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CN-117429100-B - Heat insulation method for high-resistant Wen Jiqi people

CN117429100BCN 117429100 BCN117429100 BCN 117429100BCN-117429100-B

Abstract

The invention discloses a high-resistant Wen Jiqi person heat insulation method, which belongs to the technical field of robot production, and aims to solve the problems that the existing high-resistant Wen Jiqi person heat insulation scheme realizes the heat insulation purpose through continuous stacking of the layers of heat insulation cotton and cross stacking of various heat insulation cotton, and has the defects of high operation difficulty, uneven laying, difficult treatment at butt joint dead angles, difficult modeling and reduction of the heat insulation effect of a robot. The high-temperature-resistant fiber cotton wool is filled into a reserved heat insulation cavity in the robot rapidly and effectively, the high-temperature-resistant fiber cotton wool materials are uniformly distributed, the same heat insulation effect can be achieved at each position, fibers or particles are more compact, the heat conduction path is reduced, the heat insulation performance is improved, and electronic elements and mechanical parts in the high-temperature-resistant robot can be protected from being influenced by high-temperature environments when the high-temperature-resistant robot works, so that the high-temperature-resistant robot replaces manual work to implement tasks in environments which are high-temperature, dangerous or incapable of being entered manually.

Inventors

  • CHANG JIAN
  • YANG BIN
  • Zhang Guishuo
  • WANG YAHUI
  • CHANG SHANQIANG
  • Yao Genshuang
  • YANG XIAOYAN

Assignees

  • 北京凌天智能装备集团股份有限公司

Dates

Publication Date
20260508
Application Date
20231212

Claims (3)

  1. 1. The high-temperature-resistant Wen Jiqi-person heat insulation method is characterized by comprising an inner shell (1), wherein a fixed outer shell (2) is arranged on the outer side of the inner shell (1), a heat insulation cavity (3) is formed between the inner shell (1) and the outer shell (2), two groups of channels are formed in the heat insulation cavity (3) and are respectively a filling layer (4) and a compression layer (5), one side of the inner shell (1) is respectively provided with an air outlet (6) and an air inlet (7), a high-temperature-resistant fiber cotton wool (8) is arranged in the filling layer (4), and sealing positions at two ends of the heat insulation cavity (3) are sealed by using high-temperature-resistant ceramic fiber cloth (9); The method comprises the following steps: S1, injecting air into a high-temperature-resistant fiber cotton wool (8), uniformly distributing the air in gaps or pores of the high-temperature-resistant fiber cotton wool (8), and driving the high-temperature-resistant fiber cotton wool (8) filled with the air into a filling layer (4); s2, vibrating and filling the high-temperature-resistant fiber cotton wool (8) of the filling layer (4), closely arranging fibers or particles in the high-temperature-resistant fiber cotton wool (8) of the filling layer (4), reducing pores or gaps, uniformly distributing the high-temperature-resistant fiber cotton wool (8) on the filling layer (4), and uniformly heating the high-temperature-resistant fiber cotton wool (8) at each position; S3, inflating the compression layer (5), inflating an air inlet (7) of the compression layer (5) at one side of the inner shell to expand the compression layer (5) in the heat insulation cavity (3), compressing the filling layer (4) filled with the high-temperature-resistant fiber cotton wool (8), reducing the volume and the thickness of the filling layer, increasing the density, generating pressure on the filling layer (4) in the limited heat insulation cavity (3), compressing and deforming the filling layer (4), creating an air layer compression layer (5), and realizing heat insulation by utilizing the low heat conductivity of gas; s4, exhausting air to a vacuum state at an air outlet (6) of the filling layer (4), placing the high-temperature-resistant fiber cotton wool (8) in a vacuum environment, reducing the existence of gas molecules, and reducing heat transfer by utilizing the vacuum environment; S5, using high-temperature-resistant ceramic fiber cloth (9) as a plug at the port to isolate the inner part of the heat-insulating cavity (3) from the outside; s6, installing a fixed outer shell (2) on the outer side of the inner shell (1) of the robot, using a heat shielding coating (10) and a metal heat insulation layer (11) to insulate heat for the outer shell (2), coating the heat shielding coating (10) on the surface of the outer shell of the robot, using the metal heat insulation layer (11) to wrap the outer shell of the robot, insulating the influence of the temperature of the thermal external environment and reducing the temperature conduction of the outer shell.
  2. 2. The heat insulation method for Wen Jiqi persons with high resistance according to claim 1 is characterized in that high temperature resistant ceramic fiber cloth (9) is used for sealing the sealing positions at the two ends of the heat insulation cavity (3), and meanwhile soft contact of the upper and lower bonding surfaces is ensured.
  3. 3. The method of heat insulation for human body with high heat resistance Wen Jiqi as set forth in claim 1, wherein the heat shielding layer (10) is made of ceramic to reduce heat conduction and absorption, and the metal heat insulating layer (11) is made of stainless steel, aluminum alloy or titanium alloy.

Description

Heat insulation method for high-resistant Wen Jiqi people Technical Field The invention relates to the technical field of robot production, in particular to a high-resistance Wen Jiqi-person heat insulation method. Background The robot is mechanical equipment capable of autonomously executing tasks, can execute various tasks, has the capability of tolerating high-temperature environments, can work under extreme temperature conditions, can expand the capability range of human beings, can implement tasks in environments with high temperature, danger or incapability of manually entering, can improve the working efficiency, reduce accident risks, protect personnel life and property safety, and promote the front edge of scientific research and technical innovation. The current anti-high Wen Jiqi people heat insulation scheme is to realize the heat insulation purpose through the continuous stacking of the layer number of the heat insulation cotton and the cross stacking of various heat insulation cotton, and has the advantages of high operation difficulty, uneven laying, difficult treatment at the butt joint dead angle, difficult modeling, reduction of the heat insulation effect of the robot, and easy influence of high temperature environment on internal electronic elements and mechanical parts, and influence on the working efficiency of the robot. Disclosure of Invention Therefore, the invention provides a heat insulation method for Wen Jiqi persons with high resistance to solve the problems in the prior art. In order to achieve the above object, the present invention provides the following technical solutions: According to a first aspect of the invention, a method for insulating high-Wen Jiqi people, comprising the steps of: s1, injecting air into a high-temperature-resistant fiber cotton wool, and adding the high-temperature-resistant fiber cotton wool into a filling layer; S2, vibrating and filling the high-temperature-resistant fiber cotton wool of the filling layer, uniformly distributing the high-temperature-resistant fiber cotton wool on the filling layer, and uniformly insulating the high-temperature-resistant fiber cotton wool at each position; S3, inflating the compression layer, generating pressure on the filling layer in the limited heat insulation cavity, compressing and deforming the filling layer to create an air layer compression layer, and realizing heat insulation by utilizing the low heat conductivity of gas; s4, exhausting air to a vacuum state at an air outlet of the filling layer, and reducing heat transfer by utilizing a vacuum environment; s5, using high-temperature-resistant ceramic fiber cloth as a plug at the port to isolate the inner part of the heat-insulating cavity; S6, installing a fixed outer shell on the outer side of the inner shell of the robot, using the heat shielding coating and the metal heat insulation layer as the outer shell to insulate heat, coating the heat shielding coating on the surface of the outer shell of the robot, wrapping the outer shell of the robot by using the metal heat insulation layer, isolating the influence of the temperature of the hot external environment and reducing the temperature conduction of the outer shell. Further, a fixed outer shell is arranged on the outer side of the inner shell of the robot, a heat insulation cavity is formed between the inner shell and the outer shell, a filling space of high-temperature resistant fiber cotton wool is reserved for the robot, and two groups of channels are formed in the heat insulation cavity and are respectively a filling layer and a compression layer. Further, air is injected into the high-temperature-resistant fiber cotton wool, the air is uniformly distributed in gaps or pores of the high-temperature-resistant fiber cotton wool, the high-temperature-resistant fiber cotton wool injected with the air is driven into the filling layer, and the filling layer is sealed at two ends of the heat insulation cavity. Further, the outer side of the whole shell is fixedly protected, vibration with different frequencies is carried out, and fibers or particles in the high-temperature-resistant fiber batting of the filling layer are tightly arranged in a vibration filling mode, so that pores or gaps are reduced. Further, the air inlet of the compression layer is inflated at one side of the inner shell, the compression layer expands in the heat insulation cavity, the filling layer filled with the high-temperature-resistant fiber cotton wool is compressed, the volume and the thickness of the filling layer are reduced, and the density is increased. Further, the high-temperature resistant fiber cotton wool is placed in a vacuum environment by exhausting air from the air outlet of the filling layer at one side of the inner shell, so that the existence of gas molecules is reduced, and the vacuum filling of the filling layer is realized. Further, the high-temperature resistant fiber cotton wool is filled into a reserved he