KR20190041157A - SiC FIBER HEATING ELEMENT STRUCTURE AND HEATING SYSTEM - Google Patents

Abstract

The present invention relates to a SiC fiber heating body structure and a heating system, wherein the SiC fiber heating body structure according to the present invention includes a quartz tube sealed in a vacuum state and an elongated SiC fiber heating body provided inside the quartz tube, and the SiC fiber heating body is heated by microwaves applied from the outside and a radiant heat is transmitted to the outside of the quartz tube.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a SiC fiber heating body structure,

The present invention relates to a SiC fiber heating element structure and a heating system. More particularly, the present invention relates to a SiC fiber heating element structure, and more particularly to a SiC fiber heating element structure and a heating system, The present invention relates to a fiber heating body structure and a heating system using the same.

SiC fiber is a reinforcing material of representative ultra high temperature ceramics fiber reinforced composite material and maintains structural characteristics of high strength, high toughness, corrosion resistance and high reliability under high temperature and high pressure and harsh environment. In particular, long- fiber reinforced composite materials have the greatest toughness enhancement effect compared to other composite materials such as granularity and needle-like crystalline strengthening. Therefore, they can be applied to industrial fields for extreme environments requiring high reliability such as aerospace, Is the essential material of. In recent years, the application has been expanding not only as a material for composites but also for the defense industry, automobile and aerospace industry.

In addition, iodine-doped nanostructured SiC fibers are activated by microwaves and can be rapidly heated up to 1400 ° C in the air. Because the heat generated is highly economical due to the radiation characteristic, recently, a heating system using SiC fiber as a heating element This is receiving attention.

The SiC fiber is made of a preceramic polymer known as polycarbosilane, which is made into a fibrous (polycarbosilane fiber) by melt spinning or electrospinning, and then heat- ) Fibers to inorganic (ceramic) fibers.

However, although the melting point of the polycarbosilane is usually 150 to 300 ° C, when the polycarbosilane fiber is heat-treated immediately after spinning, the fibrous phase is not retained in the melting temperature range and is melted. To prevent this phenomenon and maintain the fiber phase during the heat treatment to bond the polymer molecules present on the surface of the fiber through the so-called cross-link to obtain the final SiC fiber, the melting point of the cross- , Which is 400 ° C or higher. Therefore, it does not melt in the heat treatment process and maintains the completely fibrous phase, and finally it is made of SiC fiber.

This process is called a curing or infusibilization process, and various stabilization methods have been proposed. Typical methods include THERMAL OXIDATION CURING and E-BEAM CURING. In the case of the former, if the polycarbosilane fibers obtained by spinning are maintained in an oxidizing atmosphere of 150 to 250 ° C for an extended period of time (usually at 200 ° C in an air atmosphere), weak bonding of polymer molecules in the air, Bonds and other Si-CH3 bonds to form Si-O-Si bonds. In this process, cross-linking between the respective molecules occurs. This method is the most typical stabilization method, and Japan's NICALON-based CERAMIC GRADE fiber and TYRANNO fiber use oxidation stabilization method.

However, this method requires a long period of time for stabilization (typically 4 to 10 hours in consideration of the heating rate), and 10 to 20% of oxygen incorporated by crosslinking during stabilization is not stable at a high temperature of 1200 ° C or more, There is a disadvantage in that the high-temperature properties of the SiC fiber are greatly deteriorated.

In terms of fiber spinning, the spinning temperature of the fiber should be at least 30 to 60 ° C higher than the usual stabilizing temperature of 200 ° C to maintain the fibrous phase in the process of oxidative stabilization and to exhibit the oxidation effect. On the other hand, when the melt spinning temperature is higher than 270 ~ 290 ℃, stability of the melt is lowered and the spinning condition is not easy to control. In addition, stretching in spinning is not smooth,

For this reason, it is necessary to precisely control the flow and deformation of the raw material precursor polymer, which makes the production process of the raw material more complicated and raises the cost of the raw material. In the case of electron beam stabilization, irradiating an electron beam to a fiber breaks the intermolecular bonds on the surface, thereby forming a radical. Since these radicals are not stable in the atmosphere, they tend to bind to each other and return to a stable state. In such a recombination process, crosslinking between polymer molecules is formed. Oxygen is not mixed and heat treatment can be carried out at 1600 DEG C or higher, and thus SiC fibers having excellent physical properties can be obtained, and thus it is applied to Japanese HI-NICALON type fibers. However, since the control of the process is difficult and the manufacturing cost is high, there is a limit to the application to a general continuous mass production process.

Korean Patent Publication No. 10-1209110 discloses a method for producing SiC fibers by spinning polycarbosilane to prepare polycarbosilane fibers in order to solve the above problems. Stabilizing the polycarbosilane fiber with a gas fumigation method using a halide-based gas; And a firing step of heat-treating the stabilized polycarbosilane fiber.

In the case of the prior art using SiC fibers made of a heating element, for example, in Korean Patent Laid-Open Publication No. 10-2017-0087380, a sublimation raw material and carbon fiber selected from silicon or silicon dioxide, or a mixture thereof, And a silicon carbide fiber heating element which is disposed in an atmosphere and a high temperature state and is made from carbon fiber by sublimation of sublimation raw material gas infiltration reaction (gas infiltration reaction) and generates heat by applying microwaves.

However, when such a conventional SiC fiber is used as a heating element, the microwave is irradiated by the magnetron to generate heat in the produced SiC fiber, and thus the SiC fiber is oxidized or deformed in a long- And it is difficult to fabricate SiC fibers in various forms in accordance with the purposes of large-scale heating and heat generation. In addition, even if SiC fibers are made of heat-generating materials, shapes and sizes of heat-generating materials are not uniform. There is a problem that it is difficult to fabricate a heat generating structure.

Korean Patent Publication No. 10-1209110 Korean Patent Publication No. 10-2017-0087380

Accordingly, it is an object of the present invention to provide a SiC fiber heating element structure that does not deteriorate even when used for a long period of time, does not cause oxidation, and does not deteriorate heat generation efficiency.

It is another object of the present invention to provide a heating system having a superior heating effect by irradiating a microwave on a SiC fiber heating element structure manufactured by the present invention.

      The present invention includes the following embodiments in order to achieve the above object.

The SiC fiber heating body structure according to the present invention comprises a quartz tube sealed in a vacuum state and a long elongated SiC fiber heating body provided inside the quartz tube, and the SiC fiber heating body is heated by the microwave applied from the outside , And radiating heat to the outside of the quartz tube.

Further, the heating system according to the present invention is characterized by comprising a long elongated SiC fiber heating body structure provided in a quartz tube sealed in a vacuum state, provided in a chamber, and a magnetron for irradiating a microwave into the chamber.

The present invention can provide a SiC fiber heating body structure in which the SiC fiber heating body is deformed, oxidation is not generated, and heating efficiency is not lowered.

The present invention can provide a heating system having an exothermic effect by irradiating a microwave on a SiC fiber heating element structure.

The present invention can be applied to a heating system by fabricating a SiC fiber heating element structure in various forms according to the heating purpose, so that the use field of the heating system can be widened.

FIG. 1 is a view for explaining a process for producing a SiC fiber according to the present invention with a heating element.
2 is a view for explaining a process for manufacturing a SiC fiber heating element structure according to the present invention.
3 is a view showing a state in which SiC fiber heating body structures are arranged on a bracket according to an embodiment of the present invention.
4 is a view showing a SiC fiber heating body structure according to another embodiment of the present invention.
5 is a side view of a heating system using a SiC fiber heating body structure according to an embodiment of the present invention.
6 is a front view of a heating system using a SiC fiber heating body structure according to an embodiment of the present invention.
7 is a block diagram for explaining the operation of the control unit in the heat generation system according to the embodiment of the present invention.

      DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a SiC fiber heating element structure and a heating system using the same according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a view for explaining a process for producing a SiC fiber according to the present invention with a heating element. Referring to FIG. 1, in order to produce SiC fiber as a heating element, polycarbosilane (molecular weight Mw = 3,000 to 4,000), which is a polymer, is first melt-spun by a conventional method to produce a polycarbosilane fiber. (B) After the polycarbosilane is dissolved as a starting material, it is spun into a yarn. (B) Then, a chemical treatment with iodine is performed to dope the prepared yarn (C). Specifically, The fibers are charged in a constant heating chamber in order to apply heat to the vicinity of 200 to 300 ° C in a nitrogen atmosphere. At this time, a certain amount of iodine in a solid state is added together, and the mixture is heated to 200 to 300 ° C in a nitrogen atmosphere. When the temperature is heated to about 200 to 300 ° C, the iodine gasifies and reacts in the polycarbosilane fiber to induce insolubilization of the polycarbosilane fiber, resulting in a doped state after the heat treatment. After the above process, the incompatible polycarbosilane fiber is put into a mold having a certain shape, and heat treatment is performed at 1000 to 1350 ° C in an inert atmosphere to convert the polymer polycarbosilane fiber into SiC fiber through thermal decomposition. That is, a graphite mold to be formed is made, a chemically treated polycarbosilane fiber is put in and a heat treatment is performed (D) to produce a SiC fiber heating body. (E)

2 is a view for explaining a process for manufacturing a SiC fiber heating element structure according to the present invention. 2, the quartz tube 11 is prepared in consideration of the size of the SiC fiber heating body 12 manufactured by using the SiC fiber. (A) The quartz tube 11 is made of a commercially available product Lt; / RTI > A small quartz tube is connected to the middle of the quartz tube (11) after putting the SiC fiber heating body (12) in the prepared quartz tube (11). (B) After a small quartz tube is connected to the middle of the quartz tube 11 as described above, heat is applied to both ends of the quartz tube 11 to heat the quartz tube 11 in a hot state (C) Thereafter, the small quartz tube is removed, and the hole of the quartz tube 11 is sealed by welding to form a quartz tube (D ), And a heater bar-shaped SiC fiber heating element structure incorporating a SiC fiber heating element is completed (E)

2 is a process for manufacturing a SiC fiber heating body structure 10 in the form of a heater bar. However, as is obviously expected from the above description, the SiC fiber heating body structure 10 is formed of various types of quartz tubes 11, Can be manufactured. The heating operation in the SiC fiber heating body structure 10 as described above is such that the inside of the quartz tube 11 is vacuum and the heat of the SiC heating body 12 by microwave irradiation is transmitted to the outside of the quartz tube 11, Convection or conduction of the medium (air or fluid) surrounding the quartz tube 11 is performed.

3 is a view showing a state in which SiC fiber heating body structures are arranged on a bracket according to an embodiment of the present invention. 3, the bracket 20 in which the SiC fiber heating body structures 10 are disposed is composed of an upper bracket 21 and a lower bracket 22, and a connection bracket 22 connecting the upper bracket 21 and the lower bracket 22, (23). A plurality of holes 26 are formed in the upper bracket 21 and the lower bracket 22. Both end portions 11-1 of the quartz tube 11 in which the SiC fiber heating body 12 is embedded are inserted into holes 26 And is fixed to the upper bracket 21 and the lower bracket 22. Therefore, the quartz tube 11 in which the plurality of SiC fiber heating bodies 12 are embedded can be fixed to the bracket 20. [ At least one rib 24 is formed on the outer circumferential surface of the connection bracket 23 and at least one hole 25 is formed in the rib 24 so that the fixing bracket 33 of the heating system 100, And may be installed in the chamber 30 of the heat generation system 100 by inserting it into the hole 25.

4 is a view showing a SiC fiber heating body structure according to another embodiment of the present invention. In the above embodiment, the rod-shaped SiC fiber heating body structure 10 has been described. However, since the quartz tube 11 can be manufactured in various forms as described above, it is possible to manufacture a tube having a plurality of curved rounding shapes The SiC fiber heating body structure 10 can be manufactured by manufacturing the quartz tube 11 with the SiC fiber heating body 12 inside the quartz tube 11. The SiC fiber heating body structure 10 of this type is provided at both ends 11-1 of the SiC fiber heating body structure 100 in the chamber 30 of the heating system 100 without a separate bracket 20 as shown in Fig. A sufficient heat generating effect can be obtained without installing a plurality of SiC fiber heating body structures 10 as shown in Fig.

 FIG. 5 is a side view of a heating system using a SiC fiber heating body structure according to an embodiment of the present invention, and FIG. 6 is a front view of a heating system using a SiC fiber heating body structure according to an embodiment of the present invention. 5 and 6, a heating system 100 using a SiC fiber heating body structure 10 according to the present invention includes a SiC fiber heating body structure (see FIGS. 5 and 6) in which a plurality of SiC fiber heating bodies 12 are embedded in a chamber 30 At least one or more brackets 20 are fixed. The bracket 20 to which the SiC fiber heating element structure 10 with the SiC fiber heating body 12 is fixed can be installed by a separate fixing bracket 33 provided in the chamber 30. [ At least one magnetron (40) is installed outside the side surface of the chamber (30). The magnetron 40 generates a microwave for generating heat of the SiC fiber heating element structure 10 and the magnetron 40 and the chamber 30 are communicated with each other by a waveguide 41, Is transmitted to the SiC fiber heating body structure 10 in the chamber 30 through the waveguide 41 and the heat generated in the SiC fiber heating body structure 10 is radiated to the outside and the microwave generated in the chamber 30 ) Is converted into high-temperature air by convection. In the case where the magnetron 40 is provided outside the side surface of the chamber 30 as described above, the temperature difference between the region where the microwave is applied and the region opposite thereto by the wave guide 41 in the chamber 30 can be large, Two or more magnetrons 40 may be provided outside the opposite sides of the chamber 30 to apply microwaves to both sides of the chamber 30 through the waveguide 41, So that the magnetron is irradiated so as to communicate with the both side surfaces of the chamber 30, so that a uniform heating effect can be obtained without generating a temperature deviation.

According to the embodiment, an air inlet 50 and an air outlet 60 are installed on one side of the chamber 30, and air is introduced through the air inlet 50. An intake port damper 51 is provided at a predetermined position of the intake port 50 to control an inflow amount of the air under the control of a control unit 70 described later. The exhaust port 60 is arranged in a predetermined position of the exhaust port 60. The exhaust port 60 is connected to the exhaust port 60 through the exhaust port 60, A damper 61 is provided so that the amount of exhausted air can be adjusted by the control of a control unit 70 which will be described later.

In addition, according to the embodiment, the heating system 100 according to the present invention can move the heating system 100 to a required place easily by providing a moving means 35 on the lower surface of the chamber 30.

The embossing plate 34 having a plurality of recessed shapes may be attached to at least one outer circumferential surface of the chamber 30 to reduce heat loss in the chamber 30 according to the embodiment.

7 is a block diagram for explaining the operation of the control unit in the heat generation system according to the embodiment of the present invention. 7, a heating system 100 according to the present invention includes a sensor 30 for measuring an internal temperature of a chamber 30 to measure a temperature inside the chamber 30, It is possible to adjust the temperature inside the chamber 30 to a desired temperature by controlling the temperature control fan 32 by the control unit 70 of the heating system 100 by providing a temperature control fan 32 in the chamber 30.

The heating system 100 according to the embodiment of the present invention may be provided with a sensor 62 for measuring the exhaust temperature at a predetermined position of the exhaust port 60 between the exhaust damper 61 and the chamber 30, The control unit 70 controls the exhaust damper 61 to adjust the amount of the exhausted air.

According to the embodiment, the heating system 100 according to the present invention can control the amount of air introduced into the chamber by controlling the intake port damper 51 by the control unit 70. FIG.

The heating system 100 according to the embodiment of the present invention may be configured such that a blower 63 is installed at a predetermined portion of the exhaust port 60 and the control unit 70 controls the blower 63 to control the speed Can be adjusted.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims and their equivalents. Of course, such modifications are within the scope of the claims.

100: Heating system 10: SiC fiber heating structure
11: quartz tube 11-1: end
12: SiC fiber heating body 20: Bracket
21: upper bracket 22: lower bracket
23: connection bracket 24: rib
25: hole 26: hole
30: chamber 31: sensor for measuring internal temperature
32: Temperature control fan 33: Fixing bracket
34: Embo plate 35: Moving means
40: Magnetron 41: Waveguide
50: intake port 51: intake port damper
60: exhaust port 61: exhaust port damper
62: Sensor for exhaust temperature measurement
63: blower 70:

Claims (18)

A quartz tube sealed in a vacuum state, and a SiC fiber heating element provided in the quartz tube,
Wherein the SiC fiber heating body generates heat by a microwave externally applied and transmits radiant heat to the outside of the quartz tube. The method according to claim 1,
Wherein the SiC fiber heating body has a long elongated shape. The method according to claim 1,
The SiC fiber heating element is produced by dissolving polycarbosilane as a starting material, spinning it to produce a yarn, chemically treating it with iodine, forming a graphite mold in a desired shape, adding chemically treated polycarbosilane fibers and heat- Wherein the SiC fiber heating body structure is made of a thermoplastic resin. The method according to claim 1 or 3,
Wherein the quartz tube has a cylindrical shape. The method according to claim 1 or 3,
Wherein the quartz tube has at least one bent rounded shape. Characterized by comprising a SiC fiber heating body structure provided in a chamber and including a SiC fiber heating body provided in a quartz tube sealed in a vacuum state and a magnetron for irradiating a microwave into the chamber. The method according to claim 6,
Wherein the SiC fiber heating body has a long elongated shape. 8. The method according to claim 6 or 7,
Wherein at least one hole is formed in the upper bracket and the lower bracket inside the chamber and a bracket having a connection bracket connecting the upper bracket and the lower bracket, wherein both ends of the SiC fiber heating element structure are inserted into the holes of the bracket Wherein the heating system comprises: 8. The method according to claim 6 or 7,
Wherein the bracket to which the SiC fiber heating element structure is fixed is installed by a separate fixing bracket installed in the chamber. 8. The method according to claim 6 or 7,
Wherein the magnetron and the chamber are communicated by a waveguide. 8. The method according to claim 6 or 7,
Wherein at least two or more magnetrons are provided so as to face each other with the chamber therebetween. 8. The method according to claim 6 or 7,
Wherein a temperature measuring sensor is provided in the chamber and a temperature controlling fan is provided on one side of the chamber to control a temperature inside the chamber under the control of the controller. 8. The method according to claim 6 or 7,
And a moving means is provided on the lower surface of the chamber. 8. The method according to claim 6 or 7,
Characterized in that an embossed plate having a plurality of recessed shapes is attached to at least one outer peripheral surface of the chamber. The method according to claim 6,
And a suction port and an exhaust port are provided on one side of the chamber. 16. The method according to claim 6 or 15,
Wherein an inlet port damper is provided at a predetermined position of the inlet port to adjust an inflow amount of the air under the control of the control section. 16. The method according to claim 6 or 15,
Wherein a vent damper and a sensor for measuring an exhaust temperature are provided at predetermined positions of the exhaust port to regulate the exhaust amount of air under the control of the control section. 16. The method according to claim 6 or 15,
Wherein a blower is provided at a predetermined position of the exhaust port to regulate the speed of air exhausted under the control of the control unit.

Images