SU1699481A1 - Film-type heat-and-mass transfer apparatus - Google Patents

Abstract

The invention relates to film-type apparatuses for conducting heat and mass exchange processes and can be used in the chemical petrochemical, food and other industries, in particular for carrying out absorption and desorption processes. The purpose of the invention is to increase the efficiency of mass transfer. Heat and mass transfer apparatus of film type, containing a vertical upper and lower chambers, upper and lower tube sheets with heat exchanger tubes fixed in them so that the ends of the tubes protrude above the upper tube grid, as well as heat and discharge nozzles connected to the body, inlets and outlets liquids made in chambers from opposite ends of the apparatus, and gas inlet and outlet connections. The device has partitions installed in the upper and lower chambers, and in the upper chamber the partitions are made deaf to the wall of the chamber and with a gap to the upper tube sheet, and in the lower chamber the partitions are made deaf to the tube end of the partitions, and fittings gas inlet and outlet are made in the upper chamber at one end of the apparatus. 1 il. 9 (L & so & 30 30

Description

The invention relates to film-type apparatuses for conducting heat and mass transfer processes and can be used in the chemical, petrochemical, food and other fields, in particular, for carrying out absorption and desorption processes.

A heat and mass transfer apparatus of the film type is known, which contains

vertical housing, upper and lower chambers, upper and lower tube sheets with heat exchange tubes fixed in them. Connections to the outlet and the supply of coolant are connected to the body. The nozzle inlet and outlet for liquid are made from opposite ends of the apparatus: the inlet nozzle is in the upper chamber and the nozzle outlet for the fluid in the lower chamber. At the bottom

The chamber also has a gas phase outlet. In the apparatus, the liquid and gas move from top to bottom, i.e. mode pr motorcycle Q / Q.

A disadvantage of the known construction is the low efficiency of the apparatus operating in the gas and liquid flow mode. The efficiency of mass transfer is characterized by the magnitude of the extraction coefficient; and it is known 2 that, other things being equal, lower recovery rates are achieved with a direct flow than with a counter current.

Known gas lift absorber containing a vertical body, upper and lower chambers, upper and lower tube sheets with tubes fixed in them. Connections to the outlet and the supply of coolant are connected to the body. The fluid is supplied to the upper chamber by means of nozzles, and is withdrawn from the lower chamber through the liquid outlet nozzles. In the lower chamber, gas phase inlets and blind to the wall of the chamber and to the lower tube sheet are made of vertical partitions. The tubes of the apparatus are mainly dominated by the continuous flow of fluid and gas in the emulsion (gas-lift) mode.

However, the known structure has low efficiency when working with a gas and liquid flow. The closest to the claimed is a film-type heat and mass transfer apparatus consisting of a vertical body, an upper and lower chamber, an upper and lower tube sheet with heat-exchange tubes fixed in them, with the ends of the tubes protruding above the upper tube grid. Connections to the outlet and the supply of coolant are connected to the body. The nozzles of the inlet and outlet of the fluid are made from opposite ends of the apparatus: the inlet nozzle is in the upper chamber, and the nozzle outlet of the fluid is in the lower chamber. The gas inlet and outlet nozzles are also made from opposite ends of the apparatus: the inlet nozzle is in the lower chamber, and the gas outlet nozzle is in the upper chamber.

The apparatus operates as follows. The working fluid enters the upper chamber through the fluid inlet, where it is distributed through the upper tube sheet and is poured over the top.

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the ends of the heat-exchange tubes blunt above the grille with the formation of a film on the inner surface of the heat-exchange tubes. Gas is supplied to the apparatus in the lower chamber through the gas inlet fitting. It is further distributed through pipes and moves upwards. Thus, in a known apparatus, a liquid and gas contact occurs in countercurrent mode. The exit of gas and liquid is carried out by the fittings of the exit of liquid and gas. In the annular space of the apparatus, the coolant moves to carry out the process of heat exchange of the ED.

The disadvantages of the heat and mass transfer apparatus of the film type include the slight efficiency of mass transfer due to a single contact of gas and liquid.

The aim of the invention is to increase the efficiency of mass transfer due to multiple direct flow-countercurrent contacting of gas and liquid.

The goal is achieved by the fact that a film-type heat and mass exchange apparatus comprising a vertical body, upper and lower chambers, upper and lower tube sheets with heat-exchange tubes fixed in them so that the ends of the tubes protrude above the upper tube sheet and also connected to the body of the branch fitting and supplying the heat carrier, the liquid inlet and outlet connections to the chambers from opposite ends of the apparatus, and the gas inlet and outlet connections 1meet the bulkheads installed in the upper and lower chamber, and in ver The chamber walls are made deaf to the chamber wall and with a gap to the upper tube sheet, and in the lower chamber are deaf to the tube grid and with a gap to the chamber wall, 0 the ends of the tubes above the upper tube sheet are installed above the end of the partitions, and the gas inlet and outlet nozzles made to the upper chamber from one end of the apparatus.

The drawing shows the device of the heat and mass transfer apparatus film type, General view.

A film-type heat and mass transfer apparatus contains a vertical body 1, an upper 2 and lower 3 chambers, an upper 4 and lower 5 pipe grids with heat exchanging pipes 6 fixed in them so that the ends of the pipes protrude above the upper trumpet grid The outlet fittings 7 and inlet 8 are connected to the device body heat carrier, nozzle inlet 9 and liquid outlet 10 are made to chambers 2 and 3 at opposite ends of the apparatus, and fittings for input 11 and gas outlet 12 are from one end of the device to chamber 2. In the upper chamber 2, partitions 13 are installed so that to the wall amers 2 are deaf, and the upper tubesheet k formed with a gap. In the lower chamber 3 a partition is installed And so,

Thieves in chambers 2 and 3 need the DP to ensure multiple flow of the countercurrent contact of gas with liquid. To remove heat absorbed in the space between case 1 and pipes 6, heat carrier 8 is supplied to ceru 8, which is removed from the apparatus along row 7. In chambers 2 and 3, more partitions can be installed (Fig. 1). This will lead to an increase in the number of direct and countercurrent contacts of gas and liquid. FIG.

that with respect to the lower pipe re- 15 while 3 there are four stages of contact

(2-wire and 2-flow). For example, with three partitions in chamber 2 and

in bar 5 it is deaf, and in relation to the wall of the chamber there is a 3rd gap. The ends of the pipes 6 are made above the end of the partition 13.

The device works as follows.

Fluid is introduced into the apparatus through the fluid inlet 9. It is then distributed over the entire upper tube sheet k with the aid of gaps between the barriers 13 and the tube grid 4. The liquid flows into the heat exchange tubes 6 starts at the moment when the liquid rises to the upper end of the tubes 6 protruding above the tube grid 4. In this way, the partitions 13 are partially immersed in the liquid, which ensures the formation of a water seal in the upper chamber 2 and prevents the passage of gas from the fitting 11 to the fitting 12 directly. The gas enters the apparatus in the upper chamber 2 through the gas inlet 11 and further along pipes 6 into chamber 3. The first contact of the gas with the liquid in the pipes takes place. in the pr-motok mode (fig. 1), hereinafter, the counter-current mode (from the chamber 3 s 2), then the strand (from the chamber 2 in 3), etc. Fluid through all pipes 6 flows from top to bottom in the form of a film. C, pipe 6, the liquid flows from the lower chamber 3 to the output of the apparatus through the unit 10 of the liquid outlet, the withdrawal of gas from the apparatus is carried out through the fitting 12. The fitting of the inlet 11 and the outlet of the gas 12 are made to the upper chamber 2 from one end of the apparatus. In the lower chamber 3, the partition wall is made with a gap relative to the cell line and is immersed in a liquid, which provides for the formation of an idler valve, as well as the distribution of the liquid over Camer 3.

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2 and two partitions in chambers re 3 in the apparatus has contact steps (3 straight and 3 against the exact ones). Therefore, the efficiency of the device is significantly aged compared with the known device

Thus, this embodiment of a foam-type heat and mass exchange apparatus makes it possible to increase the efficiency of mass transfer due to the multiple direct-flow contact of gas and liquid.

Claims (1)

Invention Formula The heat and mass transfer apparatus is of the foam type, containing a fan-shaped case, the upper v is the bottom of the g-frame, the sweater and the lower trusny, 1 with the fixed 1 p-tubes in them, so that they come out above the upper at Rio as well as the connected hub and the connection of the input and output connections to the chambers with nyl of the ends of the apparatus, and output with 5 eat m c, g, ususus-, -f, youthfuli.-chostp, WOULD be the opposite of the nozzle inlet and inlet, in order to increase the efficiency of the laser exchange due to the multiplicity of its own -contracted contacting of gas and zhitsksschi, {the upper and lower chambers are equipped with partitions installed in them, while in the upper chamber the partitions are made deaf to the wall of chambers and with a gap to the upper tube sieve 1ke, and the lower chamber of the partition | pipe connection and with Zoor to the wall of the chamber, ends of rub upper tube thieves in chambers 2 and 3 need dp to ensure multiple direct flow-countercurrent contact of gas with liquid. To remove heat absorbed in the space between the housing 1 and the pipes 6, heat transfer medium is fed through fitting 8, which is removed from the apparatus through fitting 7. More chambers can be installed in chambers 2 and 3 (Fig. 1). This will lead to an increase in the number of flow and countercurrent contacts of gas and liquid. Figure 1 while three stages of contact (2-wire and 2-flow). For example, with three partitions in chamber 2 and 0 five 0 five 0 five 0 five 2 and two partitions in the chamber 3 in the apparatus have contact stages (3 continuous and 3 counterflow). Therefore, the efficiency of the apparatus will increase significantly compared with the known apparatus. Thus, this embodiment of the film-type heat and mass transfer apparatus makes it possible to increase the efficiency of mass transfer due to repeated direct-flow counter-contacting of a gas and a liquid. Invention Formula The heat and mass transfer apparatus of the film type contains a fan-shaped case, an upper v-knob g-meter, an upper and lower trusnyr, 1 ltk with 1 p-tubes fixed in them so that they are squeezed over the upper tg at Rio a also connected a digital input and output connectors to the chambers with nyl of the ends of the apparatus, and output with 5 eat m c, g g usus-, -f, yunositel, zi-chostp, WY- opposite to the nipple of the inlet and w ith and i-o, in order to increase the efficiency of Las exchange due to the multiplicity of its own | - countercurrent contact of gas and zhitsksschi, {upper and lower chambers are equipped with partitions installed in them, while in the upper chamber the partitions are made deaf to the chamber wall and with a gap to the upper tube plate and the lower chamber of the partition | deafening the pipe bindings and with the Soil to the wall of the chamber, the ends rub the upper tube with its grate installed above the end of the partitions, the yen to the upper chamber at one end of the nozzle of the input and output gas of the gas pipeline. // - - gas - liquid / 3 j / 2