SU932149A1 - Unit for absorbing water vapours at sublimitation drying - Google Patents

Description

The invention relates to refrigeration, and more specifically to installations of the absorption type for absorption of water vapor during freeze-drying.

Known installations for absorbing water vapor during freeze-drying, containing a sublimator with a heat exchange surface inside and a solution circulation loop in which an absorber connected to a sublimator is installed, a pump, a heat exchanger, a generator with lines of weak and strong solutions, and a boiler, the vapor space of which is connected by means of an ejector to a heat exchange sublimator surface D].

A disadvantage of the known installations is their low efficiency due to the high consumption of steam,. necessary to evaporate a weak solution in a boiler.

The purpose of the invention · is to increase the efficiency of the installation by using solar energy to evaporate the specified solution.

This goal is achieved by the fact that in the line of a weak solution after the heat exchanger-regenerator through a three-way valve, a heater is connected in parallel, connected to an external heat source by means of a control valve, and a solar heater equipped with a temperature sensor, connected at the outlet to the boiler, and the sensor is electrically connected to the control and three-way valves.

The drawing shows a hydraulic diagram of the proposed installation.

The installation contains a sublimator 1 ό ^ with a heat exchange surface 2 inside, an absorber 3, a heat exchanger-regenerator 4 with lines 5 and 6 of weak and strong solutions, a boiler 7, an ejector 8, a three-way valve 9, a heater 10, which controls the vein ₍ til 11, solar heater 12 and a temperature sensor 13, electrically connected to the three-way and control valves 9 and 11.

In addition, the installation includes a pump 14 for a weak solution, a vacuum pump 15, a mixer 16, a recirculation pump 17 and a water cooler 18.

Installation works as follows.

In the sublimator, under the action of condensing steam supplied to the heat exchange surface 2 from the boiler 7 by means of an ejector 8, the dried product is heated under high vacuum. The resulting vapors are sucked into the absorber 3, in which they are absorbed by a circulating aqueous solution of lithium bromide. The liberated heat of absorption is removed by cold water in the cooler 18. The weak solution formed in the absorber 3 is taken up by the pump 14 and fed through line 5 of the heat exchanger-regenerator 4 in parallel through the heater 10 and the solar heater 12 to the boiler 7, in which it is partially freed from water vapor and becomes strong .From here, a strong solution is supplied through line 6 of the heat exchanger of the regenerator 4 'to the mixer 16, from where it is taken by the recirculation pump 17 and sent through the cooler 18 again to the absorber. With excess solar energy In the case of energy, most of the weak solution is fed through the three-way valve 9 to the solar heater 12. If the amount of solar energy is small, then most of the weak solution is sent through the three-way valve 9 to the heater 10, connected through the control valve 11 to an external heat source (not shown). The opening of the three-way valve 9 and the control valve is controlled by the pulse of the temperature sensor 13 installed on the pipeline of the heated weak solution after the solar heater 5.

The economic efficiency of the invention is expressed in reducing the consumption of expensive heat used to heat a weak solution from an external heat source. So, for a plant with a capacity of 1000 kg / h of removed moisture, the savings amount to 240 thousand standard fuel per year.

Claims (1)

The invention relates to a cooling technique, and more specifically to absorption type installations for the absorption of water vapor upon sublimation. drying. Installations for the absorption of water vapor during freeze-drying are known, containing a sublimator with heat exchange surface inside and a circulation circuit for the solution, which is equipped with an absorber connected to the sublimator, a pump, a heat exchanger regenerator with lines of weak and strong solutions, and a boiler, pyrene space which is connected via an ejector to the heat exchange surface of the sublimator. A disadvantage of the known installations is their low economic efficiency due to the high steam consumption required for evaporation of the weak solution in the boiler. The purpose of the invention is to increase the economics of the installation by using solar energy to evaporate said solution. This goal is achieved by connecting a preheater connected to an external heat source through a regulating valve and a solar heater equipped with a temperature sensor connected downstream to the boiler, and the sensor electrically connected to the line of a weak solution after the heat exchanger-regenerator through a three-way valve. Zan with regulating and three-way valves. The drawing shows the hydraulic circuit of the proposed installation. The installation contains a sublimator 1 d with a hopper-exchange surface 2 inside, an absorber 3, a heat exchanger-regenerator k with lines 5 and 6 of weak and strong solutions, a boiler 7, an ejector 8, a three-way valve 9. a heater 10 regulating the fan j 11, solar heater 12 and 3 temperature sensor 13, electrically associated with three-way and regulating valves 9 and 11. In addition, the installation contains a pump for a weak solution, a vacuum pump 15, a mixer 16, a recycling pump 17 and water cooling Tel 18. The installation works as follows. In the sublimator, under the action of condensing steam supplied to the heat exchange surface 2 from the boiler 7 by means of the ejector 8, the product being dried is heated under high vacuum. The formed vapors are sucked into the absorber 3, in which they are absorbed by the circulating aqueous solution of lithium bromide. Heat absorbed by the heat absorbed by cold water in the cooler 18. The weak solution produced in the absorber 3 is collected on the pump 1 and is fed through line 5 of the heat exchanger-regenerator in parallel through the heater 10 and the solar heater 12 to the boiler 7, which is partially freed from water vapors and becomes strong. From here, a strong solution is fed through line 6 of the heat recovery compressor 4 to mixer 16, from where it is collected by the recirculation pump 17 and sent through cooler 18 again to the absorber. With an excess of solar Most of the weak solution is supplied through a three-way valve 9 to the solar heater 12. If the amount of solar energy is low, most of the weak solution is directed through the three-way valve 9 to the heater 10 connected via a regulating valve 11 to an external heat source (not shown). ). The regulation of the opening of the three-way valve 9 and the control valve is made according to it. the pulse of a thermal sensor 13 installed on the pipeline of a heated weak solution after the solar heater 12. The economic efficiency of the invention is expressed in reducing the consumption of expensive heat going to heat the weak solution from an external heat source. So, for an installation with a capacity of 1000 kg / h, the moisture that is removed is a saving of 2kQ thousand standard fuel per year. An inventive apparatus for absorbing water vapor during freeze-drying, comprising a subplate with a heat exchange surface inside and a circulation loop for a solution in which an absorber connected to the sublimator, pump, heat exchanger-regenerator with lines of weak and strong solutions, and boiler are installed, the vapor space of which is connected by means of an ejector to the heat exchanging surface of the sublimator, characterized in that, in order to increase efficiency, into the line of a weak solution after the heat exchanger-rega eratora parallel through the three-way valve incorporated heater associated with extraneous heat source via a control valve, and the solar heater fitted with a temperature sensor, connected at the output to the reboiler, and the sensor is electrically connected with the control and the three-way rectifiers. Sources of information taken into account in the examination 1. USSR author's certificate in application No. 273877 /, cl. F 25 8 15/16, 1979.