present invention will be described as follows. In the present invention, the plurality of metal diaphragms 30 are arranged in a row, but the fixing flanges 31 may be intersected at intervals of 120°, which means that the metal diaphragm 30 is divided into 6 pieces. A three-phase structure made of is also possible, and may consist of nine. Accordingly, the fixing flange 31 of the metal diaphragm 30 is spaced apart from the bottom at an interval of 120°, and the first, fourth, and seventh metal diaphragms 30, the second, fifth, and eighth metal diaphragms 30, The third, sixth and ninth metal diaphragms 30 share the same metal rod 21. Therefore, when current is supplied through the metal rod 21, the current is applied to the entire metal diaphragm 30, and the water is ionized to perform a heating action. The number of the metal diaphragm 30 is not limited to 6 or 9, but may be more than that, and the heat generation efficiency accordingly increases.

In the present invention, a temperature sensor 50 or a sensor for grounding 60 extending upward from the support part 20 is further included.

The temperature sensor 50 is embedded in the support part 20 and extends upward, and is configured to measure the temperature of the fluid supplied to the inside of the main body part. In addition, the sensor for grounding 60 is configured to sense that a current flows outside the metal rod 21 or the metal diaphragm 30 inside the main body 10, and temperature or grounding is detected at the top of the extended sensor. A sensor may be configured to measure.

In the present invention, the anti-vibration pad 70 is connected to the metal rod 21 at the top or bottom of the metal diaphragm and is closely accommodated in the main body 10 to block vibration of the metal rod 21. ) is further included.

In the present invention, the first anti-vibration pad 71 installed between the inlet 11 and the metal diaphragm 30 and the second anti-vibration pad 71 installed between the outlet 13 and the metal diaphragm 30 It includes a pad 73.

In the anti-vibration pad 70, current is supplied to the metal diaphragm 30 and water is ionized to generate electrical/thermal vibration. An anti-vibration pad 70 may be installed to support the entire metal diaphragm 30 . The anti-vibration pad 70 is installed between the first anti-vibration pad 71 installed between the inlet 11 through which fluid flows and the metal diaphragm 30 and between the metal diaphragm 30 and the outlet 13 A second anti-vibration pad 73 may be included.

In the present invention, an open hole is formed in the center of the first anti-vibration pad 71 and the second anti-vibration pad 73, and the first open hole 72 of the first anti-vibration pad 71 is 2 may have a diameter smaller than that of the second open hole 74 of the anti-vibration pad 73.

The first opening hole 72 preferably has a large diameter in order to easily transfer the fluid supplied from the inlet 11 formed at the bottom to the top, and the second opening hole 74 is a metal diaphragm ( 30), it is desirable to have a narrow diameter in order to easily transfer the fluid to the top.

In the present invention, the second anti-vibration pad 73 and the support portion 20, including a support portion 90 formed to surround the outer portion of the metal rod 21, the support portion 90 is lower It may have a truncated cone shape in which the diameter increases toward .

The supporting part 90 prevents the metal rod 21 installed through the support part 20 from being damaged or defective from vibration, etc., and the metal diaphragm 30 etc. can be stably supported on the support part 20 It may be formed to surround the outer portion of the metal rod 21 in order to be. In addition, the shape is made of a truncated cone shape with a diameter increasing toward the bottom, and more stable support is possible by increasing the area of the part in contact with the support part 20. The supporting portion 90 may be made of a material having high frictional force such as rubber.

In the present invention, the support portion 20 is protruded at a predetermined height from the upper and lower portions, and includes a lower protrusion support portion 201 and an upper protrusion support portion 203 having a smaller diameter than the support portion 20, and the lower protrusion support portion 201 ) And a screw thread is formed along the outer surface of the upper protrusion support portion 203, the upper protrusion support portion 203 is screwed to the body portion, and the cover portion 100 screwed to the lower protrusion support portion 201 contains more

In order for the support part 20 to be mutually coupled with the main body part 10, an upper protruding support part 203 having a smaller diameter may be formed on the upper part of the support part 20, and a screw thread is formed along the outer surface thereof. And, corresponding threads are formed along the lower inner surface of the body portion 10 to be coupled to each other. Here, after the upper protruding support 203 and the main body 10 are coupled, an O-ring 130 may be coupled to prevent fluid supplied therein from leaking. This may be tightly coupled to the step by placing a step inside the body portion 10, and may be coupled to the lowermost end of the body portion 10 to be sealed while surrounding the outer circumferential surface of the upper protruding support portion 203. In addition, the lower protruding support part 201 may further include a cover part 100 as a configuration for covering the metal rod 21 and the current supply part 40 connected thereto, and the cover part 100 also has a lower part. It may be mutually coupled through the protruding support 201 and screwing.

In the present invention, the support portion 20 is formed to protrude from the upper and lower portions at a predetermined height, and includes a lower protrusion support portion 201 and an upper protrusion support portion 203 having a diameter smaller than that of the support portion 20, and the main body portion 10 The lower portion protrudes outward by a predetermined length and is coupled to the upper protruding support portion 203, and further includes a lower ring 202 surrounding the outer surface of the lower protruding support portion 201, the lower ring 202 and The support portion 20 and the outer portion of the body portion 10 are integrally coupled.

This is a three-phase (construction having 6 or 9 metal diaphragms), in order to prevent excessive vibration, the body part 10, the support part 20, and the lower ring 202 are coupled with screws along the vertical direction to stably It is a structure to be supported. The lower part of the body part 10 protrudes outward by a predetermined length and has a surface parallel to the support part 20, and further includes a lower ring 202 surrounding the outer surface of the lower protruding support part 201. ) may have a structure that is mutually coupled at the upper and lower parts centered on. In addition, a current supply unit through-hole 101 for discharging the current supply unit 40 to the outside may be additionally formed on one surface of the cover unit 100 . In the case of single-phase (construction with four metal diaphragms), the current supply through-hole 101 is formed on the lower surface to discharge the current supply unit 40 to the outside, and three-phase (with 6 or 9 metal diaphragms). configuration), the current supply unit through-hole 101 is formed on the outer surface to discharge the current supply unit 40 to the outside.

In addition, a lower protrusion support groove 201a may be additionally formed along the outer surface of the lower protrusion support portion 201 . The lower protruding support groove 201a is a groove for fastening bolts in a state where the cover part 100 is coupled to the lower part of the main body part 10 to fix it.

4 to 6 show an exploded perspective view of an ion heater for heating fluid according to another embodiment of the present invention.

In the ion heater for heating fluid according to another embodiment of the present invention, the inlet 11 through which the fluid is supplied is installed on one side of the lower part, and the outlet 13 through which the fluid is discharged is installed on one side of the upper part. The body portion 10 in which a predetermined space in which fluid flows is formed, the support portion 20 installed on the body portion 10 and coupled to the body portion 10, and penetrating the support portion 20. A plurality of metal rods 21 extending to the lower part of the main body and installed inside the main body 10, connected to the plurality of metal rods 21, and arranged at a predetermined interval, vibrating when power is supplied to fluid It includes a plurality of metal diaphragms 30 that generate bubbles according to ionization to heat the fluid and a current supply unit 40 that supplies current by being connected to the metal rod 21 that has passed through the top of the support unit 20.

In the present invention, the metal diaphragm 30 has a triangular truncated pyramid shape or quadrangular truncated pyramid shape with upper and lower portions open and a diameter narrowing toward the upper portion.

The ion heater for heating fluid according to another embodiment has the same internal configuration and connection relationship as the above-described ion heater, and there is a difference in that the current supply unit 40 is supplied from the top rather than the bottom. More specifically, the support part 20 is formed on the upper part, and there is a metal rod 21 extending downward through the support part 20, and the part penetrating the upper part of the metal rod 21 It may have a structure to which the current supply unit 40 is connected. In the case of this structure, while a plurality of metal diaphragms 30 are installed on top of the metal rod, the fluid can be heated from the ion heater configured in the opposite direction.

In addition, a fixing part 140 coupled to the lower surface of the body part 10 and stably supporting the body part 10 may be further included. More specifically, in consideration of the fact that the fixing part 140 is difficult to stand upright on the ground as the lower part has a round shape when the main body part 10 is formed in the reverse direction, the lower part of the main body part 10 It is a configuration for fixing from the ground while supporting.

In addition, when the body portion 10 is formed in the reverse direction (FIGS. 4 to 6), a discharge valve 15 formed under the body portion 10 to discharge foreign substances or other waste water may be further included. Since the discharge valve 15 has a spherical sealing structure at the lower part of the body part 10, foreign substances or other wastewater may accumulate and it is necessary to discharge it periodically. (10) By opening and closing the valve in the middle of operation by configuring the lower part, the substances can be discharged from the body part 10 to the outside.

In the present invention, a lower protruding support 201 and an upper protruding support 203 are formed to protrude at a predetermined height from both sides of the support 20 and have a diameter smaller than that of the support 20, and the lower protruding support ( 201) and a screw thread are formed along the outer surface of the upper protruding support portion 203, the upper protruding support portion 203 is screwed to the body portion 10, and the cover portion screwed to the lower protruding support portion 201 (100) is further included.

In the present invention, a lower protruding support part 201 and an upper protruding support part 203 are formed to protrude from one side of the support part 20 at a predetermined height and have a diameter smaller than that of the support part 20, and the main body part 10 ) One end protrudes outward by a predetermined length and is coupled to the upper protruding support portion 203 and further includes a lower ring 202 surrounding the outer surface of the lower protruding support portion 201, wherein the lower ring 202 And the support portion 20 and the outer portion of the body portion 10 are integrally coupled. In addition, the lower protruding support part 201 may further include a cover part 100 as a configuration for covering the metal rod 21 and the current supply part 40 connected thereto, and the cover part 100 also has a lower part. It may be mutually coupled through the protruding support 201 and screwing.

In addition, in the present invention, the support portion 20 may have a structure in which the support portion 20 is respectively installed at the bottom, top, and center, and a plurality of metal diaphragms 30 are coupled and installed between each support portion 20 . In this case, the ion heater may be coupled up and down through two body parts including each metal diaphragm 30, and current is supplied from the support part 20 installed at the bottom to the metal diaphragm installed at the bottom. The fluid can be heated and discharged by (30), and at the same time, the metal installed at the top by the current supply unit 40 connected to the metal rod installed downward from the support 20 installed at the top in the same principle. The fluid can also be heated by the diaphragm 30 . This has the advantage that one can be used separately for heating and one for hot water by the configuration of the ion heater continuously installed in the upper and lower parts, and it is not limited to heating or hot water and can be selectively used as needed.

In the present invention, the thermometer 110 installed on one side of the side surface of the body portion 10 and measuring the temperature of the fluid therein and the controller 120 controlling the temperature of the fluid inside the body portion 10 are further included.

The thermometer 110 is configured to measure the temperature of the fluid heated through the metal diaphragm 30 to determine whether it is heated to a desired temperature, and operation can be controlled through the controller 120.

Although the preferred embodiments of the present invention have been described with reference to the accompanying drawings, the embodiments described in this specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention and represent all the technical ideas of the present invention. Since it is not, it should be understood that there may be various equivalents and modifications that can replace them at the time of this application. Therefore, the embodiments described above should be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the claims to be described later rather than the detailed description, and the meaning and scope of the claims and their All changes or modified forms derived from equivalent concepts should be construed as being included in the scope of the present invention.

10: body part
11: inlet
13: discharge unit
15: discharge valve
20: support
201: lower protruding support
201a: lower protrusion support groove
202: lower ring
203: upper protruding support
21: metal bar
30: metal diaphragm
31: fixed flange
40: current supply unit
50: temperature sensor
60: sensor for grounding
70: anti-vibration pad
71: first anti-vibration pad
72: first open hole
73: second anti-vibration pad
74: second open hole
80: first leg
90: supporting part
100: cover part
101: current supply through hole
110: thermometer
120: control unit
130: O-ring
140: fixing part

Claims (16)

A main body portion having an inlet through which fluid is supplied is installed on one side of the lower part, an outlet through which fluid is discharged is installed on one side of the upper part, and a predetermined space through which the fluid flows is formed therein;
a support portion installed below the body portion to support the body portion;
A plurality of metal rods passing through the support part and extending to the top of the main body part;
a plurality of metal diaphragms installed inside the main body, connected to the plurality of metal rods, spaced apart from each other at predetermined intervals, and vibrating when power is supplied to generate bubbles according to ionization in the fluid to heat the fluid; and
Including; a current supply unit connected to the metal rod passing through the lower portion of the support unit to supply current;
It is formed to protrude from the lower side of the metal diaphragm and further includes a fixing flange fixed to a predetermined position of the metal rod passing through,
The metal diaphragm is made of a triangular pyramid, and the fixing flange is installed on each lower side of the triangular pyramid,
The plurality of metal diaphragms are arranged in a row, and the fixing flanges are intersected at intervals of 120°,
Further comprising an anti-vibration pad installed in connection with the metal rod at the upper or lower portion of the metal diaphragm and tightly accommodated in the main body to block vibration of the metal rod,
In the metal diaphragm formed of a triangular pyramid,
The length of the opposite side of the upper opening of the triangular prism is made of (1/5.5 * length of the opposite side of the lower opening),
The length of the side hypotenuse is composed of (2/3 * length of the opposite side of the lower opening),
An ion heater for heating fluid, characterized in that the distance between the plurality of metal diaphragms is (1/5.5 * length of the opposite side of the lower opening). delete delete delete delete delete According to claim 1,
The anti-vibration pad,
a first anti-vibration pad installed between the inlet and the metal diaphragm;
An ion heater for heating fluid, characterized in that it comprises a second anti-vibration pad installed between the discharge unit and the metal diaphragm. According to claim 7,
An open hole is formed in the center of the first anti-vibration pad and the second anti-vibration pad,
The first open hole of the first anti-vibration pad has a smaller diameter than the second open hole of the second anti-vibration pad. delete delete A main body portion having an inlet to which fluid is supplied is installed on one side of the lower part, an outlet to which fluid is discharged is installed on one side of the upper part, and a predetermined space through which the fluid flows is formed therein;
a support part installed on an upper part of the main body part and coupled with the main body part;
A plurality of metal rods passing through the support and extending to the lower part of the main body;
a plurality of metal diaphragms installed inside the main body, connected to the plurality of metal rods, spaced apart from each other at predetermined intervals, and vibrating when power is supplied to generate bubbles according to ionization in the fluid to heat the fluid; and
A current supply unit connected to the metal rod passing through the upper part of the support unit to supply current;
Further comprising a fixing flange protruding from the lower side of the metal diaphragm and fixed to a predetermined position of the metal rod passing through,
The metal diaphragm is made of a triangular pyramid, and the fixing flange is installed on each lower side of the triangular pyramid,
The plurality of metal diaphragms are arranged in a row, and the fixing flanges are intersected at intervals of 120°,
An ion heater for heating fluid, characterized in that it further comprises an anti-vibration pad connected to the metal rod at the upper or lower portion of the metal diaphragm and received in close contact with the main body to block vibration of the metal rod. delete delete According to claim 1,
Doedoe protruding from both sides of the support portion at a predetermined height, including a lower protrusion support portion and an upper protrusion support portion having a smaller diameter than the support portion,
Screw threads are formed along the outer surfaces of the lower protrusion support and the upper protrusion support,
The upper protruding support portion is screwed to the body portion, and the ion heater for heating the fluid, characterized in that it further comprises a cover portion screwed to the lower protrusion support portion. According to claim 1,
Doedoe protruding from one side of the support part at a predetermined height, including a lower protruding support part and an upper protruding support part having a smaller diameter than the support part,
One end of the body portion protrudes outward by a predetermined length and is inserted into the upper protruding support portion,
Further comprising a lower ring surrounding the outer surface of the lower protruding support,
An ion heater for heating fluid, characterized in that the lower ring and the support portion and the outer portion of the body portion are integrally coupled. According to claim 1 or 11,
A thermometer installed on one side of the side of the main body and measuring the temperature of the fluid inside; and
The ion heater for heating the fluid, characterized in that it further comprises a control unit for controlling the temperature of the fluid inside the main body.

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