RU65277U1 - LABORATORY INSTALLATION FOR HEAT TRANSFER - Google Patents

Abstract

A useful model of a laboratory plant for heat transfer is designed to conduct training sessions in the disciplines "Heat Transfer" and "Heat Engineering".

The objective of the utility model is to increase the accuracy of measuring the temperature of the air flow due to the experimental study of the heat transfer process in a counterflow heat exchanger.

This problem is solved due to the fact that the laboratory unit for heat transfer, in which the body is made of cylindrical brass, containing two pipes placed one on the other, the inner pipe is open on both sides and contains an electric heater and two flow mixers, the outer pipe is open on top and the lower part has an outlet pipe, a vessel containing water with melting ice is mounted on the outside, has an inner pipe made of U-shaped brass, has an inlet restriction in the lower part to mix the flow before measuring By measuring the temperature of the heated air using a thermocouple and the output narrowing before measuring the temperature of the outgoing flow using a thermocouple, the bottom of the body has a branch pipe for the outlet of a cold air flow in which a thermocouple is installed, the temperature of the incoming air flow is determined by a thermometer installed in the laboratory. 1 pf 1 ill.

Description

A useful model of a laboratory plant for heat transfer is designed to conduct training sessions in the disciplines "Heat Transfer" and "Heat Engineering".

A well-known laboratory installation for heat transfer (see patent No. 2271509, priority of May 13, 2004, published on March 10, 2006, BI No. 7), comprising a housing made of two rectangular chambers - input and output - from plexiglass, on the outer surface An output chamber mounted a dewar vessel containing water with melting ice. The outer wall of the inlet chamber is made of aluminum foil, in front of which a panel with incandescent lamps is installed, the inlet and outlet chambers are separated by a heating surface made of aluminum foil and mounted on a frame. The inlet chamber in the upper part and the outlet chamber in the lower part are closed by covers in which nozzles are installed having a narrowing in the lower part and made of glass.

The disadvantage of this installation is the insufficient accuracy of temperature measurement, the complexity of the design, a small heat transfer surface, the need to use incandescent lamps.

The closest technical solution, taken as a prototype, is a laboratory unit for heat transfer (see application No. 2006138755 date of receipt in FIPS 02.11.2006), in which the casing is made of cylindrical brass containing two pipes placed one into the other. The inner pipe is open on both sides and contains an electric heater and two flow mixers. The outer pipe is open at the top and at the bottom has an outlet pipe, a vessel containing water with melting ice is mounted on the outside.

The disadvantage of this installation is the insufficient accuracy of temperature measurement due to the fact that it is impossible to obtain two-way movement of the hot stream and a small heat transfer surface.

The objective of the utility model is to increase the accuracy of measuring the temperature of the air flow due to the experimental study of the heat transfer process in a counterflow heat exchanger.

This problem is solved due to the fact that the laboratory unit for heat transfer, in which the body is made of cylindrical brass, containing two pipes placed one on the other, the inner pipe is open on both sides and contains an electric heater and two flow mixers, the outer pipe is open on top and the lower part has an outlet pipe, a vessel containing water with melting ice is mounted on the outside, has an inner pipe made of U-shaped brass, has an inlet restriction in the lower part to mix the flow before measuring By measuring the temperature of the heated air using a thermocouple and the output narrowing before measuring the temperature of the outgoing flow using a thermocouple, the bottom of the body has a branch pipe for the outlet of a cold air flow in which a thermocouple is installed, the temperature of the incoming air flow is determined by a thermometer installed in the laboratory.

Execution of a U-shaped internal pipe inside the casing, which allows creating a countercurrent flow diagram of the coolant in

Unlike the installation taken as a prototype. This increases the accuracy of temperature measurement. This heat transfer installation is compact, has a low cost, is convenient in operation and allows you to quickly enter the operating mode, as well as change it.

The utility model is illustrated by the figures:

Figure 1 presents the installation diagram.

Figure 2 is a top view of the installation.

Figure 3 - presents a diagram of the temperature changes of hot and cold streams.

Laboratory installation for heat transfer includes a housing 1 made of brass, which has a rectangular cross-section (figure 2), the upper part is open for air inlet. Inside the housing 1, a U-shaped pipe 2 made of brass is mounted. On the casing 1 from the outside there is a vessel 3 containing water with melting ice. An electric heater 4 is placed in the input section of the housing 1, the power of which is set by the LATR 5 and controlled by a power meter 6. The pipe 2 has an inlet restriction in the lower part 7 for mixing the flow before measuring the temperature t ₁ 'of heated air using a thermocouple 8 and an output restriction 9 before measuring the temperature t ₁ ″ of the outlet stream using a thermocouple 10. At the bottom of the housing 1 there is a pipe 11 for exiting a cold air stream, in which a thermocouple 12 is installed to measure the temperature t ₂ ″. The temperature of the incoming air flow t ₂ 'is determined by a thermometer installed in the laboratory.

A tap 13 is provided for draining the water.

The mass flow rates of both flows are found by the value of the velocity of the outgoing heat carriers using an electronic anemometer.

Installation works as follows.

The vessel 3 is filled with water with melting ice and the electric heater 4 is turned on, setting the set power with the LATR 5 and controlling it with a power meter 6. After 2-3 minutes, the readings are recorded

Thermocouple 8 (t ₁ '') and 12 (t ₂ '') until the steady state. Then, the values of all temperatures and air flow rates are recorded in the observation log.

The heat transfer laboratory installation was developed at the Department of Heat and Gas Supply and Ventilation of the Institute of Architecture and Construction of Siberian Federal University and has the following advantages: the accuracy of temperature measurement is increased, it is simple in design, cheap, intuitive, it allows you to easily set the operating mode, and you can create an efficient compact installation due to free convection air and does not require the use of water vapor and tap water.

Claims (1)

Heat transfer laboratory installation, in which the casing is made of cylindrical brass, containing two pipes placed one on the other, the inner pipe is open on both sides and contains an electric heater and two flow mixers, the outer pipe is open at the top and has an outlet pipe in the lower part, mounted outside a vessel containing water with melting ice, characterized in that the inner pipe is made of U-shaped brass, has an inlet narrowing in the lower part for mixing the flow before measuring the temperature of the heated air by means of a thermocouple and the outlet constriction before measuring the temperature of the outlet stream using a thermocouple, in the bottom of the body there is a nozzle for exiting a cold air stream in which a thermocouple is installed, the temperature of the incoming air stream is determined by a thermometer installed in the laboratory.