SU606003A1 - Stand for thermal and hydraulic tests of liquid-liquid heat exchangers - Google Patents

Description

(S4) STAND FOR HEAT AND HYDRAULIC TESTS OF LIQUID LIQUID OIL HEAT EXCHANGERS

The invention relates to heat engineering, in particular to research into the thermal and hydraulic characteristics of liquid-to-liquid heat mixtures and their testing on a stand, and installations.

There are stands and definitions of the thermal and hydraulic characteristics of liquid-liquid heat exchangers, containing basic (illrklnuyu) circuits with heat and coolant, which include the tube and tube sides of the test heat exchanger, while the coolant is also the working medium 1.

The known stands have the following disadvantages: the range of temperature loads is limited, since there is no possibility of lowering the temperature of the working medium; the use of ToimoHocirrenfl as a working medium and its direct heating with an electric heater limits the possibility of working with various media; the use of tap water as a coolant is not economically viable and limits the temperature range; not provided complete filling of the cavities of the test heat exchanger. These disadvantages narrow the temperature

range and area of application and reduce the quality of the test.

The aim of the invention is to conduct tests in a wide range of temperature loads.

This goal is achieved by the fact that the stand is equipped with intermediate circuits for heated and cooled media connected by pine co-guards using recuperative heat exchangers. From the side of the test heat exchanger, a vacuum pump is connected to the intermediate circuits. At the same time, the evaporator of the compression refrigeration unit of the main coolant circuit is made in V1 more than two parallel connected recuperative heat exchangers.

Claims (3)

The working media are heated or cooled by the U) Intermediate circuits to the required temperature in recuperative heat exchangers due to heat exchange between the heat and coolants of the main circuits and media without their mixing, which ensures testing in different media in the range of temperature loads. Full filling with working medium is achieved by preliminary vacuuming of the tube and intertubular cavities of the test heat exchanger with a vacuum pump. In order to increase the cooling efficiency of the main circuit coolant, liquid-liquid recuperative heat exchangers with a significantly higher heat transfer coefficient are used. The drawing shows schematically a pre-stand, which contains the main circuits of heat and coolants and intermediate circuits A and B for the heated and cooled media with the heat exchanger under test. The coolant circuit contains a compressing REFRIGERATING machine 1 with a condenser 2 and an evaporator — recuperative heat exchangers 3, a collection tank 4, a pump 5, recuperative heat exchangers 6 and 7 (coolers), valves 8 and 9, and pipelines. The coolant circuit contains a collection tank 1 with a heater 11, a pump 12, recuperative heat exchangers 13 and 14 (heaters), valves 15 and 16, and pipelines. . Intermediate circuits A and B are connected in parallel through the second cavities of the recuperative heat exchangers 13 and 14, 6 and 7, respectively, into the main circuits of heat and coolants that are interchangeable in operation, have the same circuit and design, and respectively contain containers 17 and 18 with the required working medium, pumps 19 and 20, flow meters 21 and 22, legs 23 and 24, test heat exchanger 25, valves 26 and 27, devices 28, 29 and 30, 31 temperature measurements, differential manometers 32, 33 and pipelines. The vacuum pump 34 is connected to the heat exchanger under test by pipelines with valves 35 and 36, the vacuum is determined by the device 37. The stand operates as follows. The sweetener from the collecting tank 4 is pumped through pipelines 8 through valve 8 or 9 into the cavity of the heat exchanger 6 or 7, after which the heat exchangers 3 are fed to the evaporator for cooling to the evaporator 4 and discharged into the tank 4. The coolant from the collecting tank 10 is pumped 1 through pipelines through valve 15 or 1 into the cavity of the recuperative heat exchanger 13 or and is discharged into the tank 10. The workers cpey i from the respective tanks 17 and 18 are pumped through pumps 19 and 20 through the second cavities of the recuperative heat exchangers 6 and 13 and 7 and 14, flow meters 21 and 22 C tube and annular cavity of the test heat exchanger 25 and merge into the tank 17 and 18; the flow rates of the media are controlled by valves 23 and 24. Fully filling the working medium is ensured by preliminary evacuation of the tube and annular space of the test heat exchanger with a vacuum pump 34, for which valves 35 and 36 open and valves 23, 26 and 24, 27 intersect; The magnitude of the vacuum is determined by the device 37. Recuperative stand heat exchangers — liquid-liquid radiators with pipe and inter-tube cavities hermetically insulated from each other, which allows the use of different liquids in the main and intermediate circuits, since their mixing is excluded. By use of the intermediate circuits associated recuperative heat exchangers with basic circuits heat and refrigerants, pre mu evacuated test exchanger cavities before medium filling and vsholneniyu evaporator compression holodilnots ma tire as recuperative heat exchangers, provided tests provededae a wide temperature range of loads, full, filling the pipe and annular cavities of the test heat exchanger with the medium, increased the efficiency of the cooling Noah machines and test quality. Claim 1. A stand for thermal and hydraulic tests of liquid-liquid heat exchangers containing Shchirkryl circuits of heat and coolant, which include, respectively, the tube and tube side of the test heat exchanger, in order to conduct tests in a wide range of temperature loads, the stand is equipped with intermediate circuits for heated and cooled media, which are connected to the main circuits with the help of recuperative heat exchangers. 2. Stand POP.1, characterized in that the main circuit of the coolant contains a compression refrigeration machine, the evaporator of which is made in the form of two parallel-connected recuperative heat exchangers, 3. The stand on PL, characterized in that a vacuum pump is connected to the intermediate circuits on the side of the heat exchanger under test. Sources of information taken into account in the examination: 1. Osipova V. A. Experimental study of heat exchanger processes. M., Energie, 1969, pp. 229-233.