Standard Test Method for Steady-State Heat Flux Measurements and Thermal Transmission Properties by Means of the Guarded-Hot-Plate Apparatus

Importancia y uso:

5.1 This test method covers the measurement of heat flux and associated test conditions for flat specimens. The guarded-hot-plate apparatus is generally used to measure steady-state heat flux through materials having a “low” thermal conductivity and commonly denoted as “thermal insulators.” Acceptable measurement accuracy requires a specimen geometry with a large ratio of area to thickness.

5.2 Two specimens are selected with their thickness, areas, and densities as identical as possible, and one specimen is placed on each side of the guarded-hot-plate. The faces of the specimens opposite the guarded-hot-plate and primary guard are placed in contact with the surfaces of the cold surface assemblies.

5.3 Steady-state heat transmission through thermal insulators is not easily measured, even at room temperature. This is due to the fact heat transmission through a specimen occurs by any or all of three separate modes of heat transfer (radiation, conduction, and convection). It is possible that any inhomogeneity or anisotropy in the specimen will require special experimental precautions to measure that flow of heat. In some cases it is possible that hours or even days will be required to achieve the thermal steady-state. No guarding system can be constructed to force the metered heat to pass only through the test area of insulation specimen being measured. It is possible that moisture content within the material will cause transient behavior. It is also possible that and physical or chemical change in the material with time or environmental condition will permanently alter the specimen.

5.4 Application of this test method on different test insulations requires that the designer make choices in the design selection of materials of construction and measurement and control systems. Thus it is possible that there will be different designs for the guarded-hot-plate apparatus when used at ambient versus cryogenic or high temperatures. Test thickness, temperature range, temperature difference range, ambient conditions and other system parameters must also be selected during the design phase. Annex A1 is referenced to the user, which addresses such issues as limitations of the apparatus, thickness measurement considerations and measurement uncertainties, all of which must be considered in the design and operation of the apparatus.

5.5 Apparatus constructed and operated in accordance with this test method should be capable of accurate measurements for its design range of application. Since this test method is applicable to a wide range of specimen characteristics, test conditions, and apparatus design, it is impractical to give an all-inclusive statement of precision and bias for the test method. Analysis of the specific apparatus used is required to specify a precision and bias for the reported results. For this reason, conformance with the test method requires that the user must estimate and report the uncertainty of the results under the reported test conditions.

5.6 Qualification of a new apparatus. When a new or modified design is developed, tests shall be conducted on at least two materials of known thermal stability and having verified or calibrated properties traceable to a national standards laboratory. Tests shall be conducted for at least two sets of temperature conditions that cover the operating range for the apparatus. If the differences between the test results and the national standards laboratory characterization are determined to be significant, then the source of the error shall, if possible, be identified. Only after successful comparison with the certified samples, can the apparatus claim conformance with this test method. It is recommended that checks be continued on a periodic basis to confirm continued conformance of the apparatus.

5.7 The thermal transmission properties of a specimen of material have the potential to be affected due to the following factors: (a) composition of the material (b) moisture or other environmental conditions (c) time or temperature exposure (d) thickness (e) temperature difference across the specimen (f) mean temperature. It must be recognized, therefore, that the selection of a representative value of thermal transmission properties for a material must be based upon a consideration of these factors and an adequate amount of test information.

5.8 Since both heat flux and its uncertainty may be dependent upon environmental and apparatus test conditions, as well as intrinsic characteristics of the specimen, the report for this test method shall include a thorough description of the specimen and of the test conditions.

5.9 The results of comparative test methods such as Test Method C518 depend on the quality of the heat flux reference standards. The apparatus in this test method is one of the absolute methods used for generation of the reference standards. The accuracy of any comparative method can be no better than that of the referenced procedure. While it is possible that the precision of a comparative method such as Test Method C518 will be comparable with that of this test method, Test Method C518 cannot be more accurate. In cases of dispute, this test method is the recommended procedure.

Subcomité:

C16.30

Referida por:

D7425_D7425M-13R19, C1937-24A, C1071-19, D5930-17, C0800-19, C0665-23, C1859-23, D3748-14R19, C1045-19, C0332-23, C0332-23, C0209-20, C1393-19, C0547-22A, E1591-20, C0728-17AR22, C1676_C1676M-23, C0726-24, C1427-21, C0549-23, C1014-17, C0892-19R24, F1868-23, F2165-24, C1290-16R21, C0610-17R23, C0552-22, C0449-07R24, E1091-21, C0592-22A, C1482-24E01, C0516-19, C0764-19, E1231-24, E2785-14R22, C1484-10R18, E0861-13R21, F0942-18R23E01, C0553-13R19, C1512-10R20, D4612-16, C0653-24, C0656-17R23, C1685-15R21, C1126-19, D8157-19, C0739-24, D3575-20, C1534-24, C0196-00R19, C1289-23A, C1470-20, E1730-19, C0591-22, C1149-23, C0240-21, C0991-23, D4101-24, C0612-14R19, C0447-15R22, F3319-20, C1558-24, F3340-22, C1224-22, C1822-21, C1410-17R23, C1728-23, C1902-22A, C0533-17R23, F3562-24, C1497-24, C1086-20, C0534_C0534M-23, C1146-09R18, F2178_F2178M-23A, C1029-20, C0578-23, C1594-23, C0195-07R24, C1373_C1373M-23, C1058_C1058M-10R23, C0687-18, D1039-16R22, D5364-14R24, C0680-23A, C1044-24, C0335_C0335M-23, C1130-24, C1114-06R19, C1774-24, D0116-86R20, D5456-21E01, C1043-24, C1363-24, C1696-20, D5144-08R21, E3057-19, C0518-21, C1199-22, C1303_C1303M-23

Volúmen:

04.06

Número ICS:

17.200.10 (Heat. Calorimetry)

Palabras clave:

error analysis; guarded-hot-plate; heat flow; heat flux; steady-state; thermal conductivity; thermal resistance; thermal transmission; thermal conductance; thermal testing;