TH66737B - A method of extending the service life expectancy of high temperature piping systems. And structure to expand the life expectancy of high temperature piping systems - Google Patents

Abstract

1 page of the number 1 page summary of the invention Methods of extending the life expectancy of high temperature piping include when it has been determined that Continuous, stationary use cannot be performed by Assess the anticipation of the remaining service life of the rip-off of the creep of the treated portion. Welding of high temperature pipe system Removing part of the thermal insulation material Covering the position One with high creep tearing risk in high temperature piping And making surface temperature Outside of the piping system, the high temperature drops, especially at To extend the life expectancy of High creep risk location where the width of the exposed portion received This arrangement is obtained by removing part of the heat-insulating material. Will double Or more The distance from the stripped end of the exposed part. To part Area where Compressive stress is marked 0 after a change in tensile stress. And compression stresses that arise in high temperature piping systems Due to the removal of the thermal insulation material It is made from tensile stress to compression stress and the distance at which the post-compression stress is made from tensile stress to compression stress. Will be asymptote characteristics. 0 is based on the subsequent formula (1) (formula) (1) (3 is denoted by the subsequent formula (2) (formula). Here, V is the ratio of Piecsnes and the symbol a are the average radius of the pipe system and the symbol h is the sheet thickness of the pipe system.

Claims (9)

Disclaimer (all) which will not appear on the advertisement page. : ------ 19/02/2018 ------ (OCR) Page 1 of 3 pages. 1. A method of extending the service life expectancy of high temperature piping systems (11) has been used. When it was determined that Continuous use of stationary applications cannot be obtained. This is done by assessing the residual life expectancy of the tear-off. Creep of the welded part (12) of the high temperature pipe system (11) in which the assembly method is included Removing part of the thermal insulating material (13) covering one of the risky locations. High creep tear-off in high-temperature piping (11) and local low-temperature hypothermia of high-temperature piping (11) to extend life expectancy of the location where There is a high risk of tearing from creep. Where the width (L) of the exposed portion (14) that has been provided by the removal Part of the thermal insulating material (13) will be twice or more of its distance from the end at Has been stripped off of the exposed part (14) to part Where the compressive stress will be Directive 0 after the change in the stress between the tensile and compressive stress at Occurs in high temperature piping systems (11) Due to the removal of the thermal insulating material (13) it is made from the tensile stress to the compression stress and the distance (X) where the post-compression stress The change in stress is made from tensile stress to compression stress. Will be asymptote characteristics, 0 is based on the subsequent formula (1) (formula) (1), where J3 is represented by the subsequent formula (2) (formula). Here, V is the ratio. And the symbol a is the average radius of the pipe system (11) and the symbol h is the plate thickness of the pipe system (11). 2. Methods of extending the life expectancy of high temperature piping (11) according to claim 1, where the surface of the component where the upper The thermal insulating material (13) has been removed to be cooled. 3. Methods of extending the life expectancy of high temperature piping (11) in accordance with Clause 2, page 2 of the number 3, where cooling, air-cooled (23) or Cooling by led Cooling (33) 4. Methods of extending the life expectancy of high temperature piping (11) in accordance with claim 1, where the heat dissipation assembly is installed on the surface of the bump. Assembled where on top of that The thermal insulation material (13) has been removed. 5. Methods of extending the life expectancy of high temperature piping (11) in accordance with claim 1, where the surface temperature of the assembly where the upper The thermal insulating material (13) is removed, it is measured to determine whether Suitable cooling capability 6. Methods of extending the life expectancy of high temperature piping (11) in accordance with claim 5, where when cooling capacity is not appropriate The cooling capacity will Has been changed to suit 7. The structure extends the life expectancy of high temperature piping (11) for obtaining use when it has been determined that Continuous use of stationary applications cannot be regulated. This is done by assessing the residual life expectancy of tear-out creep. Of the high temperature piping system (11) in which the extended life expectancy structure has been provided It is obtained by removing part of the thermal insulating material (13) covering one of the risky locations. Tear-off from high creep in high-temperature piping (11) and tempering of the outer surface of High temperature piping system (11) particularly low Where the width (L) of the exposed part (14) is obtained by removing a part of the thermal insulating material (13) doubling or More than that of the distance from the stripped end of the exposed part (14) to the \ 'part, where the compression stress will be a directional 0 after the change in stress between The tensile and compression stresses that occur in high temperature piping systems (11) due to the removal of the thermal insulating material (13) are exerted from the tensile stress to the compression stress and the distance (X) at Where the compression stress after the stress change is made from tensile stress to compression stress is asymptote 0 is based on the formula (1) that follows page 3 of the number 3 (formula). (1) where /? Is denoted by the subsequent formula (2) (formula). Here, V is the ratio of the Piedmont, and the symbol a is the mean radius of the pipe system (11) and the symbol h. As the sheet thickness, of the pipe system (11) 8. Structure to expand the expectation of service life of high temperature piping system (11) in accordance with Clause 7, which includes Cooling unit Which cools the surface of the assembly where, on top, the thermal insulating material (13) has been removed. 9. Expansion structure, expect the life of high temperature piping system (11) in accordance with Clause 8, where the cooling unit is the air cooling unit (23). Cooling by conduction cooling (33) 1 0. Expansion structure, the expected life of high temperature piping (11), in accordance with claim 7, where the heat-dissipating assembly is installed on the surface of the tube. Assembled where on top of that Thermal insulation material (13) has been removed ------------ 1. One method of extending the life expectancy of high temperature piping systems that include When it was determined that Continuous use of stationary applications cannot be regulated. This is done by estimating the expected residual life of the tear-out of creep. Of the welded part of the high temperature pipe system Removing part of the thermal insulation material Which covers one location at risk of tearing This exits high creep in high-temperature piping and localized lowering of the outer surface temperature of the high-temperature piping system. To clarify Anticipate the service life of the location at high creep risk where the width of the exposed part is provided by the partial removal. Of thermal insulation material Will be twice as long Or so from the tip that has been peeled off Of the part that has been revealed To part Area where Compressive stress is characterized by a 0 asymptote line after a change in tensile stresses. And the compression stresses that arise in the high temperature pipe system due to the removal of the heat insulating material Will be made up from tensile stress to Compression stress and the distance at which it is compressed After the change, stress is made up of stress. Drawn to compression stress The asymptotes 0 are based on the subsequent formula (1) (formula) x = 5 (1) (formula) is represented by the following (2) formulas (formula) = (chemical formula ) (2) Here, v is the Poisson's ratio and the symbol a is the average radius of the pipe system and the symbol h is the plate thickness of the pipe system. 2. Method of extending the life expectancy of high temperature piping in accordance with claim 1, where the surface of the assembly Where on top The thermal insulation material has been removed to be cooled. 3. Methods of extending the life expectancy of high temperature piping according to claim 2, where cooling is being cooled by air. Or cooling by water Cooling 4. Methods of extending the life expectancy of high temperature piping in accordance with claim 1, where the heat-dissipating assembly is installed on the surface of the assembly where the that The thermal insulation material has been removed. 5. Methods of extending the life expectancy of high temperature piping in accordance with claim 1, where the surface temperature of the assembly Where on top The thermal insulation material has been removed. Will be measured to determine whether Is the cooling capacity appropriate or not? 6. Methods of extending the service life expectancy of high temperature piping in accordance with claim 5, where, when the cooling capacity is not suitable, the cooling capacity will Has been changed to suit 7. The structure extends the life expectancy of a composite high temperature piping system when it has been determined that Continuous use of stationary applications cannot be regulated. This is done by assessing the residual life expectancy of tear-out creep. Of high temperature piping systems Removing part of the thermal insulation material Which covers one location at risk of tearing Exit from high creep in high temperature piping systems The normalization of the outer surface temperature of the high temperature piping system where the width of the exposed part is provided by partial removal. Of thermal insulation material Will be twice as long Or so from the tip that has been peeled off Of the part that has been revealed To part Area where Compressive stress is characterized by a 0 asymptote line after a change in tensile stresses. And the compression stresses that arise in the high temperature pipe system due to the removal of the heat insulating material Will be made up from tensile stress to Compression stress and the distance at which it is compressed After the stress change is made up of the stress Drawn to compression stress The asymptotes 0 are based on the subsequent formula (1) (formula) x = 5 (1) (formula) is represented by the following (2) formulas (formula) = (chemical formula ) (2) Here, v is the ratio of Poisson and the symbol a is the mean radius of the pipe system and the symbol h is the sheet density of the pipe system. 8. Structure to expand the expectation of service life of high temperature piping according to claim 7, which includes Cooling unit Which cools the surface of the assembly Where on top of the heat-insulating material has been removed 9. Expansion structure of the expected service life of high temperature piping in accordance with Clause 8, where the cooling unit It is an air cooling unit or a water cooling unit. 0. Expansion structure, the life expectancy of the high temperature piping system in accordance with claim 7, where the heat-dissipating assembly will be installed on the surface of the assembly where it is. The thermal insulation material has been removed.