CN213767517U - Intelligent precise mold heat insulation base plate used in high-temperature environment - Google Patents
Intelligent precise mold heat insulation base plate used in high-temperature environment Download PDFInfo
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- CN213767517U CN213767517U CN202022845846.9U CN202022845846U CN213767517U CN 213767517 U CN213767517 U CN 213767517U CN 202022845846 U CN202022845846 U CN 202022845846U CN 213767517 U CN213767517 U CN 213767517U
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Abstract
The utility model discloses an intelligent accurate mould thermal-insulated backing plate that uses in high temperature environment, including from top to bottom compound heat-resisting steel layer of modification, first mica composite bed, silica layer, second mica composite bed and the high manganese steel layer of modification in proper order, the top surface on heat-resisting steel layer of modification and the bottom surface on high manganese steel layer of modification have thermal-insulated glue dope layer all coated. The modified heat-resistant steel layer and the modified high-manganese steel layer play a reinforcing role, the first mica composite layer and the second mica composite layer play an insulating role, and the silicon dioxide layer plays a role in stopping temperature from being conducted slowly from high temperature to low temperature, so that a heat insulation effect is achieved, and high strength is provided. The service life of the heat insulation backing plate is obviously prolonged, and is increased from 20 times of traditional use to 400 times of traditional use.
Description
Technical Field
The utility model relates to a thermal-insulated backing plate, specific intelligent precision mold thermal-insulated backing plate who uses in high temperature environment that says so.
Background
Thermal insulation materials are of great importance in numerous industrial fields of aerospace, energy, chemical and metallurgy, and conventional thermal insulation materials such as foam materials, fiber materials and the like have excellent thermal insulation properties, but lack high temperature strength. At present, the thermal insulation materials used at high temperature are silicon dioxide composite materials and mica sheet composite materials, but the silicon dioxide composite materials are easy to crack into fragments along with the increase of the use times at the high temperature state, and the mica sheet composite materials can become scaly along with the volatilization of glue at the high temperature state. In a word, the currently used silica insulation materials and mica sheet insulation materials generally have the problem of low service life, and the service life of the silica insulation materials and the mica sheet insulation materials is about twenty times of repeated use. In order to prolong the service life of the heat insulating material and reduce the loss of the heat insulating material in a high-temperature environment in various industrial fields, the applicant has made intensive research and developed the scheme.
SUMMERY OF THE UTILITY MODEL
The utility model provides a thermal-insulated backing plate of accurate mould of intelligence that uses in high temperature environment, its main aim at overcome the current lower problem of life at the thermal insulation material of high temperature use.
In order to solve the technical problem, the utility model adopts the following technical scheme:
the utility model provides an intelligent accurate mould thermal-insulated backing plate that uses in high temperature environment, includes modified heat-resisting steel layer, first mica composite bed, silica layer, second mica composite bed and the high manganese steel layer of modification that from top to bottom compounds in proper order, the top surface on modified heat-resisting steel layer and the bottom surface on modified high manganese steel layer have all coated thermal-insulated glue dope layer.
Further, the first mica composite layer, the silicon dioxide layer and the second mica composite layer are bonded through a heat insulation glue coating to form a high-temperature insulation layer, and the modified heat-resistant steel layer, the high-temperature insulation layer and the modified high-manganese steel layer are fixedly connected through a plurality of ceramic screws.
Furthermore, the modified heat-resistant steel layer, the high-temperature insulating layer and the modified high-manganese steel layer are provided with four screw holes which are distributed in four corners, and the ceramic screws sequentially penetrate through the screw holes of the modified heat-resistant steel layer, the high-temperature insulating layer and the modified high-manganese steel layer to connect the modified heat-resistant steel layer, the high-temperature insulating layer and the modified high-manganese steel layer.
And furthermore, the screw hole of the modified heat-resistant steel layer is a countersunk head screw hole.
Further, the first mica composite layer comprises a first phlogopite sheet and a first stainless steel fiber layer compounded on the bottom surface of the first phlogopite sheet, and the second mica composite layer comprises a second phlogopite sheet and a second stainless steel fiber layer compounded on the top surface of the second phlogopite sheet.
Further, the first stainless steel fiber layer and the second stainless steel fiber layer are both 310S stainless steel fiber layers.
From the above description of the present invention, compared with the prior art, the present invention has the following advantages: the modified heat-resistant steel layer and the modified high-manganese steel layer play a reinforcing role, the first mica composite layer and the second mica composite layer play an insulating role, and the silicon dioxide layer plays a role in stopping temperature from being conducted slowly from high temperature to low temperature, so that a heat insulation effect is achieved, and high strength is provided. The service life of the heat insulation backing plate is obviously prolonged, and is increased from 20 times of traditional use to 400 times of traditional use.
Drawings
Fig. 1 is a schematic view of the utility model.
Fig. 2 is a schematic view of the present invention after the ceramic screw is removed.
Fig. 3 is a schematic view of the first mica composite layer according to the present invention.
Fig. 4 is a schematic view of a second mica composite layer according to the present invention.
Detailed Description
Refer to fig. 1. The utility model provides an intelligent accurate mould thermal-insulated backing plate that uses in high temperature environment, includes modified heat-resisting steel layer 1, first mica composite bed 2, silica layer 3, second mica composite bed 4 and modified high manganese steel layer 5 that from top to bottom compounds in proper order, the top surface of modified heat-resisting steel layer 1 and the bottom surface of modified high manganese steel layer 5 have all coated thermal-insulated glue dope layer, and this thermal-insulated glue dope layer can improve the top surface of modified heat-resisting steel layer 1 and the high temperature resistant temperature of modified high manganese steel layer 5.
Refer to fig. 1 and 2. The first mica composite layer 2, the silicon dioxide layer 3 and the second mica composite layer 4 are bonded through heat-insulating glue paint to form a high-temperature insulating layer 6, and the modified heat-resistant steel layer 1, the high-temperature insulating layer 6 and the modified high-manganese steel layer 5 are fixedly connected through a plurality of ceramic screws 7. Further, the modified heat-resistant steel layer 1, the high-temperature insulating layer 6 and the modified high-manganese steel layer 5 are all provided with four screw holes 8, and the four screw holes 8 are distributed in four corners. The ceramic screw 7 passes through the screw holes 8 of the modified heat-resistant steel layer 1, the high-temperature insulating layer 6 and the modified high-manganese steel layer 5 in sequence to connect the modified heat-resistant steel layer 1, the high-temperature insulating layer 6 and the modified high-manganese steel layer 5, the ceramic screw 7 plays roles in connection and insulation, and the screw holes 8 of the modified heat-resistant steel layer 1 are countersunk head screw holes.
Refer to fig. 3 and 4. The first mica composite layer 2 comprises a first phlogopite sheet 21 and a first stainless steel fiber layer 22 compounded on the bottom surface of the first phlogopite sheet 21, and the second mica composite layer 4 comprises a second phlogopite sheet 41 and a second stainless steel fiber layer 42 compounded on the top surface of the second phlogopite sheet 41. First stainless steel fibrous layer 22 and second stainless steel fibrous layer 42 are the 310S stainless steel fibrous layer, first phlogopite piece 21 and 310S stainless steel fiber, second phlogopite piece 41 and 310S stainless steel fiber are all compound through thermal-insulated glue, put into thermal-insulated glue earlier 310S stainless steel fiber and carry out the misce bene, then will mix the thermal-insulated glue that has 310S stainless steel fiber and coat respectively in the bottom surface of first phlogopite piece 21 and the top surface of second phlogopite piece 41. The stainless steel fiber is wear-resistant and high-temperature resistant (in an oxidation environment, the temperature can reach 600 ℃ for continuous use), and can provide the service life of the phlogopite sheet in a high-temperature environment.
Refer to fig. 1. The design principle of the utility model is as follows: the performance of the modified heat-resistant steel layer and the modified high-manganese steel layer can still meet the use requirement at high temperature, the high-temperature insulating layer 6 can be protected and reinforced, the first mica composite layer 2 and the second mica composite layer 4 can be used for insulation, and the silicon dioxide layer 3 can be used for preventing the temperature from being conducted from high temperature to low temperature and slowing down, so that the heat insulation effect and the strength are achieved. Compared with the existing heat insulation backing plate, the service life of the heat insulation backing plate is obviously prolonged, and the service life is increased from 20 times of traditional use to 400 times of traditional use.
The above-mentioned be the utility model discloses a concrete implementation way, nevertheless the utility model discloses a design concept is not limited to this, and the ordinary use of this design is right the utility model discloses carry out immaterial change, all should belong to the act of infringement the protection scope of the utility model.
Claims (6)
1. The utility model provides a thermal-insulated backing plate of accurate mould of intelligence that uses in high temperature environment which characterized in that: the heat-insulation mica composite board comprises a modified heat-resistant steel layer, a first mica composite layer, a silicon dioxide layer, a second mica composite layer and a modified high-manganese steel layer which are sequentially compounded from top to bottom, wherein the top surface of the modified heat-resistant steel layer and the bottom surface of the modified high-manganese steel layer are coated with heat-insulation glue coating layers.
2. An intelligent precision mold thermal insulating blanket used in high temperature environments as claimed in claim 1, wherein: the first mica composite layer, the silicon dioxide layer and the second mica composite layer are bonded through heat-insulating glue paint to form a high-temperature insulating layer, and the modified heat-resistant steel layer, the high-temperature insulating layer and the modified high-manganese steel layer are fixedly connected through a plurality of ceramic screws.
3. An intelligent precision mold thermal insulating blanket used in high temperature environments as claimed in claim 2, wherein: the modified heat-resistant steel layer, the high-temperature insulating layer and the modified high-manganese steel layer are all provided with four screw holes which are distributed in four corners, and the ceramic screws sequentially penetrate through the screw holes of the modified heat-resistant steel layer, the high-temperature insulating layer and the modified high-manganese steel layer to connect the modified heat-resistant steel layer, the high-temperature insulating layer and the modified high-manganese steel layer.
4. An intelligent precision mold thermal insulating blanket used in high temperature environments as claimed in claim 3, wherein: the screw hole of the modified heat-resistant steel layer is a countersunk head screw hole.
5. An intelligent precision mold thermal insulating blanket used in high temperature environments as claimed in claim 1, wherein: the first mica composite layer comprises a first phlogopite sheet and a first stainless steel fiber layer compounded on the bottom surface of the first phlogopite sheet, and the second mica composite layer comprises a second phlogopite sheet and a second stainless steel fiber layer compounded on the top surface of the second phlogopite sheet.
6. An intelligent precision mold thermal insulating blanket used in high temperature environments as claimed in claim 5, wherein: the first stainless steel fiber layer and the second stainless steel fiber layer are both 310S stainless steel fiber layers.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202022845846.9U CN213767517U (en) | 2020-12-01 | 2020-12-01 | Intelligent precise mold heat insulation base plate used in high-temperature environment |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202022845846.9U CN213767517U (en) | 2020-12-01 | 2020-12-01 | Intelligent precise mold heat insulation base plate used in high-temperature environment |
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| CN213767517U true CN213767517U (en) | 2021-07-23 |
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| CN202022845846.9U Active CN213767517U (en) | 2020-12-01 | 2020-12-01 | Intelligent precise mold heat insulation base plate used in high-temperature environment |
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Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN114361740A (en) * | 2022-03-19 | 2022-04-15 | 浙江荣泰电工器材股份有限公司 | Low-thermal-conductivity mica composite part applied to thermal runaway protection among battery cells and preparation method thereof |
-
2020
- 2020-12-01 CN CN202022845846.9U patent/CN213767517U/en active Active
Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN114361740A (en) * | 2022-03-19 | 2022-04-15 | 浙江荣泰电工器材股份有限公司 | Low-thermal-conductivity mica composite part applied to thermal runaway protection among battery cells and preparation method thereof |
| CN114361740B (en) * | 2022-03-19 | 2022-06-17 | 浙江荣泰电工器材股份有限公司 | Be applied to thermal runaway protection low heat conduction mica composite between electric core |
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Address after: 362200 d304-5, building D, Chuangke street, Sanchuang Park, No. 3001, south section of Century Avenue, Sunei community, Luoshan street, Jinjiang City, Quanzhou City, Fujian Province Patentee after: Quanzhou Jiugao Intelligent Technology Co.,Ltd. Address before: No. 3001, south section of Century Avenue, Luoshan street, Jinjiang City, Quanzhou City, Fujian Province Patentee before: JINJIANG JIUGAO INTELLIGENT TECHNOLOGY CO.,LTD. |
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