SU930087A1 - Method of measuring material heat capacity - Google Patents

Description

(54) METHOD OF MEASURING HEAT CAPACITY The invention relates to thermal measurements of the physicochemical properties of materials, in particular to a calorimetric method of measuring the heat capacity of materials, and is used in various energy conversion devices. Methods are known for measuring the heat capacity, for example, adiabatic, isothermal, and required. large time costs, direct contact with the sample of the material under study. Therefore, during radiation testing of materials with their help, it is possible to measure the heat capacity of the material either before irradiation or after irradiation using the remote control of the movement of a radioactive sample. A disadvantage of the known methods for measuring the heat capacity is that they allow the heat bone to be determined directly during irradiation. MATERIALS The closest to the invention in its technical essence and the achieved result is a method for measuring the heat capacity of materials during irradiation by determining the growth rate of the temperature of the sample under study. According to a known method for measuring the heat capacity of material C during irradiation, it is necessary to measure the rate of temperature rise (9T / BT) for the reference and test samples at a exactly we and that point of the radiation field with a strictly constant radiation intensity, then use the known ratios to determine C G2. The main disadvantages of the known method are that measuring C in a wide temperature range is impossible and radiation can practically only be carried out in a radiation field. neither The purpose of the invention is to expand the temperature range of measurements of heat capacity during irradiation without restrictions on the type of radiation and the properties of the material under study. This goal is achieved by the fact that according to the method of measuring the heat capacity of materials under radiation exposure by determining the rate of growth of the sample temperature, electric, radiation and joint radiation are produced consistently | Electric heating of the sample under adiabatic conditions, maintaining a constant electric power of heating and joint heating , and radiation and joint heatings are carried out in the course of irradiation, after which, according to the measured growth rates. quenching the required heat capacity C to the heat capacity of an unirradiated sample of Co according to the formula g / g - (- T / ET) o U-1-H () 4 where (ET / BT) (d, () (2) is the rate of temperature rise of the sample with electric , radiation and joint radiation-electric heating, respectively, determined for the same temperature of the experiment. In addition, measurements of the heat capacity are performed many times as the radiation dose is measured by the sample. The method is carried out as follows. 1. The sample is electrically heated in a given temperature range under adiabatic conditions using a heater on the sample at a certain constant power. Rad As a result, the GO / T / dependence and the auxiliary curve C VT / Eg) o / T / are obtained, where GO is the specific heat of the unirradiated sample, T is the temperature. Here we have RED So (et / et). (2) 2. After the sample is introduced into the field and radiation (the type of radiation does not play a role from a methodological point of view), stabilization of the temperature mode and the set of the first of the set values of the absorbed radiation dose, turn on the composite heater and record the temperature changes under adiabatic conditions. in time due to radiation heating. Then Рро, д С (ЭТ / ЭГ) (3) where С is the unknown specific heat capacity of the sample during the irradiation at the dose set to the measurement point; radiant heat power RL release. 3. The compensation heater is disconnected, the output of the initial temperature level is turned on, the heater is turned on, setting the REM power (clause 1) and the change in the sample temperature in the specified range is recorded under adiabatic conditions. To increase the accuracy of determination of C, the value of RDD must not exceed the value of Rrdd by at least 2 times. In this case, REA - C (.ET / EG) 2. (4) from (3) and (4) follows CEA C 1 (fl / fl:) a- (9T / egg) (5) Comparing (5) and (2), we get (dT / dg) about 0 (fl / dt g- (at / et. Here, all values of the derivatives are taken at the same test temperature. 4. Both heaters are turned off and radiation continues until the next prescribed dose is set. The operations of paragraphs 2 and 3 are repeated each time. The process itself Since during radiation tests and studies, the main interest is not the absolute value of the heat capacity G, but its relative change in C / C, the error of the proposed Sob is obtained no more than 5. If the change in G in a given temperature range does not exceed, then the operation according to claim 2 can be reduced to measurement only at the initial temperature of the experiment. As an example of a method for measuring the heat capacity of materials, consider the definition of the heat capacity of high-pressure polyethylene. supply a working electric heater with a resistance of about 1000 m. The resistance of the compensation heater is about 200 Ohms (the material of the heaters is constant). Sample with sheath

Claims (1)

Claim A method for measuring the heat capacity of materials under radiation exposure by determining the rate of increase in temperature of the sample, which differs, in that, in order to expand the ₅₅ • V temperature range for measuring heat capacity, electrical, radiation and joint radiation-electric heating of the sample is carried out in series under adiabatic conditions, keeping constant electric power during electric and joint heating, and radiation and joint heating are performed in the process of irradiation, after which the measured velocities growth temperature is determined the ratio of the desired heat capacity C of the specific heat of the unirradiated sample C _of the formula S / S ₀ where (9T / _{dr) t0)} - velocity grew that the sample temperature at an electric, radiative and joint radiation electric heating respectively defined for audio and same temperature experience.