SU1265564A1 - Method for checking quality of vacuum flasks - Google Patents

Abstract

This invention relates to methods for controlling the quality of thermoses by the active thermal method. The purpose of the invention is to increase the reliability and speed up the quality control of the thermal insulation of thermoses. This is achieved by heating the internal flasks of the thermometers with warm heat from the radiator and cooling the external flasks of the thermoses in the refrigerator of the refrigerating machine. Through the refrigerator of the cold machine, the thermograms are looped through, and the differential radiometer compares the temperature of the internal flasks of the thermoses at the inlet and outlet of the refrigerator and generates a signal for rejecting the output thermoses if the difference between the temperature parameters is higher than nominal. SL 1 Il.

Description

The invention relates to methods for non-destructive quality control of household industrial thermoses using an active thermal method.

The purpose of the invention is to increase reliability and accelerate quality control of thermal insulation of thermoses.

The drawing schematically shows a device for implementing a method for controlling the quality of thermoses.

A device for carrying out quality control of thermos flasks ^: holds a refrigerator with a heat exchanger 1, a radiator 2 and a refrigerator 3, as well as a blower 4, gas nozzles 5, which supply air to the inner flasks of the thermos 6, as well as a differential radiometer 7 and processor 8.

When implementing the method of controlling the quality of thermoses, the thermoses 6 to be monitored are supplied alternately to the input of the device, and after passing the control, they are removed from its output. In this case, the thermoses 6 move stepwise with a linear step h, a temporary '’t and a stop time

During a stop, warm air is introduced into the inner flasks of the thermos 6 using gas nozzles 5. To facilitate convective heat transfer during purging and retaining thermal air in their inner flasks: by subsequent movement of the thermos 6, turn the neck down. Warm air is formed in the heat exchanger 1, where the atmospheric air. Takes heat from the radiator 2 of the refrigeration machine. The atmospheric air is drawn by a blower 4. It is advisable to supply air to several gas nozzles 5 located at a distance equal to step h from each other.

This allows to minimize hydraulic losses by reducing the speed of gas jets and to achieve the same heating of the inner flasks of all thermoses 6. As a result of the supply of warm air, the air temperature in each thermos 6 becomes higher than the ambient temperature, but slightly lower than the temperature of the radiator 2.

When the thermos 6 enters the refrigerator 3, the outer flask of the thermos 6 begins to cool, and after a while its temperature becomes equal to the temperature of the refrigerator, and the temperature gradient between the inner and outer flasks of the thermos 6 reaches its maximum value.

After cooling in the refrigerator 3, the thermos 6 approaches the receiving chamber of the differential radiometer 7 located between the inlet and the outlet of the refrigerator 3. During the stop time fit, the differential radiometer compares the air temperatures in the inner flasks of the chilled thermos 6 and the corresponding thermos 6 supplied for cooling. If the temperature difference fiT turns out to be higher than the nominal, the differential radiometer 7 gives a signal to the processor 8 to reject the outgoing thermos.

Due to the use of a refrigerating machine at the same time for heating and cooling thermos flasks, the method allows to reduce energy consumption for controlling the quality of thermoses, while a high control speed is achieved due to the main property of the loop-like chain - stretching the cooling time of thermoses in the refrigerator. Thanks to the cooling of the outer bulb, the internal cavities in the in and out of the refrigerator thermos have a different temperature even when the heating of the inner bulb is turned off. The heat removed from the radiator of the chiller allows you to heat the inner flasks of all thermoses coming to the control to the same temperature. This fact, combined with the possibilities of differential radiometer, and improves the reliability _of kontro- la.

& about

Claims (3)

The invention relates to methods: non-destructive quality control of household industrial thermoses using the active thermal method. The purpose of the invention is to increase reliability and speed up the quality control of thermo insulations. The drawing shows schematically an apparatus for carrying out a method for controlling the quality of thermos flasks. A device for carrying out the process; the thermoses quality control unit contains a refrigeration machine with a heat exchanger 1, a radiator 2 and a refrigerator 3, as well as a blower 4, gas nozzles 5 feeding air into the internal flasks of thermoses 6, as well as a differential radiometer 7 and pro; Cesoryor 8. i With the help of the control method (the quality of the thermoses, the thermoses 6 to be monitored are received alternately: but at the input of the device, and after passing the control, they are removed from its output. In this case, the thermoses 6 move in a stepwise manner with a linear pitch h time t and stop time t During the stop time, warm air is introduced into the internal flasks of the thermoses 6 by means of gas nozzles 5. To facilitate convective heat exchange when purging and retaining the thermal: air in the internal flasks and them: subsequent movement of the thermoses 6 next Do not turn the neck down, Warm air is formed in the heat exchanger, where the atmospheric air: the heat from the radiator 2 of the cooling machine is blown in. The atmospheric air is blown out by the blower 4. It is advisable to supply air to several gas nozzles 5 that are spaced apart from each other. This equals the step h. This allows minimizing hydraulic losses by reducing the velocity of the gas jets and achieving the same heating of the internal flasks of all thermoses 6. As a result of the supply of warm air, the temperature of the air rxa each thermos 6 becomes vsh1e ambient temperature but somewhat lower temperature radiator 2. When the thermos 6 enters the refrigerator 3, the external flask of the thermos 6 begins to cool, and after some time its temperature becomes equal to the temperature of the refrigerator, and the temperature gradient between the internal and external flasks of the thermoses 6 reaches the maximum value. After cooling in the refrigerator 3, the thermos 6 approaches the receiving chamber of the differential radiometer 7 located between the entrance and the exit of the refrigerator 3. During the shutdown time, ut, the differential radiometer compares the air temperature in the internal flasks of the cooled thermos 6 and the corresponding thermos 6 supplied to the cooling. If the temperature difference ΔT turns out to be higher than the nominal one, the differential radiometer 7 issues a signal to the processor 8 to reject the outgoing thermos. By using the refrigerating machine at the same time to heat and cool flasks of thermoses, the method reduces the energy consumption for quality control of thermoses, while achieving a high speed of control due to the main property of the loop-like chain - stretching the cooling time of thermoses in the refrigerator. Due to the cooling of the external bulb, the internal cavities in the thermoses in and out of the refrigerator have different temperatures when the heating of the internal flask is turned off. The heat removed from the radiator of the chiller allows the internal flasks of all the thermoses coming into the control to be heated to the same temperature. This circumstance, in combination with the capabilities of the differential radiometer, makes it possible to increase the reliability and control. Formula of images The method of controlling the quality of thermoses, including creating a temperature gradient between the internal and external flasks of the thermos by heating the air in the internal flask and estimating the heat leakage by changing the temperature in it, which in order to increase the reliability and accelerate the monitoring of the thermal insulations , to create a temperature gradient between the inner and outer flasks of thermoses, a refrigeration machine is used, with In this case, the internal flasks of the thermoses are heated with air coming from a heat exchanger that cools the radiator of the rlodilb machine, after which the thermoses are looped through a refrigerator through the refrigerator of the refrigerating machine and the temperatures of the internal flasks of the thermoses entering and leaving the refrigerator are compared with a differential radiometer, which is rejected outgoing thermoses. ir-