CN113374989A - Nano-micropore vacuum heat insulation device for high-temperature-resistant kiln - Google Patents

Abstract

The invention belongs to the field of vacuum heat insulation, and particularly relates to a nano micropore vacuum heat insulation device for a high temperature resistant kiln, which comprises a nano micropore plate, a first vacuum plate, a second vacuum plate, a rectangular rod, a T-shaped round rod, an L-shaped groove, a sliding block, a flat head bolt, a first spring, a square block, an oval rod, an oval block, a rotating pin, a torsional spring, a first magnetic block, a second magnetic block, a U-shaped rod, a clamping block, a second spring and an adjusting bolt; install vacuum plate two inside the U type region, make the rectangular rod install inside the rectangular channel, make circular through-hole on the rectangular rod align with the cylinder groove of rectangular channel inside, insert vacuum plate one inside with T type round bar, make T type round bar bottom pass circular through-hole entering cylinder inslot, T type round bar bottom gets into the cylinder inslot, make the slider remove along the perpendicular groove in L type groove, when the slider removes to perpendicular groove end, the user rotates T type round bar, make the slider remove the horizontal inslot portion that gets into L type groove, and then with T type round bar one end joint inside the cylinder inslot.

Description

Nano-micropore vacuum heat insulation device for high-temperature-resistant kiln

Technical Field

The invention relates to the field of vacuum heat insulation, in particular to a nano micropore vacuum heat insulation device for a high temperature resistant kiln.

Background

The vacuum heat-insulating plate (VIP plate) is one of vacuum heat-insulating materials, is formed by compounding a filling core material and a vacuum protection surface layer, and effectively avoids heat transfer caused by air convection, so that the heat conductivity coefficient can be greatly reduced.

The vacuum heat insulation device can effectively reduce heat transfer, the heat insulation effect of the vacuum heat insulation device can be further improved by adding the nano micropore plate on the outer side of the vacuum plate, but the nano micropore plate is generally fixedly installed on the vacuum heat insulation plate through bolts, and the vacuum heat insulation device is inconvenient to disassemble, assemble and maintain.

The vacuum heat insulation device that uses at present has certain defect, lacks the convenient installation mechanism of nanometer micropore board, causes inconveniently to carry out the dismouting to the nanometer micropore board and maintains. Therefore, the nano micropore vacuum heat insulation device for the high temperature resistant kiln is provided aiming at the problems.

Disclosure of Invention

The invention provides a nano micropore vacuum heat insulation device for a high temperature resistant kiln, aiming at making up for the defects of the prior art and solving the problems that the currently used vacuum heat insulation device has certain defects, lacks a convenient installation mechanism of a nano micropore plate and is inconvenient to assemble, disassemble and maintain the nano micropore plate.

The technical scheme adopted by the invention for solving the technical problems is as follows: the invention relates to a nano micropore vacuum heat insulation device for a high temperature resistant kiln, which comprises a nano micropore plate, a vacuum plate I, a vacuum plate II and a connecting mechanism, wherein the nano micropore plate I is arranged on the vacuum plate II; the first vacuum plates are three, the first vacuum plates form a U-shaped area in a surrounding mode, two second vacuum plates are symmetrically arranged in the U-shaped area, and nano-porous plates are arranged at one ends, far away from the second vacuum plates, of the first vacuum plates and on the outer sides of the second vacuum plates;

the connecting mechanism comprises a rectangular rod and a T-shaped round rod, a rectangular groove is formed in one end, close to two ends of the vacuum plate, of the vacuum plate I, the rectangular rod is fixedly mounted at each of the left end and the right end of the vacuum plate II, the rectangular rod is mounted inside the rectangular groove, the T-shaped round rod is mounted at the top end of the vacuum plate I, the cylindrical groove is formed in the bottom end of the rectangular groove, the bottom end of the T-shaped round rod penetrates through the rectangular rod and extends to the inside of the cylindrical groove, the vacuum plate II is mounted inside a U-shaped area, the rectangular rod is mounted inside the rectangular groove, a circular through hole in the rectangular rod is aligned with the cylindrical groove in the rectangular groove, the T-shaped round rod is inserted into the vacuum plate I, and the bottom end of the T-shaped round rod penetrates through the circular through hole to enter the cylindrical groove.

Preferably, two sliding blocks are symmetrically arranged on the annular side surface of the T-shaped round rod, two L-shaped grooves are symmetrically formed in the cylindrical groove, and the sliding blocks are arranged in the L-shaped grooves; inside T type round bar bottom got into the cylinder inslot for the slider removed along the perpendicular groove in L type groove, when the slider removed to perpendicular groove end, user of service rotated T type round bar, made the slider remove the horizontal inslot portion that gets into L type groove, and then with T type round bar one end joint inside the cylinder inslot.

Preferably, a circular through hole is formed in the top end of the rectangular rod, two strip-shaped holes are symmetrically formed in the circular through hole, the size of the cross section of each strip-shaped hole is the same as that of the cross section of the sliding block, and a T-shaped round rod is mounted in the circular through hole; the design of circular through-hole is convenient for T type round bar to pass rectangular pole, and the design of bar pole is convenient for the slider to pass circular through-hole.

Preferably, the L-shaped groove consists of a vertical groove and a transverse groove, two vertical grooves and two transverse grooves are symmetrically formed in the cylindrical groove, the bottom end of the vertical groove is communicated with one end of the transverse groove, and a sliding block is arranged in the transverse groove; the design in L type groove is convenient for with the slider joint in the cylinder inslot portion, and then with T type round bar bottom joint in the cylinder inslot portion.

Preferably, a flat head bolt is installed at the top end of the T-shaped round rod, a first nut is installed on the annular side face of the flat head bolt, the outer side of the first nut is fixedly installed inside the T-shaped round rod, an accommodating groove is formed in the lower end of the T-shaped round rod, a first spring is fixedly installed at the top end inside the accommodating groove, a square block is fixedly installed at the bottom end of the first spring, the bottom end of the square block extends into the cylindrical groove, and the bottom end of the flat head bolt penetrates through the T-shaped round rod and is attached to the top end of the square block; when the slider moves to the transverse groove end, the square bottom aligns with the square groove, then the flat-head bolt is screwed, the flat-head bolt moves along the nut I, the flat-head bolt moves to drive the square to move, the square moves to enter the square groove, the top of the square is located inside the accommodating groove at the moment, the T-shaped round rod is prevented from rotating, the slider is prevented from being separated from the L-shaped groove, the square moves to stretch the spring I, the elastic force of the spring I is convenient for the square to move and reset, and meanwhile the elastic force of the spring I prevents the flat-head bolt from being loosened.

Preferably, a square groove is formed in the bottom end of the inner portion of the cylindrical groove, the size of the cross section of the square groove is the same as that of the cross section of the square block, and the bottom end of the square block extends into the square groove; the square groove is designed to facilitate the square block to extend into the cylindrical groove.

Preferably, the first vacuum plate and the second vacuum plate are both fixedly provided with elliptical rods, the annular side surface of each elliptical rod is provided with a nano-microporous plate, one end of each nano-microporous plate is provided with an elliptical hole, and the elliptical rods are arranged in the elliptical holes; the design of the elliptical rod and the elliptical hole is convenient for installing the nano microporous plate on the elliptical rod.

Preferably, one end of the elliptic rod is rotatably provided with an elliptic block, the size of the cross section of the elliptic rod is the same as that of the cross section of the elliptic block, one end of the elliptic block, which is close to the elliptic rod, is attached to the nano microporous plate, the middle position of one end of the elliptic block, which is close to the elliptic rod, is fixedly provided with a rotating pin, and the rotating pin is rotatably arranged inside the elliptic rod; the design of the elliptical block is convenient for clamping the nano microporous plate on the elliptical rod, and further the installation of the nano elliptical rod is realized.

Preferably, a torsion spring is mounted on the annular side face of the rotating pin, the outer side of the torsion spring is fixedly mounted inside the elliptical hole, a first magnetic block is fixedly mounted on the annular side face of the rotating pin, a second magnetic block is fixedly mounted inside the elliptical rod, and the first magnetic block and the second magnetic block are located in the same vertical plane; the rotating pin is driven to rotate by rotating the elliptical block, the rotating pin rotates to extrude the torsion spring, the rotating pin rotates to drive the first magnetic block to move and adhere to the second magnetic block in an adsorption mode, the adsorption force between the first magnetic block and the second magnetic block is larger than the torsion force of the torsion spring, the position of the elliptical block is further fixed, the elliptical rod is completely adhered to the elliptical block, and the nano microporous plate is convenient to install on the elliptical rod.

Preferably, the annular side surface of the rotating pin is fixedly provided with a miniature bearing, and the outer side of the miniature bearing is fixedly arranged in the elliptic rod; the design of the miniature bearing is convenient for the rotating pin to be rotatably arranged inside the elliptic rod.

The invention has the advantages that:

1. according to the invention, the second vacuum plate is arranged in the U-shaped area, the rectangular rod is arranged in the rectangular groove, the circular through hole in the rectangular rod is aligned with the cylindrical groove in the rectangular groove, the T-shaped round rod is inserted into the first vacuum plate, the bottom end of the T-shaped round rod penetrates through the circular through hole and enters the cylindrical groove, the bottom end of the T-shaped round rod enters the cylindrical groove, the sliding block moves along the vertical groove of the L-shaped groove, when the sliding block moves to the end of the vertical groove, a user rotates the T-shaped round rod, the sliding block moves into the transverse groove of the L-shaped groove, and then one end of the T-shaped round rod is clamped in the cylindrical groove, so that the problem that the first vacuum plate and the second vacuum plate are inconvenient to connect is solved;

2. according to the invention, the nano micropore plate is arranged on the elliptical rod, the elliptical block is reversely twisted, and the elliptical block rotates to drive the rotating pin to rotate, so that the first magnetic block is separated from the second magnetic block, and the elliptical block rotates and resets under the action of torsional spring torsion, thereby completing the installation of the nano micropore plate, and solving the problems that the nano micropore plate is inconvenient to assemble, disassemble and maintain due to the lack of a convenient installation mechanism of the nano micropore plate, and the service life of the nano micropore plate is shortened.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive exercise.

FIG. 1 is a schematic overall structure diagram according to a first embodiment;

FIG. 2 is a schematic view of an assembly structure of a first vacuum plate and a second vacuum plate according to the first embodiment;

FIG. 3 is an enlarged view of a portion A of the first embodiment;

FIG. 4 is a schematic view of an assembly structure of the elliptical rod and the elliptical block according to the first embodiment;

fig. 5 is a schematic view of an assembly structure of the elliptical block and the nano-micro plate according to the second embodiment.

In the figure: 1. a nano-microporous plate; 2. a first vacuum plate; 3. a second true hole plate; 4. a rectangular bar; 5. a T-shaped round bar; 6. an L-shaped groove; 7. a slider; 8. a flat head bolt; 9. a first spring; 10. a square block; 11. an elliptical rod; 12. an elliptical block; 13. a rotation pin; 14. a torsion spring; 15. a first magnetic block; 16. a second magnetic block; 17. a U-shaped rod; 18. a clamping block; 19. a second spring; 20. and adjusting the bolt.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example one

Referring to fig. 1-4, a nano-microporous vacuum insulation apparatus for a high temperature resistant kiln comprises a nano-microporous plate 1, a vacuum plate one 2, a vacuum plate two 3 and a connecting mechanism; the three vacuum plates I2 are arranged, the three vacuum plates I2 enclose a U-shaped area, two vacuum plates II 3 are symmetrically arranged in the U-shaped area, and the nano-microporous plates 1 are arranged at one ends of the vacuum plates I2 far away from the vacuum plates II 3 and at the outer sides of the vacuum plates II 3;

the connecting mechanism comprises a rectangular rod 4 and a T-shaped round rod 5, a rectangular groove is formed in one end, close to the second vacuum plate 3, of the first vacuum plate 2, the rectangular rod 4 is fixedly installed at the left end, the right end and the rear end of the second vacuum plate 3, the rectangular rod 4 is installed inside the rectangular groove, the T-shaped round rod 5 is installed at the top end of the first vacuum plate 2, a cylindrical groove is formed in the bottom end of the rectangular groove, and the bottom end of the T-shaped round rod 5 penetrates through the rectangular rod 4 and extends into the cylindrical groove; during operation, the user installs two 3 vacuum panels inside U type region for rectangle pole 4 is installed inside the rectangular channel, makes the circular through-hole on the rectangle pole 4 align with the inside cylinder groove of rectangular channel, inserts one 2 inside vacuum panels with T type pole 5, makes 5 bottoms of T type pole pass circular through-hole and get into inside the cylinder groove.

Two sliding blocks 7 are symmetrically arranged on the annular side surface of the T-shaped round rod 5, two L-shaped grooves 6 are symmetrically formed in the cylindrical grooves, and the sliding blocks 7 are arranged in the L-shaped grooves 6; during operation, 5 bottoms of T type round bar get into the cylinder inslot for slider 7 removes along the perpendicular groove in L type groove 6, and when slider 7 removed to perpendicular groove end, user of service rotated T type round bar 5, made slider 7 remove the horizontal inslot portion that gets into L type groove 6, and then with 5 one end joints of T type round bar in the cylinder inslot portion.

A circular through hole is formed in the top end of the rectangular rod 4, two strip-shaped holes are symmetrically formed in the circular through hole, the size of the cross section of each strip-shaped hole is the same as that of the cross section of the sliding block 7, and a T-shaped round rod 5 is installed in the circular through hole; during operation, the T-shaped round rod 5 can conveniently penetrate through the rectangular rod 4 due to the design of the round through hole, and the sliding block 7 can conveniently penetrate through the round through hole due to the design of the strip-shaped rod.

The L-shaped groove 6 consists of a vertical groove and a transverse groove, two vertical grooves and two transverse grooves are symmetrically formed in the cylindrical groove, the bottom end of each vertical groove is communicated with one end of each transverse groove, and a sliding block 7 is arranged in each transverse groove; during operation, the design in L type groove 6 is convenient for with 7 joints of slider inside the cylinder inslot, and then with 5 bottom joints of T type round bar inside the cylinder inslot.

A flat head bolt 8 is mounted at the top end of the T-shaped round rod 5, a first nut is mounted on the annular side face of the flat head bolt 8, the outer side of the first nut is fixedly mounted inside the T-shaped round rod 5, a containing groove is formed in the lower end of the T-shaped round rod 5, a first spring 9 is fixedly mounted at the top end inside the containing groove, a square block 10 is fixedly mounted at the bottom end of the first spring 9, the bottom end of the square block 10 extends into the cylindrical groove, and the bottom end of the flat head bolt 8 penetrates through the T-shaped round rod 5 and is attached to the top end of the square block 10; the during operation, when slider 7 removed to the cross slot end, 10 bottoms of square align with the square trough, twist flat head bolt 8 after that, flat head bolt 8 removes along nut one, flat head bolt 8 removes and drives square 10 and remove, square 10 removes and gets into the square trough inside, square 10 top is located and accomodates the inslot portion this moment, avoid T type round bar 5 to take place to rotate, avoid slider 7 to break away from L type inslot 6 inside, square 10 removes and stretches spring 9, the elasticity of spring 9 is convenient for the removal of square 10 to reset, the elasticity of spring 9 avoids flat head bolt 8 to appear not hard up simultaneously.

A square groove is formed in the bottom end of the inner portion of the cylindrical groove, the size of the cross section of the square groove is the same as that of the cross section of the square block 10, and the bottom end of the square block 10 extends into the square groove; in operation, the square groove is designed to facilitate the block 10 to extend into the cylindrical groove.

The first vacuum plate 2 and the second vacuum plate 3 are both fixedly provided with elliptical rods 11, the annular side surface of each elliptical rod 11 is provided with a nano-microporous plate 1, one end of each nano-microporous plate 1 is provided with an elliptical hole, and each elliptical hole is internally provided with the elliptical rod 11; during operation, the design of the elliptical rod 11 and the elliptical hole facilitates the installation of the nano-microporous plate 1 on the elliptical rod 11.

An elliptical block 12 is rotatably mounted at one end of the elliptical rod 11, the size of the cross section of the elliptical rod 11 is the same as that of the cross section of the elliptical block 12, one end, close to the elliptical rod 11, of the elliptical block 12 is attached to the nano-microporous plate 1, a rotating pin 13 is fixedly mounted at the middle position of one end, close to the elliptical rod 11, of the elliptical block 12, and the rotating pin 13 is rotatably mounted inside the elliptical rod 11; during operation, the design of the elliptical block 12 is convenient for the nano microporous plate 1 to be clamped on the elliptical rod 11, and then the nano elliptical rod 11 is installed.

The annular side surface of the rotating pin 13 is provided with a torsion spring 14, the outer side of the torsion spring 14 is fixedly arranged in the elliptical hole, the annular side surface of the rotating pin 13 is fixedly provided with a first magnetic block 15, the inner part of the elliptical rod 11 is fixedly provided with a second magnetic block 16, and the first magnetic block 15 and the second magnetic block 16 are positioned in the same vertical plane; during operation, the rotating pin 13 is driven to rotate through the rotating elliptical block 12, the rotating pin 13 rotates to extrude the torsion spring 14, the rotating pin 13 rotates to drive the first magnetic block 15 to move and adhere to the second magnetic block 16 in an adsorption mode, the adsorption force between the first magnetic block 15 and the second magnetic block 16 is larger than the torsion of the torsion spring 14, the position of the elliptical block 12 is further fixed, the elliptical rod 11 is completely adhered to the elliptical block 12, and the nano microporous plate 1 is conveniently installed on the elliptical rod 11.

A miniature bearing is fixedly arranged on the annular side surface of the rotating pin 13, and the outer side of the miniature bearing is fixedly arranged inside the elliptical rod 11; in operation, the micro-bearing is designed to facilitate the rotation of the rotation pin 13 inside the elliptical rod 11.

Example two

Referring to fig. 5, as another embodiment of the present invention, in a first comparative example, a U-shaped rod 17 is slidably installed at one end of an elliptical block 12, one end of the U-shaped rod 17 penetrates through the elliptical block 12 and is fixedly installed with two clamping blocks 18, two clamping grooves are symmetrically formed at one end of a nano-microporous plate 1, one end of each clamping block 18 extends into each clamping groove, an adjusting bolt 20 is installed on an annular side surface of the U-shaped rod 17, one end of each adjusting bolt 20 penetrates through the U-shaped rod 17 and is rotatably installed on the elliptical block 12, a nut is installed on an annular side surface of each adjusting bolt 20, and the outer side of each nut is fixedly installed inside the U-shaped rod 17; during operation, install nanometer micropore board 1 on elliptical rod 11, reverse twisting oval piece 12, oval piece 12 rotates and drives the rotation pin 13 and rotate, make magnetic path one 15 and magnetic path two 16 separate, under the effect of 14 torsional forces of torsional spring, oval piece 12 rotates and resets, make fixture block 18 and draw-in groove align, twist adjusting bolt 20 after that, make nut two remove along adjusting bolt 20, and then drive U type pole 17 and remove, U type pole 17 removes and drives fixture block 18 and remove inside getting into the draw-in groove, and then the position of fixed oval piece 12, the stability of installing of nanometer micropore board 1 has been improved.

The theory of operation, install two 3 vacuum plates in U type regional inside, make rectangle pole 4 install inside the rectangular channel, make circular through-hole on the rectangle pole 4 align with the cylinder groove of rectangular channel inside, insert one 2 insides vacuum plate with T type pole 5, make 5 bottoms of T type pole pass circular through-hole and get into inside the cylinder groove, 5 bottoms of T type pole get into inside the cylinder groove, make slider 7 remove along the perpendicular groove of L type groove 6, when slider 7 removes to perpendicular groove end, the user rotates T type pole 5, make slider 7 remove the inside cross slot that gets into L type groove 6, and then 5 one end joints of T type pole are inside the cylinder groove.

The rotating pin 13 is driven to rotate by rotating the elliptical block 12, the rotating pin 13 rotates to extrude the torsion spring 14, the rotating pin 13 rotates to drive the first magnetic block 15 to move to be attached to the second magnetic block 16 in an adsorption mode, the adsorption force between the first magnetic block 15 and the second magnetic block 16 is larger than the torsion force of the torsion spring 14, the position of the elliptical block 12 is further fixed, the elliptical rod 11 is completely attached to the elliptical block 12, the nano microporous plate 1 is conveniently installed on the elliptical rod 11, the elliptical block 12 is reversely twisted, the rotating pin 13 is driven to rotate by rotating the elliptical block 12, the first magnetic block 15 is separated from the second magnetic block 16, the elliptical block 12 is rotated and reset under the action of the torsion force of the torsion spring 14, and installation of the nano microporous plate 1 is completed.

In the description herein, references to the description of "one embodiment," "an example," "a specific example" or the like are intended to mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the invention as claimed.

Claims (10)

1. A nanometer micropore vacuum heat insulation device for a high temperature resistant kiln is characterized in that: comprises a nano microporous plate (1), a first vacuum plate (2), a second vacuum plate (3) and a connecting mechanism; the three vacuum plates I (2) are arranged, a U-shaped area is defined by the three vacuum plates I (2), two vacuum plates II (3) are symmetrically arranged in the U-shaped area, and the nano-microporous plate (1) is arranged at one end, far away from the vacuum plates II (3), of the vacuum plate I (2) and at the outer side of the vacuum plate II (3);

coupling mechanism includes rectangle pole (4) and T type pole (5), vacuum plate (2) are close to vacuum plate two (3) one end and have been seted up the rectangular channel, the equal fixed mounting in both ends and rear end has rectangle pole (4) about vacuum plate two (3), install at the rectangular channel inside rectangle pole (4), T type pole (5) are installed on vacuum plate one (2) top, the cylinder groove has been seted up to the rectangular channel bottom, T type pole (5) bottom is passed rectangle pole (4) and is extended to the cylinder inslot portion.

2. The nano micropore vacuum heat insulation device for the high temperature resistant kiln as recited in claim 1, wherein: two sliding blocks (7) are symmetrically installed on the annular side face of the T-shaped round rod (5), two L-shaped grooves (6) are symmetrically formed in the cylindrical grooves, and the sliding blocks (7) are installed in the L-shaped grooves (6).

3. The nano micropore vacuum heat insulation device for the high temperature resistant kiln as recited in claim 1, wherein: the round through hole is formed in the top end of the rectangular rod (4), two strip-shaped holes are symmetrically formed in the round through hole, the cross section of each strip-shaped hole is the same as that of the corresponding sliding block (7), and a T-shaped round rod (5) is installed inside the round through hole.

4. The nano micropore vacuum heat insulation device for the high temperature resistant kiln as recited in claim 2, characterized in that: the L-shaped groove (6) is composed of vertical grooves and transverse grooves, the two vertical grooves and the two transverse grooves are symmetrically formed in the cylindrical groove, the bottom ends of the vertical grooves are communicated with one ends of the transverse grooves, and sliding blocks (7) are arranged in the transverse grooves.

5. The nano micropore vacuum heat insulation device for the high temperature resistant kiln as recited in claim 1, wherein: flat head bolt (8) are installed on T type round bar (5) top, install nut one on flat head bolt (8) the annular side, and a nut outside fixed mounting is inside T type round bar (5), T type round bar (5) low side has been seted up and has been accomodate the groove, and has been accomodate inslot portion top fixed mounting spring one (9), spring one (9) bottom fixed mounting has square (10), square (10) bottom extends to the cylinder inslot portion, flat head bolt (8) bottom is passed T type round bar (5) and is laminated mutually with square (10) top.

6. The nano micropore vacuum heat insulation device for the high temperature resistant kiln as recited in claim 5, wherein: the bottom end in the cylindrical groove is provided with a square groove, the size of the cross section of the square groove is the same as that of the cross section of the square block (10), and the bottom end of the square block (10) extends into the square groove.

7. The nano micropore vacuum heat insulation device for the high temperature resistant kiln as recited in claim 1, wherein: equal fixed mounting has elliptical rod (11) on vacuum plate (2) and vacuum plate two (3), install nanometer micropore board (1) on elliptical rod (11) annular side, the elliptical hole has been seted up to nanometer micropore board (1) one end, elliptical hole internally mounted has elliptical rod (11).

8. The nano-microporous vacuum heat insulation device for the high-temperature resistant kiln as claimed in claim 7, characterized in that: elliptical rod (11) one end is rotated and is installed elliptical block (12), the size of elliptical rod (11) cross section is the same with the size of elliptical block (12) cross section, elliptical block (12) are close to elliptical rod (11) one end and are laminated with nanometer micropore board (1) mutually, elliptical block (12) are close to elliptical rod (11) one end intermediate position fixed mounting has rotating pin (13), and rotating pin (13) rotate and install inside elliptical rod (11).

9. The nano-microporous vacuum heat insulation device for the high-temperature resistant kiln as claimed in claim 8, characterized in that: install on rotating pin (13) annular side torsional spring (14), and torsional spring (14) outside fixed mounting inside the elliptical aperture, fixed mounting has magnetic block one (15) on rotating pin (13) annular side, the inside fixed mounting of elliptical rod (11) has magnetic block two (16), and magnetic block one (15) and magnetic block two (16) are inside same vertical face.

10. The nano-microporous vacuum heat insulation device for the high-temperature resistant kiln as claimed in claim 9, characterized in that: the annular side surface of the rotating pin (13) is fixedly provided with a miniature bearing, and the outer side of the miniature bearing is fixedly arranged in the elliptic rod (11).

Images