SU1599031A1 - Evaporator system - Google Patents

Abstract

The invention relates to the design of contact evaporators and is intended for use in the chemical, petroleum refining and other industries of the industry for concentrating solutions and the production of distillate. The aim of the invention is to increase the economics of the evaporation process and prevent the evaporation of evaporated substances into the atmosphere. The evaporator unit contains a recuperative heater of the evaporated solution, a vapor-gas mixture cooler, a contact gas-liquid heat exchanger with an additional heater, connected in series with each other along the vapor-gas mixture line. The outlet of the gas-vapor mixture of the contact gas-liquid heat exchanger is connected to the inlet of the recuperative solution preheater, forming a closed loop of the gas-vapor mixture in which the gas blower is installed to pump the vapor-gas stream. The plant is also equipped with a heat pump to increase the temperature potential of the gas-vapor mixture. The cooling heat exchange surface of the heat pump is located in the vapor-gas mixture cooler, and the heating heat exchange surface is located in the additional heater of the contact gas-liquid heat exchanger. 1 il.

Description

The invention relates to the design of contact evaporators and is intended for use in chemical, petrochemical, food processing and other industries for evaporation of solutions and distillate.

The aim of the invention is to increase the economics of the evaporation process and prevent the evaporation of evaporated substances into the atmosphere.

The scheme of the proposed installation shown in the drawing.

The installation includes a recuperative gas-liquid heater 1 solution, a cooler 2 of the gas-vapor mixture a gas blower 3, a contact gas-liquid

heat exchanger 4. The outlet 5 of the gas-vapor mixture of the contact gas-liquid heat exchanger 4 is connected to the inlet port 6 of the gas-vapor mixture of 1 solution preheater with the formation of a closed loop of the vapor-gas mixture. The outlet 7 of the evaporated solution of the contact gas-liquid heat exchanger 4 is connected to the inlet 9 of the evaporated solution of the solution preheater by means of a circulation pump 8 with the formation of a closed loop of the evaporated solution. The installation is equipped with a heat pump. 10. A cooling heat exchange surface M of which is located in the cooler of the vapor-gas mixture 2, and the heating heat exchange surface 12 times.

 with

05

placed in the contact gas-liquid heat exchanger 4.

The installation works as follows.

In the preheater 1 of the evaporated solution, a hot humidified vapor – gas mixture and a solution from the contact gas – liquid heat exchanger 4 are fed. At the same time, water vapor condenses from the vapor – gas mixture and transfers the heat of condensation to the solution. The cooled and dried vapor-gas mixture enters the cooler 2 of the vapor-gas mixture, where it is further cooled to a temperature below the temperature of the solution at the outlet of the heat exchanger 4. Then the finally cooled and dried vapor-gas mixture enters the contact gas-liquid heat exchanger 4, which is also fed heated in the heater 1 evaporated solution. Upon contact of the hot solution and the cold vapor-gas mixture, the liquid evaporates into the gas stream. In this case, heating and moistening of the vapor-gas mixture and cooling of the evaporated solution takes place. The heat removed from the gas-vapor mixture in the cooler 2 of the gas-vapor mixture is transferred by heat pump 10 to the heat exchange surface 12. Heated and moistened in the contact gas-liquid heat exchanger 4, the steam-gas mixture enters the preheater 1. It is also cooled through and partially evaporated in the heat exchanger 4 solution.

The initial solution coming to evaporation is fed to the closed circulation loop of the evaporated solution, formed by the preheater 1 solution, the contact gas-liquid heat exchanger 4 and the circulation pump 8. From the same circuit, the solution is evaporated to the required concentration.

Thus, in the proposed installation, heat is removed from the gas-vapor mixture and this heat is transferred to the evaporated solution in the preheater 1. In the contact gas-liquid heat exchanger 4, this heat is spent on additional evaporation of a part of the solution. Calculations show that in solution heater 1 it is possible to transfer approximately 70-75% of the heat contained in the vapor-gas mixture entering the heater 1. The rest of the heat (25-30%) must be removed from the vapor-gas mixture in cooler 2. Temperature potential this heat is increased by the heat pump 10. As a result, this heat

can again be transferred to the gas-vapor mixture using the surface 12 placed in the contact gas-liquid heat exchanger 4.

Thus, when the proposed installation works, only the flow rate takes place.

electricity for operation of the gas blower 3, the circulation pump 8 and the heat pump 10 without heat supply for evaporation of the solution from the environment. Calculations show that if, in a known installation, the total consumption of heat and electric energy consumed for evaporation is 1530 kJ / kg of evaporated water, then in the proposed installation the consumption of electricity consumed for evaporation is about 250 kJ / kg

 evaporated water, i.e. b times less.

In addition, the installation completely lacks the entrainment of the evaporated substances, since the gas coolant in contact with the evaporated solution circulates around the closed loop and is not emitted into the atmosphere.

Claims (1)

Invention Formula An evaporation unit containing a regenerative solution heater, a vapor-gas mixture cooler and a contact gas-liquid heat exchanger with an additional heater, connected in series along the vapor-gas mixture, inlet and outlet pipes of the vaporized solution and the vapor-gas mixture of the heater and heat exchanger, which in order to increase the efficiency of the evaporation process and prevent the evaporation of evaporated substances into the atmosphere, the outlet of the gas vapor mixture of contact azozhidkostnogo heat exchanger is connected to the inlet regenerative preheater solution to form a closed loop vapor-gas mixture, and the installation is provided with 5 by a gas blower installed in a closed loop of the gas-vapor mixture, and a heat pump, the cooling heat exchange surface of which is located in the vapor-gas mixture cooler, and the heating heat exchange surface in an additional heater of the contact gas-liquid heat exchanger. Subbod heat C5 condensate