KR100997957B1 - Carbon heating element that have flange type of structure - Google Patents

Abstract

PURPOSE: A carbon fiber heating element that have the flange type of a structure is provided to remove a concern of water leakage by enabling the carbon fiber heating element to be detachable from a plate or a fixing unit. CONSTITUTION: A carbon fiber heating element(122) is arranged inside a quartz tube(121). The carbon fiber heating element has a wound filament structure. The quartz tube(124) is arranged inside the carbon fiber heating element. Molybdenum metal(126) is arranged at both sides of the carbon fiber heating element and the quartz tube. A power supply member(130) is directly connected to the carbon fiber heating element and the quartz tube in order to supply external power supply to the carbon fiber heating element. A flange(110) is combined in one side of a carbon fiber heater structure(100).

Description

Carbon heating element that have flange type of structure}

The present invention relates to a carbon heating element having a flange-type structure, and more particularly, a carbon fiber heating element mounted in a vacuum-formed quartz tube and a carbon heater structure heated by electricity supply to an inner quartz tube are stored for generating high temperature. One or more power supply members installed at one or more in the vertical type or horizontal type at the upper part of the space, coupled to the plate and fixed to the plate when mounted in the vertical length direction, and allowing the carbon heating element combined with the flange to generate heat to the plate. The present invention relates to a carbon heating element having a flange-type structure having a flange-type structure which is configured only as a cartridge type and is mounted in a cartridge type on one side of a unit to be fixed when mounted in the horizontal longitudinal direction and is kept horizontal.

Typically, carbon is mainly composed of carbon (carbon) having an inorganic or organic graphite structure, and in the form of carbon yarn made of thread, powder made of powder, carbon felt made of cotton, solidified carbon rod, etc. These carbons are often stronger than iron and lighter than aluminum because of their high elasticity and strength. Depending on the raw material, it is classified into polyacrylonitrile (PAN), pitch, and rayon, but PAN and rayon are used for the most part.

A common carbon heater is a heater that uses a filament made of carbon as a heating element, and has a good thermal efficiency, is harmless to the environment at the time of disposal, and is known to have various effects such as far-infrared radiation and deodorization effect, sterilization and antibacterial effect. Of course, there is a trend that is increasingly being used in a heating device, a drying device.

1 is a schematic internal configuration diagram showing a spiral carbon heater of the conventional carbon heater.

The carbon heater of the prior art, as shown in Figure 1, the quartz tube (quartztube 10) that is sealed inside through both the encapsulation portion 11, and the carbon arranged in a spiral structure in the quartz tube 10 elongated Through the filament 12, the metal wire 14 connected to both sides of the quartz tube 10 at both ends of the carbon filament 12, and the metal pieces in the encapsulation portion 11 of the quartz tube 10 The external electrode 16 is electrically connected to the metal wire 14 and exposed to the outside.

The quartz tube 10 is sealed inside, and a vacuum or an inert gas is filled in the sealed inside so that the carbon filament does not oxidize at 250 to 300 ° C or higher.

Since the conventional carbon heater supports the carbon filament 12 in a pulled state so that the carbon filament 12 is maintained in the quartz tube 10 through the metal wire 14 at both ends thereof, the carbon filament 12 is increased when used for a long time. As the paper is deformed, there is a problem in that the inner surface of the quartz tube 10 may be deformed.

In addition, as shown in FIG. 1, the metal wire 14 configured to supply electricity to both sides has a structure connected horizontally through both sides in the storage tank. There is a problem that is difficult to use for hot water due to the occurrence of cracks).

In addition, since the density (W / cm 2) (heater capacity / heater surface area) of the carbon heater constituting the horizontal structure in the storage tank falls, it is not suitable for use for hot water.

As such, the carbon heater having a horizontal structure must have a structure that penetrates both sides of the storage tank in order to be connected to the power supply lines of both sides in the storage tank, so that the carbon heater fails to meet the parallelism, which causes the quartz tube to break. , It is difficult to install because it must be mounted horizontally accurate, there is a problem that takes time because the internal storage tank water must be discharged in order to replace or replace if there is water inside.

An object of the present invention for solving the problems according to the prior art, the carbon fiber heating element mounted in the vacuum-formed quartz tube and the carbon heater structure which is heated by electricity supply to the inner quartz tube is perpendicular to the storage space for generating a high temperature It is installed in one or more of the type or horizontal type, it is coupled to the plate and fixed when mounted in the vertical longitudinal direction, and constitutes only one side of the power supply member that allows the carbon heating element combined with the flange to generate heat to the plate detachable To provide a carbon heating element having a flange-type structure having a flange-type structure that is mounted in a cartridge type on one side of the unit to be fixed when mounted in the horizontal longitudinal direction and kept horizontal to radiate heat of high temperature.

Carbon heating element having a flange-type structure of the present invention for solving the above technical problem, is formed long in the longitudinal direction, the carbon fiber heating element and the inner quartz tube is inserted into the inside of a predetermined space provided in a cylindrical shape sealed on one side Characterized in that the carbon heater structure consisting of a removable flange that is coupled to maintain a vacuum inside one side of the heating element is configured to only one side of the power supply member to generate heat.

Preferably, the carbon heater structure is a power supply member for electrically coupling the carbon fiber heating element and the internal quartz tube is located inside the flange and the flange and the carbon heating element is mounted to one side to complete one carbon heater structure, It is characterized by having a heat generating structure by electricity supply made in only one direction.

Preferably, the carbon heater structure, and the flange to form a coupling hole on both sides to be coupled to the external device; A carbon heating element which is coupled to the flange in the form of a detachable cartridge but which heats the carbon fiber heating element and the inner quartz tube by heating to generate a high temperature; A power supply member configured at a flange side to be directly connected to a carbon fiber heating element and an internal quartz tube to supply external power to the carbon heating element; .

Preferably, the carbon heating element is formed in a longitudinal shape in the longitudinal direction inside the predetermined space, one side is a quartz tube closed in the form of a cap; A carbon fiber heating element having a wound filament structure accommodated in the quartz tube; An internal quartz tube long embedded in the carbon fiber heating element in a longitudinal direction; Molybdenum metal which is a high temperature heating element on both sides of the carbon fiber heating element and the inner quartz tube; And a pair of power lines connected to the carbon fiber heating element and the inner quartz tube, respectively, extending to one side to supply external power from only one side.

Preferably, the carbon heater structure is installed at least one carbon heater structure which is fixed perpendicularly to the upper portion of the storage unit for receiving water to supply the heating water of the boiler or the hot water of the instant water heater, while standing in the vertical longitudinal direction Flange is coupled to the plate to be attached and detached, characterized in that the carbon heater structure consisting of only one side of the power supply member to allow the carbon heater structure to generate heat.

Preferably, the storage unit for storing the water for supplying hot water to supply the hot water of the heating water or the instant water heater of the boiler; A plate of plate-shaped body mounted on the storage unit and provided with at least one fixed through hole for vertically mounting the carbon heater structure in a cartridge type; A power supply configured at an upper portion to be connected to a carbon heating element and an internal quartz tube to supply external power to the carbon heater structure; .

Preferably, at least one carbon heater structure is mounted in an upright state in a fixed through hole of the plate, and the at least one carbon heater structure is characterized in that the lower part is kept in a state immersed in water.

Preferably, the carbon heater structure is mounted to the flange in a vertical structure, characterized in that for mounting the carbon heater structure having a corresponding length according to the depth of the storage tank for storing water.

Preferably, the carbon heater structure is installed at least one carbon heater structure which is horizontally fixed in a cartridge type on one side of the inside of the heater to dissipate the heat of high temperature, detachable from one side of the protective film for supporting the heat generating rear surface It is characterized in that the carbon heater structure consisting of only one side of the power supply member is fixed to the flange coupled to the support unit to be coupled so that the carbon heater structure generates heat.

Preferably, the carbon heater structure is installed at least one carbon heater structure that is horizontally fixed in a cartridge type on one side of the inner tube of the heat blower to heat the high-temperature wind, fixed to combine to be detachable from one side of the inner tube The flange is coupled to the unit and fixed, and the power supply member configured to allow the carbon heater structure to generate heat only on one side is characterized in that the wind generated from the fan is heated to a high temperature by the carbon heater structure and discharged through the discharge port. do.

The present invention as described above, the carbon heater structure is a vertical type can be used in boilers, instantaneous water heaters, etc. when mounted in the cartridge form, while the horizontal type generates a high temperature heat such as a heater, hot air blower when mounted in the cartridge form It can be mounted on a device, so the range of application is wide for various high temperature generators, and the installation and replacement is very simple.

In addition, only one side of the power supply member for heat generation of the carbon heater structure coupled to the flange to be attached to or detached from the plate or fixed unit It has a vertical or horizontal structure, no noise, simple wiring and easy replacement of the cartridge type carbon heater structure.

In addition, since the carbon heater structure is configured to supply power only from one side, it is possible to attach or detach the plate or the fixing unit in the form of a cartridge, and there is no fear of leakage because it does not need to penetrate the storage tank for storing water. There is an effect that does not occur.

In addition, the plate or the fixed unit can be mounted in a plurality of vertical or horizontal constituents in easy to replace, easy to replace, additional installation, it is possible to additionally install the required carbon heater structure according to the capacity of the water during instant hot water, such as storage tank It is effective.

In addition, the carbon heater structure may be selectively mounted in accordance with the capacity of the storage tank or the output of the hot air fan to supply hot water or hot air regardless of the capacity, and select the length according to the depth of the storage tank or the hot air output. It is a very useful invention because the installation work is very easy and effective.

1 is a view showing a conventional carbon heater.
2 is a view showing a carbon heating element having a flange type structure according to the present invention.
3 is a view showing a boiler configured with a carbon heating element having a flange type structure according to the present invention.
Figure 4 is a view showing a plate vertically coupled with a carbon heating element having a flange-type structure according to the present invention.
Figure 5 is a side view of the boiler reservoir equipped with a carbon heating element having a flange-type structure according to the present invention.
Figure 6 is a view showing the length adjustment according to the boiler capacity configured carbon heating element having a flange-type structure according to the present invention.
7 is a view showing an instantaneous water heater equipped with a carbon heating element having a flange-type structure according to the present invention.
8 is a front view of a heater having a carbon heating element having a flange type structure according to the present invention;
9 is a side view of a heater having a carbon heating element having a flange type structure according to the present invention;
10 is a side view of a hot air fan configured with a carbon heating element having a flange type structure according to the present invention;
11 is a plan view of a hot air fan configured with a carbon heating element having a flange type structure according to the present invention.
12 is a front view of a hot air fan having a carbon heating element having a flange type structure according to the present invention;

The present invention for achieving the above object,

Carbon heater consisting of a removable flange that is formed long in the longitudinal direction, and coupled to maintain a vacuum inside one side of the carbon heating element and the carbon heating element in which the inner quartz tube is inserted into the inside of the predetermined space provided in a sealed cylindrical shape on one side It was achieved by providing a carbon heating element having a flange-type structure, characterized in that the power supply member is configured to only one side to allow the structure to generate heat.

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

Prior to this, terms or words used in the present specification and claims should not be construed as being limited to the common or dictionary meanings, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only one of the most preferred embodiments of the present invention, and do not represent all of the technical idea of the present invention, they can be replaced at the time of the present application It should be understood that there may be various equivalents and variations.

2 is a view showing a carbon heating element having a flange type structure according to the present invention.

As shown, the carbon heating element 120 having a flange-type structure according to the present invention is heated by electricity supply to the carbon fiber heating element 122 and the inner quartz tube 124 mounted in the vacuum-formed quartz tube 121. One or more carbon heater structures 100 are installed in a vertical type or a horizontal type at an upper portion of a storage space for generating a high temperature. In order to achieve this, the carbon heating element 120 coupled with the flange 110 is configured as a cartridge type on one side of the unit for fixing only one side of the power supply member 130 to generate heat, and when mounting in the horizontal longitudinal direction It has a flange-type structure that keeps the heat to radiate heat of high temperature.

At this time, the carbon heater structure 100 using the carbon fiber can be used in various ways for dissipating heat to the heater 310, instantaneous water heater 220, boiler 210, hot air fan 410, etc. as the carbon heating element 120. It is a structure that can be.

This, the carbon heater structure 100 is formed long in the longitudinal direction, one side is sealed and the other side is a structure in which the flange 110 is coupled to the open structure.

That is, the carbon heater structure 100 vacuums the inside to one side of the carbon heating element 120 in which the carbon fiber heating element 122 and the inner quartz tube 124 are inserted into a predetermined space provided in a cylindrical shape in which one side is sealed. It consists of a removable flange 110 that is coupled to hold.

Then, the carbon heater structure 110 is configured to only one side of the power supply member 130 to generate heat.

In addition, the carbon heater structure 110 is a power supply member 130 that allows the carbon fiber heating element 122 and the internal stone tube 124 to be electrically coupled to the flange 110 while being located inside the flange 110. The carbon heating element 120 is mounted to one side to complete one carbon heater structure 100, It has a heat generating structure by electricity supply made in only one direction.

At this time, the power supply member 130 for supplying power in one direction is connected to two power lines 128 at predetermined intervals.

Meanwhile, the carbon heater structure 100 includes a flange 110, a carbon heating element 120, and a power supply member 130.

First, the flange 110 to form a coupling hole on both sides to be coupled to the external device.

In addition, the carbon heating element 120 that forms a removable cartridge form on one side of the flange 110 is the carbon fiber heating element 122 and the inner quartz tube 124 is heated to the power supply connected to the flange 110 side It generates heat.

Here, it is made of a power supply member 130 configured on the flange 110 side to be directly connected to the carbon fiber heating element 122 and the internal quartz tube 124 to supply external power to the carbon heating element 120.

In this case, the power supply member 130 is directly connected to the carbon fiber heating element 122 and the internal stone tube 124 through the flange 110 while being connected to an external power source.

On the other hand, the carbon heating element 120 constituting the carbon fiber heating element 122 and the inner quartz tube 124 is composed of a quartz tube 121 forming the outside, the quartz tube 121 has a long shape in the longitudinal direction The interior forms a predetermined space, one side is finished in the form of a cap.

In addition, the carbon fiber heating element 122 accommodated in the quartz tube 121 has a filament structure in a wound form.

In addition, the inner quartz tube 124 is formed to be embedded in the carbon fiber heating element 122 in the longitudinal direction.

Here, molybdenum metal 126, which is a high temperature heating element, is supported on both sides of the carbon fiber heating element 122 and the inner quartz tube 124 to be electrically connected.

At this time, while being connected to the carbon fiber heating element 122 and the internal quartz tube 124, a pair of power lines 128 are extended to the flange 110 side to supply external power from only one side.

On the other hand, when the carbon heater structure 100 is described in detail, the carbon heating element 120 is made of quartz, the quartz tube 121 is closed in one side in the longitudinal shape in the longitudinal direction is composed of the appearance.

The quartz tube 121 is finished in a cap shape for maintaining a vacuum on one side, and a predetermined space is provided. The quartz tube 121 has a carbon fiber heating element 122 made of carbon fiber therein, and supplies power to the carbon heating element 120. It consists of an electrode etc. to supply.

The quartz tube 121 is made of quartz having high temperature heat resistance and durability to withstand high temperatures.

The quartz tube 121 is preferably a cylindrical tube made of quartz, but is not necessarily limited thereto, and may be a tube having sufficient heat resistance and strength such as a special glass tube.

In addition, the quartz tube 121 is a tubular shape having a long length, the lower part is closed and the upper part is opened to connect with the power supply device to the upper part.

The carbon fiber heating element 122 accommodated in the quartz tube 121 has a wound filament structure.

The carbon heating element 120 is configured inside the coil shape having a predetermined diameter.

At this time, the inner quartz tube 124 is embedded in the carbon heating element 120 in the longitudinal direction to be composed of the carbon fiber heating element 122.

The carbon fiber heating element 122 and the inner quartz tube 124 of the carbon heating element 120 are molybdenum metal 126, which is a high temperature heating element located inside the quartz tube 121, and the carbon fiber heating element 122 and the inner quartz tube. It is fixed to the connection with (124).

In addition, the carbon fiber heating element 122 of the carbon heating element 120 and the internal quartz tube 124 is configured to be connected to the power supply member 130 by a connection piece made of molybdenum metal 126 at the position supplied with power.

Then, a pair of power lines 128 are connected to the carbon fiber heating element 122 and the inner quartz tube 124, respectively, and extend to one side to stably supply external power.

As such, the carbon fiber heating element 122 and the inner quartz tube 124 are configured inside the quartz tube 121 of the carbon heating element 120, and the flange 110 is finished on one side of the quartz tube 121. Combined.

The flange 110 is configured to be coupled to seal the inside in a vacuum state inside the quartz tube 121.

That is, since the inside of the quartz tube 121 is in a vacuum state, the carbon heating element 120 is spirally wound around the outer circumferential surface of the inner quartz tube 124, so that the carbon heating element 120 having a long length can be applied. The heat generation efficiency of the structure 100 can be significantly improved.

Such a carbon heating element having a flange-type structure of the present invention can be applied to the boiler 210, the instant water heater 220, the heater 310 and the hot air fan 410 in a simple structure.

In addition, referring to the first embodiment in which the carbon heating element having the flange-type structure of the present invention is applied to the boiler 210 or the instantaneous water heater 220, the boiler 210 is illustrated in FIGS. 3 and 5 to 6. Alternatively, as shown in FIG. 7, the water may be mounted in a configuration for heating the hot water of the instantaneous high temperature, such as the instantaneous water heater 220.

Specifically, the carbon heater structure 100 is vertically fixed to the upper portion of the storage unit 230 for receiving the water to supply the heating water of the boiler 210 or the hot water of the instant water heater 220. ) Is installed in one or more, and the flange 110 is fixed to the plate 240 to be mounted and detached while standing in the vertical longitudinal direction, the power supply member 130 to allow the carbon heater structure 100 to generate heat ) Consists of only one side.

That is, the carbon fiber heating element 122 mounted in the vacuum-formed quartz tube 121 and the carbon heater structure 100 heated by electricity supply to the inner quartz tube 124 of the storage unit 230 that can receive water. One or more installed from the top downward, coupled to the plate 240 so as to stand in the vertical longitudinal direction, and fixed to, and the heat generating from the carbon heating element 120 coupled with the flange 110 to be detachable to the plate 240 I would have to.

The carbon heater structure 100 is to make hot water by instantaneous heating of the water stored in the storage unit 230.

The carbon heater structure 100 is a plate-shaped body located on the upper side of the storage unit 230 for storing water to supply high temperature water to supply the heating water of the boiler 210 or the hot water of the instant water heater 220. At least one carbon heater structure 100 is vertically mounted in the fixed through hole 242 provided in the plate 240.

In addition, while the carbon heating element 120 portion of the carbon heater structure 100 faces downward, the lower end of the carbon heater structure 100 is immersed in water.

In this way, when the power is supplied in a state where the portion of the carbon heating element 120 is obtained in water, the stored water is instantaneously heated.

This, the carbon heater structure 100 As shown in FIG. 4, a plate 240 and a flange 110, a carbon heating element 120, and a power supply member 130 are mounted to the storage unit 230.

First, the plate 240 is provided with one or more fixed through holes 242 for mounting the carbon heater structure 100 vertically in a cartridge type while being horizontally mounted in a plate-shaped body on the upper portion of the storage unit 230 for storing water. do.

While mounting the carbon heater structure 100 vertically to the fixed through-hole 242 of the plate 240, the flange 110, which is mounted to protrude upwardly above the plate 240, is mounted on at least one plate 240 It is composed of a device for supplying external power.

In addition, the carbon heating element 120 to form a vertical coupling in the form of a removable cartridge to the flange 110 allows the carbon fiber heating element 122 and the inner quartz tube 124 to be heated to the power supply.

At this time, the power supply member 130 configured at the upper portion to be connected to the carbon fiber heating element 122 and the internal quartz tube 124 to supply external power to the carbon heating element 120 is configured inside the flange 110.

In this way, the carbon heating element 120 is a quartz tube 121, the internal quartz tube 124 and the carbon fiber heating element 122, the power supply member 130 to be electrically coupled to the flange 110 is formed therein While located inside the flange 110 is a carbon heater structure 100 is completed by mounting the carbon heating element 120 to one side, each carbon heater structure 100 in the fixed through-hole 242 of the plate 240 Is mounted vertically.

Here, at least one carbon heater structure 100 is mounted in an upright state in the fixed through hole 242 of the plate 240, and at least one carbon heater structure 100 is maintained in a state in which one side is immersed in water.

 The carbon heater structure 100 is characterized in that the power is supplied only in one direction.

At this time, the power supply member 130 for supplying power in one direction is connected to two power lines 128 at predetermined intervals.

On the other hand, since the power supply is configured to be made only on one side among the features of the carbon heater structure 100, it is possible to attach and detach the plate 240 in the form of a cartridge. Concerns do not arise.

In addition, the plate 240 can be mounted in a plurality of vertically configured in the easy to replace, easy to replace, additional mounting, required carbon heater structure 100 according to the capacity of the water at the moment of hot water, such as storage unit 230 Will be added.

Thus, the carbon heater structure 100 is configured to be instantaneous high temperature heat generation, the water in the storage unit 230 can be changed to instant hot water.

In addition, the carbon heater structure 100 is mounted to a plurality of plates 240, but arranged to be spaced apart at an appropriate interval so as to emit radiant heat at a constant temperature.

Here, the carbon heater structure 100 may be mounted in a vertical structure on the flange 110, but may be equipped with a carbon heater structure 100 having a corresponding length according to the depth of the storage unit 230 storing water.

As such, the carbon heater structure 100 is mounted in a vertical shape in the storage unit 230, and one carbon heater structure 100 takes about 5 to 7 minutes to heat 20 L of water to 100 ° C on average. .

As such, the carbon heater structure 100 may be selectively mounted in accordance with the capacity of the storage unit 230 as shown in FIG. 6 to enable rapid heating of hot water regardless of the capacity, and to the depth of the storage unit 230. The installation work is very simple, as the length can be selected and mounted accordingly.

Meanwhile , referring to the second embodiment in which the carbon heating element having the flange-type structure of the present invention is applied to the heater 310, it is mounted in a configuration for heating with the heater 310 as shown in FIGS. 8 and 9. Can be.

Specifically, the heater 310 for dissipating high-temperature heat by mounting the carbon heater structure 100 to be detachable in a cartridge type has a predetermined height and can be adjusted in length, while the front forms an open structure. For the sake of safety, a safety net 340 is mounted.

And, the protective film 320 for mounting and mounting the carbon heater structure 100 on the rear side is provided with one or more carbon heater structure 100 is fixed horizontally in the cartridge type on one side inside.

The protective film 320 is fixed to the flange 110 is coupled to the support unit 330 for coupling so that the carbon heater structure 100 is detachable from one side of the protective film 320 supporting the heat generating rear surface, the carbon heater structure Only one side of the power supply member 130 to allow 100 to generate heat.

That is, the carbon heater structure 100 is mounted in a plurality of horizontally on the inner protective film 320 in the same structure as the heater 310, the mounting is configured to be detachable in the cartridge type to one side inside the heater 310.

While the carbon heater structure 100 is horizontally mounted in plural, the carbon heating element 120 generates heat by external power supply to radiate heat to the outside.

In addition, the heater 310 having a plurality of the carbon heater structure 100 maximizes the advantages of the carbon fiber heating element 122 of the carbon heater structure 100 having excellent heat generating performance and power saving performance, and provides a comfortable space.

In addition, referring to the third embodiment in which the carbon heating element having the flange-type structure of the present invention is applied to the hot air blower 410, the air is heated at high temperature like the hot air blower 410 as shown in FIGS. 10 and 11 to 12. Heating can be mounted to a configuration for discharging hot air.

Specifically, the carbon heater structure 100 is a hot air blower to heat the hot wind by mounting the carbon heater structure 100 to the heat blower 410 to be detachable in a cartridge type to heat the hot air. One or more carbon heater structures 100 are horizontally fixed in a cartridge type on one side of the inner tube 420 of the 410.

In addition, the flange 110 is coupled and fixed to the fixing unit 430 coupled to be detachable from one side of the inner tube 420 of the hot air fan 410, the power supply to allow the carbon heater structure 100 to generate heat By forming the member 130 to one side only the wind generated from the fan is heated to a high temperature by the carbon heater structure 100 is discharged through the discharge port 440.

The hot air blower 410 constituting the carbon heater structure 100 has good thermal efficiency because the introduced air can be discharged while being sufficiently warmed by the carbon heater structure 100.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto, and the technical idea of the present invention and the following by those skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of equivalents of the claims to be described.

100: carbon heater structure 110: flange
120: carbon heating element 121: quartz tube
122: carbon fiber heating element 124: internal quartz tube
124: molybdenum metal 128: power line
130: power supply member 210: boiler
220: instantaneous water heater 230: storage unit
240: Plate 242: Fixed hole
310: heater 320: protective film
330: support unit 340: safety net
410: hot air fan 420: inner tube
430: fixed unit 440: discharge outlet

Claims (10)

In the carbon heating element formed long in the longitudinal direction and sealed on one side,
A quartz tube formed in a predetermined shape in an elongated shape in a longitudinal direction, and one side of which is closed in a cap shape;
A carbon fiber heating element having a wound filament structure accommodated in the quartz tube;
An internal quartz tube long embedded in the carbon fiber heating element in a longitudinal direction;
Molybdenum metal which is a high temperature heating element on both sides of the carbon fiber heating element and the inner quartz tube;
A pair of power lines connected to the carbon fiber heating element and the inner quartz tube, respectively, extending to one side to supply external power from only one side;
A power supply member configured at a flange side to be directly connected to a carbon fiber heating element and an internal quartz tube to supply external power to the carbon heating element;
The power supply member is located inside the flange, and the heating water of the boiler, the instantaneous water heater in the form of a cartridge that is coupled to maintain the vacuum inside one side of the carbon heating element is inserted into the carbon fiber heating element and the inner quartz tube inside the quartz tube. A removable flange installed at least one carbon heater structure vertically fixed to an upper portion of the storage unit accommodating water so as to supply hot water, and coupled to the plate to be detachable while standing vertically; in Carbon heating element having a flange-type structure, characterized in that configured.
delete delete delete delete The method of claim 1,
A storage unit storing water for supplying hot water so as to supply heating water of the boiler or hot water of the instant water heater;
A plate of plate-shaped body mounted on the storage unit and provided with at least one fixed through hole for vertically mounting the carbon heater structure in a cartridge type;
Carbon plate heating element having a flange-type structure, characterized in that the carbon heater structure is mounted on the plate while being obtained in the storage unit and mounted vertically in the boiler or instantaneous water heater.
The method of claim 1,
At least one carbon heater structure is mounted in an upright state in the fixed through-hole of the plate, the at least one carbon heater structure is a carbon heating element having a flange-type structure, characterized in that the bottom is immersed in water.
The method of claim 1,
The carbon heater structure,
A carbon heating element having a flange-type structure, characterized in that mounted on the flange in a vertical structure, but equipped with a carbon heater structure having a corresponding length in accordance with the depth of the storage portion for storing water.
The method of claim 1,
The carbon heater structure,
At least one carbon heater structure which is horizontally fixed in a cartridge type is installed at one inner side of the heater to dissipate high temperature heat, and the flange is supported on the support unit for attaching and detaching at one side of the protective film supporting the rear surface of the heat. Is coupled and fixed, the carbon heating element having a flange-type structure, characterized in that the carbon heater structure consisting of only one side of the power supply member to allow the carbon heater structure to generate heat.
The method of claim 1,
The carbon heater structure,
One or more carbon heater structures are horizontally fixed in a cartridge type on one side of the inner tube of the heat blower to dissipate high-temperature wind, and the flange is coupled to and fixed to the fixing unit for attaching and detaching the inner tube. Carbon heating element having a flange type structure, characterized in that the wind power generated by the fan is heated to a high temperature by the carbon heater structure is discharged through the discharge port by configuring only one side of the power supply member for the carbon heater structure to generate heat .

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