KR20220141698A - Plat-shaped ion heating element chamber - Google Patents

Abstract

The present invention relates to a plate-type ion heating element chamber. Specifically, the present invention relates to the plate-type ion heating element chamber which heats a fluid by ionizing the fluid through electrical vibration and thermal vibration at the heating plate interior. The plate-type ion heating element chamber of the present invention comprises: a heating plate (100); a fixation plate (200); a lower part vortex pad (310); an upper part vortex pad (320); a fixation stand (400); a fixation cover (500); and an electric wire rod (600).

Description

Plate-shaped ion heating element chamber {PLAT-SHAPED ION HEATING ELEMENT CHAMBER}

The present invention relates to a plate-shaped ion heating element chamber.

Specifically, it relates to a plate-type ion heating element chamber that heats a fluid by ionizing the fluid through electrical and thermal vibrations inside the heating plate.

The hot water system used in industry, industry, or home often uses a heating method by a boiler, and it is made in a manner in which 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. depending on the energy source used, and are divided into heat pump type or heat heating type boilers according to heating methods.

In recent years, energy-saving boilers that can increase thermal efficiency or save hot water costs through efficient heating methods are continuously being developed.

Among them, the heat heating type 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 PTC, which is a kind of semiconductor element, and the sheath heater is made by encapsulating a heating wire together with an insulator in a pipe such as stainless steel, and can obtain high heat and has high durability, so it can be used in electric boilers, etc. It is often used for direct heating.

The heating element of the heat-heating boiler as described above is called a rod-shaped heater and is called a heater rod, and the water is heated while generating heat according to the electrical resistance generated by supplying current to the heating wire installed inside the heater rod.

However, in the case of the heating method using the heater rod as described above, the heating rod itself is heated by supplying current to the heater rod first, and then the heater rod heats the water. There is a disadvantage that the efficiency is lowered, which results in economic loss.

In relation to the above-described technology, Patent Publication No. 10-2016-0035904 discloses a heat storage type boiler using a heater rod and a phase change material.

The technology includes a heat storage tank filled with a phase change material (PCM) therein; a plurality of heater rods installed vertically inside the heat storage tank to heat the water flowing into the heat storage tank by heating the phase change material (PCM) filled in the heat storage tank, but to increase the heating area of the water; It is installed at a predetermined interval between the heater rod and the heater rod, and both ends are composed of an inlet and an outlet of water, respectively, and the water supplied therein comes into contact with the heat emitted from the phase change material (PCM) and is heated to circulate water. Disclosed is a heat storage type boiler using a heater rod and a phase change material, characterized in that it comprises a tube.

Laid-Open Patent Publication No. 10-2016-0035904 (2016.04.01.)

An object of the present invention relates to a plate-shaped ion heating element chamber.

Specifically, to provide a plate-shaped ion heating element chamber that heats the fluid by ionizing the fluid through electrical vibration and thermal vibration inside the heating plate.

The plate-shaped ion heating element chamber according to the present invention, which was devised to achieve the above-described object, is a heating plate ( 100) and;

a fixing plate 200 coupled to the lower side of the heating plate 100 to prevent the heating plate 100 from being separated;

a lower vortex pad 310 coupled to a lower side of the fixing plate 200;

an upper vortex pad 320 coupled to the upper side of the fixing plate 200;

The fixing plate 200, the lower vortex pad 310 and the upper vortex pad 320 through the fixing plate 400 for fixing;

a fixing cover 500 penetrating through the fixing base 400 to cover the lower vortex pad 310 and the upper vortex pad 320;

It is characterized in that it includes; a wire rod 600 passing through one side of the fixing plate 500 provided on the upper and lower sides, and connected to the heating plate 100 to receive power and supply power to the heating plate 100; .

In addition, the heating plate 100,

a plate 111 having a plate shape;

a plurality of microbubble holes 112 penetrating the upper and lower portions of the plate 111;

a plurality of fixing parts 113 protruding outwardly from one side of the outer diameter of the plate 111;

A plate protruding outwardly on the other side corresponding to one side of the outer diameter of the plate 111 in which the fixing part 113 is not formed, and a groove penetrating the upper and lower parts are formed on the other side of the plate to receive power. (115);

In addition, the heating plate 100 is characterized in that a plurality of them are stacked with a predetermined interval.

In addition, the heating plate 100,

Further comprising a plate connection part 114 for connecting any two heating plates 100 selected using the wire connection part 115,

The plate connection part 114,

The two adjacent heating plates 100 are not connected to each other,

When two or more plate connection parts 114 are provided in the bundle of heating plates connected by the plate connection part 114, the plate connection part 114 is characterized in that it has a crossed position between adjacent ones.

In addition, among the stacked heating plates 100 , the heating plate positioned on the uppermost side has a spacing between the heating plate closest to it and 1.5 to 3 times that of the stacking interval between other heating plates.

In addition, the fixing plate 200,

a fluid through hole 210 passing through the upper and lower portions at the center;

a first stepped portion 220 having a predetermined height upward along the circumference of the fluid through hole 210;

a second stepped portion 230 having a predetermined thickness and height from the outer diameter and one side of the fixed plate 200 and having the same height as the first stepped portion 220 so as to block the inflow of fluid from the outside;

It has a predetermined width and depth between the first stepped portion 220 and the second stepped portion 230 and a rubber packing groove 240 to which a rubber ring is coupled; characterized in that it is formed.

In addition, the lower vortex pad 310 is

a first through hole 311 having a cylindrical shape and penetrating the upper and lower portions at the inner center;

a first supporting jaw 312 protruding a predetermined portion from one lower side surface adjacent to the outer diameter of the cylindrical shape;

a first vortex groove 313 in which a groove of a predetermined depth is formed between the first through hole 311 and the first support jaw 312;

a first vortex jaw 314 protruding a predetermined portion in one direction between the first through hole 311 and the first supporting jaw 312;

It is characterized in that it comprises a first fixing hole 315 passing through the upper and lower sides of the first vortex jaw 314.

In addition, the upper vortex pad 320,

a second through hole 321 having a cylindrical shape and penetrating the upper and lower portions at the inner center;

a second support protrusion 322 protruding a predetermined portion from one side of the lower side adjacent to the outer diameter of the upper vortex pad 320;

a second vortex groove 323 in which a groove of a predetermined depth is formed between the second through hole 321 and the second support jaw 322;

a second vortex jaw 324 protruding a predetermined portion in one direction between the second through hole 321 and the second support jaw 322;

It is characterized in that it includes a second fixing hole 325 penetrating the upper and lower portions on one side of the second vortex jaw 324.

In addition, the fixed cover 500,

a fixing part 510 having a cylindrical shape;

a cover hole 520 through which the fluid is received or discharged through the upper and lower portions on one side of the fixing part 510;

a plurality of fixing hole 530 passing through the upper and lower portions so that the fixing rod 400 can be coupled to one side of the fixing part 510;

a wire rod coupling hole 540 that penetrates one side of the fixing part 510 at the top and bottom, and is formed outside the fixing hole 530;

It is characterized in that it includes a sensor coupling hole 550 for measuring the temperature of the fluid through the upper and lower portions on one side of the fixing part 510 .

In addition, the wire rod 600 is,

a single-stage electric wire rod 610 to which an electric wire is connected;

a two-stage electric wire rod 620 coupled to the upper end of the first single electric wire rod 610 and extending;

A plurality of two-stage electric wire rods 620 are connected to the upper end of the two-stage electric wire rod 620, and the uppermost electric wire rod 620n is connected to the uppermost side to receive electricity.

In addition, the single-stage electric wire rod 610 is,

a single-stage fixing part 611 having a predetermined thickness;

a first-stage power supply unit 612 protruding a predetermined portion from one side of the first-stage fixing unit 611 to the other side to receive power;

a first-stage cover coupling part 613 coupled to the other side of the first-stage fixing part 611 to which the first-stage power supply unit 612 is coupled, a predetermined portion protruding outwardly, and a screw thread is formed on the outer diameter;

Doedoe protruding along the longitudinal direction of the first-stage cover coupling portion 613, the first-stage coupling band 614 having a narrower diameter than the diameter of the first-stage cover coupling portion 613;

It is characterized in that it comprises a; doedoe protruding outward from one side of the first stage coupling band (614), a first stage extension portion (615) in which a thread is formed in the outer diameter.

In addition, the two-stage electric wire rod 620,

a two-stage coupling band 621 having a cylindrical shape and a predetermined length;

a multi-stage wire groove 622 in which a groove of a predetermined depth is formed on one side of the two-stage coupling band 621 and a thread is formed along the inner diameter;

It is characterized in that it comprises a; is coupled to the other side of the two-stage coupling band 621 in which the dazan wire groove 622 is formed and protrudes outwardly, a second-stage extension 623 having a screw thread formed on the outer diameter thereof.

In addition, a plurality of microbubble holes 112 are formed along the circumferential direction from the center of the plate 111,

The size of the microbubble hole 112 located in the center and the microbubble hole 112 formed on the outermost side is formed larger than others,

The size of the other microbubble holes 112 is formed relatively small,

The relatively large microbubble hole 112 allows the fluid to pass through,

The relatively small microbubble hole 112 is characterized in that it forms micro-bubbles based on a fluid.

In addition, the plate 111 has a circular or polygonal shape,

Its upper surface is characterized in that it is formed flat or convex.

In addition, the heating plate bundle,

As a bundle of a plurality of heating plates 100 integrally connected through the plate connection part 114,

When the plate connection part 114 is included, the bundle of heating plates is characterized in that at least two or more.

According to the plate-type ion heating element chamber according to the present invention, there is an advantage in that the fluid can be heated without a separate heating element by ionizing the fluid rather than the heating method using a heater rod and heating the fluid by electrical vibration and thermal vibration. .

In addition, as the fluid itself is heated, there is an advantage in that the heating efficiency is higher than that of the conventional heater rod method and energy can be saved.

In addition, as a resonance phenomenon occurs between the heating plates and the fluid is ionized, there is an advantage that more heat than input energy can be output.

In addition, the current supply can be supplied from the upper part as well as from the lower part, so it can be made in a reverse structure, so that it can be selectively used as needed.

1 shows a plate-shaped ion heating element chamber according to the present invention.
Figure 2 shows the heating plate of the plate-type ion heating element chamber according to the present invention.
3 is an embodiment showing that the heating plate of the plate-shaped ion heating element chamber according to the present invention has various shapes.
Figure 4 shows that the heating plate of the plate-shaped ion heating element chamber according to the present invention is stacked with a predetermined interval and coupled to the wire rod.
5 shows a fixed plate of the plate-shaped ion heating element chamber according to the present invention.
Figure 6 shows what has various shapes according to the embodiment for the fixed plate of the plate-shaped ion heating element chamber according to the present invention.
7 shows a vortex pad of the plate-shaped ion heating element chamber according to the present invention, showing a lower vortex pad on the lower side and an upper vortex pad on the upper side.
8 shows the side surfaces of the lower vortex pad and the upper vortex pad of the plate-shaped ion heating element chamber according to the present invention.
9 shows a fixed cover of the plate-shaped ion heating element chamber according to the present invention.
10 is an exploded perspective view of the electric wire rod of the plate-shaped ion heating element chamber according to the present invention.
11 is a perspective view of Example 2 of the plate-shaped ion heating element chamber according to the present invention.
12 shows the first heating plate bundle of Example 2 of the plate-shaped ion heating element chamber according to the present invention.
13 shows the second heating plate bundle of Example 2 of the plate-shaped ion heating element chamber according to the present invention.
14 shows the heating plate of Example 2 of the plate-shaped ion heating element chamber according to the present invention.
15 shows an embodiment in which the heating plate has various shapes.

The terms or words used in the present specification and claims are not to be construed as being limited to their ordinary or dictionary meanings, and the inventor may appropriately define the concepts of the terms in order to best describe his invention. Based on the principle, it should be interpreted as meaning and concept consistent with the technical idea of the present invention.

Accordingly, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical spirit of the present invention, so various equivalents that can be substituted for them at the time of the present application It should be understood that there may be variations and examples.

Hereinafter, prior to the description with reference to the drawings, it is not shown or specifically described for the known components that are not necessary to reveal the gist of the present invention, that is, a known configuration that can be obviously added by those skilled in the art with ordinary knowledge. reveal the sound

a heating plate 100 in which a plurality of through-holes are formed in a plate shape to generate vibration and heat by supplying power to form micro bubbles in the fluid;

a fixing plate 200 coupled to the lower side of the heating plate 100 to prevent the heating plate 100 from being separated;

a lower vortex pad 310 coupled to a lower side of the fixing plate 200;

an upper vortex pad 320 coupled to the upper side of the fixing plate 200;

The fixing plate 200, the lower vortex pad 310 and the upper vortex pad 320 through the fixing plate 400 for fixing;

a fixing cover 500 penetrating through the fixing base 400 to cover the lower vortex pad 310 and the upper vortex pad 320;

A wire rod 600 passing through one side of the fixing plate 500 provided on the upper and lower sides, and connected to the heating plate 100 to receive power and supply power to the heating plate 100; characterized in that it comprises a , plate-shaped ion heating element chamber.

Example 1) Heating plate composed of one object

1 shows a plate-shaped ion heating element chamber according to the present invention, FIG. 2 shows a heating plate of the plate-shaped ion heating element chamber according to the present invention, and FIG. 3 is a plate-shaped ion heating element chamber according to the present invention. 4 shows that the heating plates of the plate-shaped ion heating element chamber according to the present invention are stacked with a predetermined interval and coupled to the wire rods.

The plate-shaped ion heating element chamber is composed of a heating plate 100 , a fixing plate 200 , a vortex pad 300 , a fixing table 400 , a fixing cover 500 , and an electric wire rod 600 .

First, the heating plate 100 includes a first plate 111 , a first microbubble hole 112 , a first fixing part 113 , and a first wire connection part 115 .

The first plate 111 has a plate shape having a predetermined thickness, and a plurality of first microbubble holes 112 are formed along the circumference of the first plate 111 .

At this time, the shape of the first plate 111 may be formed in a polygonal shape, an elliptical shape, etc. as shown in FIG. 3 according to an embodiment, and may have a shape partially curved upwardly, but the present invention is not limited thereto.

A plurality of the first microbubble holes 112 are formed along the circumferential direction from the center of the first plate 111, and the sizes of the first microbubble holes 112 formed at the center and the outermost side are large, The size of the other first microbubble hole 112 is configured to be smaller than that.

The reason that the size of the first microbubble hole 112 formed at the center and the outermost portion is large is for the fluid to be discharged smoothly, and the first microbubble hole 112 formed small in other cases is formed to form micro bubbles. it is for

As described above, if the first microbubble holes 112 are not formed differently in size and all the first microbubble holes 112 are large, microbubbles are not formed, so it is difficult to raise the temperature of the fluid, and the first microbubble holes are not formed differently. When the bores of the holes 112 are all small, the fluid is discharged in an amount less than the pressure at which the fluid is to be discharged, resulting in a problem in which the first plate 111 is damaged.

The first microbubble hole 112 is configured to have various shapes such as a circle, a polygon, and the like, but is not limited thereto.

A plurality of the first fixing parts 113 are formed along the circumference of the outer diameter of the first plate 111 .

The first fixing part 113 may be configured in a 'T' shape as shown in a protrusion shape protruding a predetermined portion in the outward direction, which is first fixed in the protrusion groove 221 of the fixing plate 200 to be described later. The top 113 is coupled and fixed to prevent the first plate 111 from being separated from the fixing plate 200 .

In order to prevent the first fixing part 113 from being separated from the fixing plate 200, it may be configured in various shapes such as a date, a 'L', a 'C' shape other than a 'T' shape, but is not limited thereto. does not

The first wire connection part 115 has a plate that is perpendicular to the outside from one side of the outer diameter of the first plate 111, and a wider plate is formed on the protruding side, and the plate has holes passing through the upper and lower parts. configured to be formed.

A wire rod 600 to be described later is coupled to the hole of the first wire connection part 115 and is configured to receive power from the wire rod 600 to be described later.

The first wire connection part 115 is configured such that the first wire connection part 115 is coupled to the other side opposite to one side of the outer diameter of the first plate 111, but according to the embodiment, the outer diameter of the first plate 111 has a first One wire connection part 115 is configured to be coupled with at least two or more at a predetermined interval, but is not limited thereto.

On the other hand, the heating plate 100 is configured to be stacked in plurality along the longitudinal direction of the wire rod 600 to be described later as shown in FIG. They are rotated at a predetermined angle and configured to be stacked.

In this way, the heating plates 100 stacked at each angle are formed with different pole numbers, so that the heating plate 100 stacked on the uppermost side has an adjacent lower plate space of 1.5 to 3 compared to the other heating plates 100 for smooth operation. It is preferable to be configured to receive electrical compensation by being spaced apart by more than twice.

In the heating plate 100 stacked as described above, when electricity is supplied from the electric supply unit through the first wire connection part 115, the fluid (water) accommodated in the spaced apart space between the heating plates 100 is ionized into positive and negative ions. The heat is generated through mutual friction between the fluid molecules while moving between the heating plates 100 tens of times per second.

To elaborate on this:

First, alternating current (AC) or direct current (DC) exists as a method of supplying current through the current supply unit.

First, in the case of supplying current in an alternating current (AC) method, the voltage may vary in the range of 100 to 420V, and the AC power supplied to Korean homes is usually 220V, 60Hz. Here, in the case of 60 Hz, the current direction is changed 60 times per second and the fluid is ionized to generate electrical vibration in the heating plate 100 to heat the fluid, and in the case of 50 Hz, water molecules ionized 50 times per second The fluid is heated while moving between the heating plates 100 . In addition, when the current is supplied in the direct current (DC) method, as the current value increases, the wavelength increases and the amount of ions produced according to the ionization of water molecules may further increase.

The principle of the heating plate 100 is that as current is supplied, the water supplied inside is rapidly electrolyzed, and high-pressure expansion into oxygen and hydrogen bubbles causes high-temperature vortex cavitation (vortex cavitation). As thermal vibration occurs, more heat (about 120 to 150% or more of heat) is output than the initial input energy.

When the heating plate 100 as described above is used, in contrast to the 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), water itself becomes a medium and heat is generated. Therefore, the heating efficiency is very high, and compared to the heating method used in conventional ion electric boilers (a method in which electrolyzed water is ionized and heat is generated through mutual friction between water molecules when electricity is directly supplied to water with an electrode), electrolyzed water is not required and supplied. Since water itself generates heat, it is more efficient, and even when there is no water inside the heating device, water itself becomes a medium, so there is no risk of fire. In other words, as the water itself heats up without a separate heating medium, the heat output is significantly higher than the heating efficiency of the ion electric boiler, thereby increasing the heating effect. It has the advantage of being able to save ~50% or more.

In addition, as the heater rod is continuously used inside the boiler, problems such as destruction or corrosion may occur due to hardening, but there is an advantage that it can be used semi-permanently without the above problems.

This heating plate 100 has a plate shape, and as the heating plate 100 has a certain interval, it is made on the principle that water is heated by the ionization process occurring therebetween, and has an open top and bottom. Accordingly, water can be easily introduced from the lower part, and the heated fluid (water) can be easily discharged to the upper part.

The fixing plate 200 is coupled between the heating plates 100 .

Figure 5 shows the fixed plate of the plate-shaped ion heating element chamber according to the present invention, Figure 6 shows that it has various shapes according to the embodiment for the fixed plate of the plate-shaped ion heating element chamber according to the present invention.

The fixing plate 200 includes a fluid through hole 210 , a first stepped portion 220 , a second stepped portion 230 , and a rubber packing groove 240 .

The fixing plate 200 includes a first step portion 220 having a predetermined height in the upper direction along the circumference of the fluid through hole 210 and the fluid through hole 210 passing through the upper and lower portions in the center, and the A second stepped portion 230 and a first step having a predetermined thickness and height from the outer diameter and one side of the fixed plate 200 and having the same height as the first stepped portion 220 so as to block the inflow of fluid from the outside. A rubber packing groove 240 having a predetermined width and depth and to which a rubber ring is coupled is formed between the jaw portion 220 and the second stepped portion 230 .

The fluid through hole 210 is configured to have a hole shape through which the fluid (water) can move, and is configured to have a diameter of the same shape as that of the first plate 111 , and the shape of the first plate 111 and It is configured so that it can be formed into a triangle, an oval, or a polygon depending on the shape.

The reason why the fluid through hole 210 is formed in various shapes is to be coupled with the first plate 111 , but the fluid is actually formed in the first microbubble hole 112 of the first plate 111 . This is to properly create micro-sized bubbles.

The first stepped portion 220 includes a protrusion groove 221 , a fixing hole 222 , and a first hook portion 223 .

The protrusion groove 221 is formed with a protrusion groove 221 of a predetermined depth on the inner circumference adjacent to the fluid through hole 210 , and the protrusion groove 221 is a first groove formed on the outer diameter of the first plate 111 . It is configured to have the same position, number, shape, and height as the position of the top portion 113 , so that the first fixing part 113 can be coupled to the protrusion groove 221 .

A plurality of fixing bracket holes 222 are formed on one side of the first stepped portion 220 so that the fixing rod 400 to be described later can be coupled through the upper and lower portions.

The first hook portion 223 is formed with a groove having a predetermined depth perpendicular to the outer diameter direction from the inner diameter of the first stepped portion 220, and is also formed on the other side corresponding thereto.

The first wire connection part 115 is seated and fixed on the first hook part 223 , and the first wire connection part 115 is connected through the second hook part 231 included in the second stepped part 230 . It is configured to protrude to the outside.

The second hook part 231 and the first hook part 223 are formed to have the same height and width as the first wire connection part 115 .

A rubber ring (not shown) is coupled to the rubber packing groove 240 , and the fixing plate 200 is coupled to the lower side of the stacked first plate 111 , so that the upper and lower portions of the adjacent fixing plates 200 are will come into contact

The abutting fixing plate 200 is configured to prevent distortion by a rubber ring (not shown) coupled to the rubber packing groove 240 and prevent foreign substances from being introduced from the outside.

A predetermined groove may be formed on the lower side of the fixing plate 200 in which the rubber packing groove 240 is formed so that a rubber ring (not shown) coupled to the rubber packing groove 240 can be inserted and coupled to a predetermined portion.

In addition to the rubber ring, protrusions and grooves may be formed in the fixing plate 200 .

The protrusion (not shown) protrudes a predetermined portion on the upper portion of the first stepped portion 220, and the protrusion (not shown) is coupled to the lower side of the fixing plate 200 corresponding to the protrusion (not shown). It is configured such that a recessed groove is formed in the upper direction of a predetermined portion so as to be able to do so.

These protrusions and grooves are configured in plurality, and the fixing plates 200 stacked by the protrusions and grooves are more firmly fixed to prevent distortion.

The fixing plate 200 is stacked on top of each other between the heating plates 100 , and a lower vortex pad 310 and an upper vortex pad 320 are formed on the lower portion of the fixing plate 200 formed on the upper and lower sides of the stacked fixing plates 200 . are combined

7 shows a vortex pad of the plate-shaped ion heating element chamber according to the present invention, showing a lower vortex pad on the lower side and an upper vortex pad on the upper side, and FIG. 8 is a lower vortex pad and upper vortex pad of the plate-shaped ion heating element chamber according to the present invention. The side of the pad is shown.

The lower vortex pad 310 and the upper vortex pad 320 have a vortex shape on the lower side, and the upper portion of the lower vortex pad 310 is coupled to the lower portion of the stacked fixing plate 200 , and the stacked fixing plate 200 . It is configured such that the lower side of the upper vortex pad 320 is coupled to the upper portion.

First, the lower vortex pad 310 includes a first through hole 311 , a first support jaw 312 , a first vortex groove 313 , a first vortex jaw 314 , and a first fixing hole 315 . do.

The lower vortex pad 310 has a cylindrical shape and includes a first through hole 311 penetrating the upper and lower portions in the inner center, and a first supporting jaw protruding a predetermined portion from one side of the lower portion adjacent to the outer diameter of the cylindrical shape ( 312), a first vortex groove 313 in which a groove of a predetermined depth is formed between the first through hole 311 and the first supporting jaw 312, and the first through hole 311 and the first A first vortex jaw 314 that protrudes a predetermined portion in one direction between the supporting jaws 312 and a first fixing hole 315 penetrating the upper and lower sides of the first vortex jaw 314 on one side.

One side of the first through hole 311 is configured to have a predetermined inclination in the other direction so that the fluid can flow quickly.

A plurality of the first vortex groove 313 and the first vortex jaw 314 are formed, and the first vortex groove 313 and the first vortex jaw 314 are sequentially formed.

The first holder hole 315 is configured such that a plurality of first vortex jaws 314 are formed according to the number of the fixing table 400 .

The upper vortex pad 320 includes a second through hole 321 , a second support jaw 322 , a second vortex groove 323 , a second vortex jaw 324 , and a second fixing hole 325 . .

The upper vortex pad 320 has a cylindrical shape and has a second through hole 321 penetrating the upper and lower portions in the center of the inner side, and a second through-hole 321 that protrudes a predetermined portion from one side of the lower portion adjacent to the outer diameter of the upper vortex pad 320 . 2 supporting jaws 322, a second vortex groove 323 in which a groove of a predetermined depth is formed between the second through hole 321 and the second supporting jaw 322, and the second through hole 321 ) and a second vortex jaw 324 protruding a predetermined portion in one direction between the second supporting jaw 322 and a second fixing hole 325 penetrating the upper and lower sides of the second vortex jaw 324 on one side. includes

One side of the second through-hole 321 is configured to have a predetermined inclination in the other direction so that the fluid can flow rapidly in the longitudinal direction of the hole by the inclination angle.

A plurality of the second vortex groove 323 and the second vortex jaw 324 are formed, and the second vortex groove 323 and the second vortex jaw 324 are sequentially formed.

The second holder hole 325 is configured such that a plurality of the second vortex jaw 324 is formed according to the number of the holder 400 .

The difference between the lower vortex pad 310 and the upper vortex pad 320 will be described.

The size of the first through hole 311 is larger than that of the second through hole 321 .

The first vortex groove 313 and the first vortex jaw 314 are formed more than the second vortex groove 323 and the second vortex jaw 324 .

It is preferable that the first through-hole 311 of the lower anti-vibration pad 310 is formed large in order for a lot of fluid to flow in when the fluid is supplied from the bottom, and the second through-hole 321 is formed by the heating plate 100 . It is desirable to have a narrow diameter so that the heated fluid can be easily transferred to the upper part.

And the first vortex groove 313 and the first vortex jaw 314 of the lower vortex pad 310 are formed with the vortex groove 323 and the second vortex jaw 324 of the upper vortex pad 320 are introduced from the bottom It is configured to make the inflow of the fluid used more smoothly, and to form a small vortex of the upper vortex pad 320 so that the temperature of the fluid can be raised and discharged.

The lower surface of the lower anti-vibration pad 310 and the upper anti-vibration pad 320 is configured to have a concave shape in the direction of the center hole to collect the flow of the fluid in the direction of the center hole.

The holder 400 is configured in the form of a cylindrical long rod, and penetrates through the holder hole 222 , the first holder hole 315 , the second holder hole 325 , and the holder hole 530 of the fixing cover 500 . are combined

9 shows a fixed cover of the plate-shaped ion heating element chamber according to the present invention.

The fixed cover 500 is coupled to the lower side of the lower vortex pad 310 and the upper side of the upstream vortex pad 320 , respectively.

The fixing cover 500 includes a fixing part 510 , a cover hole 520 , a fixing base hole 530 , a wire rod coupling hole 540 , and a sensor coupling hole 550 .

The fixing cover 500 includes a fixing part 510 having a cylindrical shape, a cover hole 520 through which the fluid is received or discharged through upper and lower portions on one side of the fixing part 510, and the fixing part ( A plurality of fixture holes 530 passing through the upper and lower portions so that the fixture 400 can be coupled to one side of the 510, and upper and lower penetrating one side of the fixture 510, the fixture hole 530 It includes a wire rod coupling hole 540 formed on the outer side and a sensor coupling hole 550 for measuring the temperature of the fluid through upper and lower portions on one side of the fixing part 510 .

First, the fixing part 510 has a predetermined thickness and is configured to have a wider circumference than the circumference of the fixing plate 200 .

This is so that the wire rod 600 to be described later is coupled to the wire rod coupling hole 540 , the first plate connection part 114 and the second plate connection part 124 , the wire rod coupling hole 540 , the first plate connection part 114 . ) and the second plate connection part 124 are configured to be located on the same line.

The cover hole 520 of the fixed cover 500 coupled to the lower side of the lower vortex pad 310 is formed to have the same size as the first through hole 311 , and is coupled to the upper side of the upper vortex pad 320 . The cover hole 520 of the fixed cover 500 is formed to have the same size as the size of the second through hole 321 .

In addition, the inner diameter of the cover hole 520 may be threaded along a circumference, and a hose pipe may be screwed to the Nana mountain.

The holder hole 530 may have the same position and number of the first holder hole 315 of the lower vortex pad 310 and the second holder hole 325 of the upper vortex pad 320 .

This means that the holder hole 530 is through-coupled to the holder 400 protruding through the first holder hole 315 and the second holder hole 325 , and bolts at the upper and lower portions are respectively coupled to the holder 400 . Because.

The wire rod coupling hole 540 has the same diameter as that of the wire rod 600 to be described later, and is formed in the same number and position as the conductive rod 600 .

The sensor coupling hole 550 is formed at a position spaced apart from the wire rod coupling hole 540 by a predetermined distance, and since the temperature cannot be accurately measured by the heat emitted from the wire rod coupling hole 540, it is preferable to space it.

A temperature sensor (S) for measuring the temperature of the fluid heated by the heating plate 100 is coupled to the sensor coupling groove 550 so that the user can check the temperature of the fluid through the temperature sensor (S). is composed

10 is a perspective view of the electric wire rod of the plate-shaped ion heating element chamber according to the present invention.

The electric wire rod 600 is composed of a single-stage electric wire rod 610 and a second-stage electric wire rod 620 .

The single-stage electric wire rod 610 includes a first-stage fixing part 611 , a first-stage power supply unit 612 , a first-stage cover coupling part 613 , a first-stage coupling band 614 , and a first-stage extension part 615 .

The single-stage electric wire rod 610 includes a first-stage fixing part 611 having a predetermined thickness, and a one-stage power supply unit 612 that protrudes a predetermined portion from one side of the first-stage fixing part 611 to the other side to receive power supply; , The first stage power supply unit 612 is coupled to the other side of the one-stage fixing portion 611 coupled to a predetermined portion protruding outwardly, and a first-stage cover coupling portion 613 having a thread formed on the outer diameter, and the first stage Doedoe protruding along the longitudinal direction of the cover coupling part 613, the first stage coupling band 614 having a diameter narrower than the diameter of the first stage cover coupling part 613 and one side of the first stage coupling band 614 outward direction Doedoe projecting to include a first-stage extension 615 in which a thread is formed on the outer diameter.

The two-stage electric wire rod 620 includes a two-stage coupling band 621 , a multi-stage electric wire groove 622 , and a two-stage extension part 623 .

A two-stage coupling band 621 having a cylindrical shape and a predetermined length, a groove of a predetermined depth is formed on one side of the two-stage coupling band 621, and a multi-stage wire groove 622 in which a thread is formed along the inner diameter, and the above It is coupled to the other side of the two-stage coupling band 621 in which the dazan wire groove 622 is formed and protrudes outward, and includes a two-stage extension 623 having a thread formed on the outer diameter.

The first-stage fixing part 611 is formed to be larger than the diameter of the wire rod coupling hole 540 and is fixed to the upper portion of the coupling fixture 510 , and the first-stage cover coupling part 613 is connected to the wire rod coupling hole 540 . configured to be coupled.

The first stage power supply unit 612 is configured such that a screw thread is formed in the outer diameter, an electric wire is connected to receive power supply, and a washer (Y) and a bolt (B) are coupled. At this time, it is configured to prevent loosening by coupling two or more bolts (B).

The first-stage extension 615 has a smaller diameter than the diameter of the first-stage coupling band 614 , and a C-shaped C-ring (C), a washer (Y), and a first wire connection part 115 are coupled, and the two-stage electric The dazan wire groove 622 of the front rod 620 is coupled.

The second stage extension portion 623 is configured such that the second stage wire groove 622 of the other two stage wire rod 620 is coupled.

That is, the two-stage electric wire rods 620 of various lengths are sequentially coupled to the second-stage extension portion 623 of the second-stage electric wire rod 620 coupled to the first-stage electric wire rod 610, and at the end, the uppermost electric wire rod 620n is combined. configured to be

In this way, a C-ring (C) or a washer (Y) may be coupled between the second-stage extension 623 of the second-stage electric wire rod 620 and the other two-stage electric wire rod 620 .

And a ring (C), two washers (Y) and two bolts (B) are coupled to the upper portion of the uppermost wire rod (620n), an electric wire is connected to receive power supply to the uppermost wire rod (620n), and a ring ( C), two washers (Y) and two bolts (B) are combined.

And the wire cover 650 is coupled to the outer diameter of the first-stage coupling band 614 of the single-stage electric wire rod 610 and the second-stage coupling band 621 of the second-stage electric wire rod 620 .

The electric wire cover 650 is made of an insulating material and is configured to prevent the user from being electrocuted from the electric wire rod 600 .

Example 2) Heating plate formed in a bundle

Figure 11 shows a perspective view of Example 2 of the plate-shaped ion heating element chamber according to the present invention, Figure 12 shows the first heating plate bundle of Example 2 of the plate-shaped ion heating element chamber according to the present invention, Figure 13 is the present invention It shows the second heating plate bundle of Example 2 of the plate-shaped ion heating element chamber according to, Figure 14 shows the heating plate of Example 2 of the plate-shaped ion heating element chamber according to the present invention.

11 to 14 , the heating plate 100 of the second embodiment includes a first heating plate bundle 110 and a second heating plate bundle 120 .

On the other hand, in the heating plate 100 of Example 2, any one of the first wire connection parts 115 of the first wire connection parts 115 coupled to one side and the other side of the first plate 111 of Example 1 is 'c' It includes a first plate connection part 114 and a second plate connection part 124 configured in the shape of a ruler.

In addition, as the first plate connection part 114 and the second plate connection part 124 are formed, the heating plate 100 is divided into a first heating plate bundle 110 and a second heating plate bundle 120 .

The first heating plate bundle 110 includes a first plate 111 having a plate shape, a plurality of first microbubble holes 112 penetrating the upper and lower portions of the first plate 112 , and the first A plurality of first fixing parts 113 projecting outwardly from the outer diameter circumference of the plate 111, and a first plate 111 in which the first microbubble hole 112 and the first fixing part 113 are coupled A plurality of first plates 111 stacked with a predetermined distance apart and the other first plates 111 on top of the stacked first plates 111 are stacked at a greater distance than the stacked gap, the uppermost first The first plate connecting portion 114 and the first plate 111 are connected to the plate 111n and their first plates 111 having a 'C' shape and adjacent to each other in a symmetrical direction on the left and right sides. With respect to the first plate connection part 114 includes a first wire connection part 115 extending to one side to which it is not connected.

The first plate connection part 114 is formed by bending the first wire connection part 115 of any one of the first wire connection parts 115 coupled to one side and the other side of the outer diameter of the first plate 111 of the first embodiment. It may be configured to have a form of one plate connection part 114 .

Accordingly, the first plates 111 are stacked spaced apart from each other by a predetermined distance, and the uppermost first plates 111n spaced apart from the other first plates 111 by 1.5 to 3 times or more are stacked on the uppermost side.

A first plate connection part 114 is connected to one side of the first plate 111 and the uppermost first plate 111n stacked as described above,

The first wire connection part 115 is coupled to one side of the lowermost first plate 111 and the uppermost first plate 111n to which the first plate connection part 114 is not coupled.

15, the second plate 121, the second microbubble hole 122, the second fixing part 123, the second plate connection part 124, and the second wire are reference numerals for the second heating plate bundle 120. The connection part 125 is shown.

However, this is a reference number for clarifying the distinction between the first embodiment and the second embodiment in explaining the present invention, and is actually the same structure and is only a criterion for distinguishing that it is connected by the first plate connection part 114 .

With reference to these standards, the second heating plate bundle 120 according to the second embodiment includes a second plate 121 , a second microbubble hole 122 , a second fixing part 123 , and a second as shown in FIG. 15 . It consists of a plate connection part 124 and a second wire connection part 125 .

A second plate 121 having a plate shape of a predetermined thickness, a plurality of second microbubble holes 122 penetrating the upper and lower portions of the second plate 121, and the second microbubble holes 122 A second plate symmetrically connected to the left and right sides of a second fixing part 123 protruding outward from the outer diameter of It includes a connection part 124 and a second wire connection part 115 extending to one side to which the second plate connection part 124 is not connected with respect to the second plate 121 .

The second plate 121 includes a first plate 111 , the second microbubble hole 122 includes a first microbubble hole 112 , and the second fixing part 123 includes a first fixing part 113 . , the second plate connection part 124 has the same shape, configuration, and effect as the first plate connection part 114 and the second wire connection part 125 as the first wire connection part 115 .

The heating plate 100 includes a second heating plate bundle 120 consisting of two second plates 121 between the first heating plate bundle 110 consisting of three first plates 111 shown in FIG. 14 . It is stacked with a gap, and the uppermost first plate 111 and the second plate 121 adjacent to each other are configured to be spaced apart a lot.

That is, the first plate connection part 114 and the second plate connection part 124 are configured to have a structure connected to at least one or more of the stacked first plates 111 and second plates 121 .

15 shows an embodiment in which the heating plate has various shapes.

The first plate 111 of the first heating plate bundle 110, the uppermost first plate 111n, and the second plate 121 of the second heating plate bundle 120 are polygonal, circular or oval curved upwards; It is configured to have various shapes such as a plate-shaped circle, an oval, and the like.

The diameter and shape of the first microbubble hole 112 and the second microbubble hole 122 may be circular, oval, polygonal, or the like, but is not limited thereto.

Figure 16 shows that the second heating plate bundle is further coupled to the heating plate of Example 2 of the plate-shaped ion heating element chamber according to the present invention.

16 , in the heating plate 100 , the second heating plate bundles 120 may be coupled between the first heating plate bundles 110 .

The description will be made in order, but the lowest side is number 1 and the uppermost side is number 7.

The first heating plate bundle 110 is located at 1, 4, and 7, the second heating plate bundle 120 is located at 2 and 5, and the other second heating plate bundle 120 is located at 3 and 6 positions. It is configured to be stacked in a state.

That is, when at least two or more second heating plate bundles 120 are stacked between the first heating plate bundles 110, the first plate connection part 114 is connected to at least one or more subsequent plates among the stacked plates, The second plate connection part 124 is configured to be connected to at least one or more next plates among the laminated plates.

On the other hand, as shown in FIG. 11 , the upper and lower portions of the wire rod 600 are separated to be divided into a cathode and an anode, respectively.

At this time, the upper and lower portions are configured to be connected to each other.

In addition, the polarities are configured to have a predetermined interval so as not to cause a short circuit.

In this case, the electric wire rod 600 may be configured to be connected only to the first electric wire connecting portion 115 and the first electric wire rod 610 and the second electric wire rod 620 .

That is, it may be configured to extend upwardly or downwardly from the first wire connection part 115, but is not limited thereto.

What has been described above using the drawings is to describe only the main points of the present invention, and it is obvious that the present invention is not limited to the configuration of the drawings as much as various designs are possible within the technical scope.

100: heating plate
110: first heating plate bundle
111: first edition
111n: uppermost first plate
112: first microbubble hole
113: first fixing part
114: first plate connection part
115: first wire connection part
120: second heating plate bundle
121: 2nd edition
122: second micro bubble hole
123: second fixing part
124: second plate connection part
125: second wire connection part
200: fixed plate
210: fluid through hole
220: first single-turn unit
221: protrusion groove
222: fixing hole
223: first hook part
230: second stepped portion
231: second hook part
240: rubber packing groove
310: lower vortex pad
311: first through hole
312: first support jaw
313: first vortex groove
314: first vortex jaw
315: first fixing base hole
320: upper vortex pad
321: second through hole
322: second support jaw
323: second vortex groove
324: second vortex jaw
325: second fixing base hole
400: fixture
500: fixed cover
510: fixed part
520: cover hole
530: fixing hole
540: wire rod coupling hole
550: sensor coupling hole
600: wire rod
610: single wire lead
611: 1-stage fixed part
612: 1 stage power supply unit
613: 1st stage cover coupling part
614: 1 stage coupling band
615: 1st stage extension
620: double wire wire rod
621: two-stage coupling band
622: 2 wire groove
623: 2 stage extension
620n: top wire rod
650: wire cover
B: bolt
C: C ring
E: water out
S: sensor
I: get
Y: washer

Claims (15)

a heating plate 100 in which a plurality of through-holes are formed in a plate shape to generate vibration and heat by supplying power to form micro bubbles in the fluid;
a fixing plate 200 coupled to the lower side of the heating plate 100 to prevent the heating plate 100 from being separated;
a lower vortex pad 310 coupled to a lower side of the fixing plate 200;
an upper vortex pad 320 coupled to the upper side of the fixing plate 200;
The fixing plate 200, the lower vortex pad 310 and the upper vortex pad 320 through the fixing plate 400 for fixing;
a fixing cover 500 penetrating through the fixing base 400 to cover the lower vortex pad 310 and the upper vortex pad 320;
A wire rod 600 passing through one side of the fixing plate 500 provided on the upper and lower sides, and connected to the heating plate 100 to receive power and supply power to the heating plate 100; characterized in that it comprises a , plate-shaped ion heating element chamber.
The method according to claim 1,
The heating plate 100 is
a plate 111 having a plate shape;
a plurality of microbubble holes 112 penetrating the upper and lower portions of the plate 111;
a plurality of fixing parts 113 protruding outwardly from one side of the outer diameter of the plate 111;
A plate protruding outwardly on the other side corresponding to one side of the outer diameter of the plate 111 in which the fixing part 113 is not formed, and a groove penetrating the upper and lower parts are formed on the other side of the plate to receive power. (115); characterized in that it comprises a, plate-shaped ion heating element chamber.
3. The method according to claim 2,
The heating plate 100, a plate-shaped ion heating element chamber, characterized in that a plurality of stacked with a predetermined interval.
4. The method of claim 3,
The heating plate 100 is
Further comprising a plate connection part 114 for connecting any two heating plates 100 selected using the wire connection part 115,
The plate connection part 114,
The two adjacent heating plates 100 are not connected to each other,
When two or more plate connection parts 114 are provided in the bundle of heating plates connected by the plate connection part 114, the plate connection part 114 has a crossed position between adjacent ones, characterized in that the plate-shaped ion heating element chamber .
3. The method according to claim 2,
Among the stacked heating plates 100, the heating plate positioned at the uppermost side has a spacing between the heating plate closest to it and 1.5 to 3 times the spacing between other heating plates.
The method according to claim 1,
The fixing plate 200,
a fluid through hole 210 passing through the upper and lower portions at the center;
a first stepped portion 220 having a predetermined height upward along the circumference of the fluid through hole 210;
a second stepped portion 230 having a predetermined thickness and height from the outer diameter and one side of the fixed plate 200 and having the same height as the first stepped portion 220 so as to block the inflow of fluid from the outside;
The plate-shaped ion heating element chamber, characterized in that it has a predetermined width and depth between the first stepped portion 220 and the second stepped portion 230, and is formed with a rubber packing groove 240 to which a rubber ring is coupled.
The method according to claim 1,
The lower vortex pad 310 is
a first through hole 311 having a cylindrical shape and penetrating the upper and lower portions at the inner center;
a first supporting jaw 312 protruding a predetermined portion from one lower side surface adjacent to the outer diameter of the cylindrical shape;
a first vortex groove 313 in which a groove of a predetermined depth is formed between the first through hole 311 and the first support jaw 312;
a first vortex jaw 314 protruding a predetermined portion in one direction between the first through hole 311 and the first supporting jaw 312;
The plate-shaped ion heating element chamber, characterized in that it comprises a first fixing hole (315) penetrating the upper and lower portions on one side of the first vortex jaw (314).
The method according to claim 1,
The upper vortex pad 320,
a second through hole 321 having a cylindrical shape and penetrating the upper and lower portions at the inner center;
a second support protrusion 322 protruding a predetermined portion from one side of the lower side adjacent to the outer diameter of the upper vortex pad 320;
a second vortex groove 323 in which a groove of a predetermined depth is formed between the second through hole 321 and the second support jaw 322;
a second vortex jaw 324 protruding a predetermined portion in one direction between the second through hole 321 and the second support jaw 322;
A plate-shaped ion heating element chamber, characterized in that it comprises a second fixing hole 325 penetrating the upper and lower portions on one side of the second vortex jaw (324).
The method according to claim 1,
The fixed cover 500,
a fixing part 510 having a cylindrical shape;
a cover hole 520 through which the fluid is received or discharged through the upper and lower portions on one side of the fixing part 510;
a plurality of fixing hole 530 passing through the upper and lower portions so that the fixing rod 400 can be coupled to one side of the fixing part 510;
a wire rod coupling hole 540 that penetrates one side of the fixing part 510 at the top and bottom, and is formed outside the fixing hole 530;
A plate-shaped ion heating element chamber, characterized in that it includes a sensor coupling hole 550 for measuring the temperature of the fluid through the upper and lower portions on one side of the fixing part 510 .
The method according to claim 1,
The wire rod 600 is,
a single-stage electric wire rod 610 to which an electric wire is connected;
a two-stage electric wire rod 620 coupled to the upper end of the first single electric wire rod 610 and extending;
A plurality of two-stage electric wire rods 620 are connected to the upper end of the two-stage electric wire rod 620, and the uppermost electric wire rod 620n is connected to the uppermost side to receive electricity. .
11. The method of claim 10,
The single wire wire rod 610 is,
a single-stage fixing part 611 having a predetermined thickness;
a first-stage power supply unit 612 protruding a predetermined portion from one side of the first-stage fixing unit 611 to the other side to receive power;
a first-stage cover coupling part 613 coupled to the other side of the first-stage fixing part 611 to which the first-stage power supply unit 612 is coupled, a predetermined portion protruding outwardly, and a screw thread is formed on the outer diameter;
Doedoe protruding along the longitudinal direction of the first-stage cover coupling portion 613, the first-stage coupling band 614 having a narrower diameter than the diameter of the first-stage cover coupling portion 613;
Doedoe projecting outward from one side of the first stage coupling band (614), the first stage extension portion (615) having a thread formed on the outer diameter; characterized in that it comprises a plate-shaped ion heating element chamber.
11. The method of claim 10,
The two-stage electric wire rod 620 is,
a two-stage coupling band 621 having a cylindrical shape and a predetermined length;
a multi-stage wire groove 622 in which a groove of a predetermined depth is formed on one side of the two-stage coupling band 621 and a thread is formed along the inner diameter;
It is coupled to the other side of the two-stage coupling band 621 in which the dazan wire groove 622 is formed and protrudes outwardly, the two-stage extension part 623 having a thread formed on the outer diameter; plate-shaped ion comprising a; heating element chamber.
3. The method according to claim 2,
A plurality of microbubble holes 112 are formed along the circumferential direction from the center of the plate 111,
The size of the microbubble hole 112 located in the center and the microbubble hole 112 formed on the outermost side is formed larger than others,
The size of the other microbubble holes 112 is formed relatively small,
The relatively large microbubble hole 112 allows the fluid to pass through,
The plate-shaped ion heating element chamber, characterized in that the microbubble hole 112 having a relatively small size forms a micro-sized bubble based on a fluid.
3. The method according to claim 2,
The plate 111 has a circular or polygonal shape,
A plate-shaped ion heating element chamber, characterized in that its upper surface is flat or convex.
5. The method according to claim 4,
The heating plate bundle,
As a bundle of a plurality of heating plates 100 integrally connected through the plate connection part 114,
When including the plate connection part 114, the plate-shaped ion heating element chamber, characterized in that at least two or more heating plate bundle.

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