RU2354429C1 - Film evaporating apparatus with climbing film - Google Patents

Abstract

FIELD: instrument making.

SUBSTANCE: invention is related to apparatuses for concentration of solutions, preparation of desalinated water and may find application in chemical, microbiological and other fields of industry, and also for performance of laboratory and research works. Apparatus comprises vertical cylindrical body equipped with heating chamber and chambers for introduction of suspension and discharge of concentrated solution, condensate of secondary steam. Chamber for discharge of secondary steam condensate is equipped with nozzle for introduction of compressed gas, and drain nozzles equipped with hydraulic lock are tightly installed on lower ends of nozzles for drain of secondary steam condensate placed along length of cylindrical pipes with gap relative to each other. In upper part of nozzles for condensate drain on their side surface there are devices that provide for rotary reciprocal motion of steam (gas)-liquid mixture, and nozzle for gas discharge is located on apparatus cover.

EFFECT: all specified above makes it possible to organise climbing film flow not with secondary flow of steam but with flow of gas introduced in chamber for condensate drain, and therefore it makes it possible to provide for film flow along the whole length of cylindrical pipes, which increases heat transfer and accordingly, apparatus efficiency by evaporated moisture.

3 dwg

Description

The invention relates to the construction of evaporators with an ascending film, intended for the concentration and cooling of solutions, obtaining desalinated water. It can find application in the chemical, microbiological, food and other industries.

Known evaporation apparatus, including a heating tube chamber, a separation device with a liquid chipper, a receiving chamber, a circulation pipe, pipelines and fittings for inputting the output of the solution and steam, equipped with a pressure section with additional fittings, one of which is connected to the solution input pipe, and the other with a circulation pipe, while the pressure section is located in the upper part of the heating chamber, and channels are made in the pipes of the heating chamber by which the chamber cavity is in communication with the pipe cavity [1].

However, this device has a high hydraulic resistance, low evaporation rate and high usable temperature difference.

The high hydraulic resistance of the apparatus is due to the high axial velocity of the secondary steam in the pipes. The low productivity of evaporated moisture is due to the fact that 1/3 of the length of the pipes is filled with a solution, where the heat transfer is an order of magnitude lower than in the film, which leads to a low productivity of evaporated moisture. High speeds of the secondary vapor in the pipes also lead to the breakdown of solution droplets from the film surface, which requires a decrease in the productivity of the apparatus. In addition, the resistance of the apparatus increases and, consequently, the value of the useful temperature difference is up to (10-17) ° C, and this is energy-intensive. The useful temperature difference is the difference between the average temperature of the heating steam and the boiling point of the solution.

The closest in technical essence is a film evaporation apparatus, consisting of a vertical casing, divided by horizontal partitions into chambers for introducing a suspension and withdrawing a concentrated solution, a heating chamber, chambers for introducing and discharging refrigerant and discharging secondary steam condensate. The device is equipped with fittings and cylindrical pipes, inside of which an annular spiral is installed. On the axis of the cylindrical pipes, the inner pipes are coaxially placed along the entire length of the apparatus, and an additional horizontal partition is placed in the chamber for condensate discharge of the secondary steam above the lower partition, equipped with nozzles installed in the holes with a gap relative to the cylindrical and inner pipes [2].

However, this apparatus, despite the achievement of high liquid loads, does not have a high enough productivity for the secondary pair due to the relatively low values of heat transfer coefficients in the film of the solution. In the apparatus under consideration, gravitational runoff is realized, and it is well known that with ascending forward flow the heat transfer is an order of magnitude higher than with gravitational runoff of liquid. For example, with a Reynolds film 5000, the heat transfer coefficient in a liquid does not exceed 8000 W / m ² · K, and with an upward one, depending on the speed of the secondary steam, it reaches 30,000 W / m ² · K and more due to high tangential stresses on the interface.

The invention solves the problem of increasing the productivity of the apparatus by evaporated moisture, reducing the usable temperature difference.

The technical result consists in the fact that in the proposed apparatus an upward flow is implemented, not with secondary steam, as is done in an apparatus taken as an analog, but by introducing a stream of compressed (compressed) into the lower part of the apparatus (into the chamber for condensate output of secondary steam) gas, which allows the process to be carried out at high values of the heat transfer coefficient and low useful temperature difference, while it is not necessary to achieve a large temperature difference to ensure the flow of secondary steam and the implementation of the upward movement Niya liquid film.

The specified technical result is achieved in that in an evaporating film apparatus with an ascending film, consisting of a vertical cylindrical body with a lid and a bottom, equipped with technological fittings, a heating chamber and cameras for introducing a suspension and output of concentrated solution, secondary steam condensate, pipelines for input and output refrigerant, cylindrical and internal pipes, pipes for condensate drainage of secondary steam installed in the lower part of the device with the formation of a gap relative to the top spacing of cylindrical and inner pipes, according to the invention, the secondary steam condensate outlet chamber is provided with a fitting for injecting compressed gas, and drain pipes equipped with a water seal are hermetically installed on the lower ends of the secondary steam condensate outlets arranged along the length of the cylindrical pipes with a gap relative to each other moreover, in the upper part of the nozzles for condensate drainage on their lateral surface there are devices providing rotational-translational movement of vapor (gas) liquid the rest of the mixture, and on the lid of the apparatus there is a fitting for gas outlet.

Installation in the chamber for condensate discharge of a secondary steam nozzle for injecting compressed gas, the presence on the lower ends of the nozzles for condensate discharge of secondary steam, placed with a gap along the length of the cylindrical pipes, drain pipes with a water seal, as well as the placement of condensate drain pipes on top of them the side surface of the devices for providing rotational-translational movement of the vapor (gas)-liquid mixture and the execution on the lid of the apparatus of the nozzle for gas outlet allows you to organize an ascending full-time flow not with a secondary steam stream, but with a gas stream introduced into the condensate discharge chamber, and thereby allows for a film flow along the entire length of cylindrical pipes (as is known in evaporators with an upward film (analog), 1/3 of the height of the heating chamber pipes is filled solution), which increases the heat transfer, and consequently, the productivity of the device for evaporated moisture. In addition, the gas flow entering the lower ends of the cylindrical pipes is capable of transporting large amounts of liquid in the film, which also leads to an increase in the apparatus’s capacity for evaporated moisture. In this case, there is no need to create a stream of secondary steam for transporting the solution in the form of a film up the inner surface of cylindrical pipes (the solution is transported by a gas stream), and therefore, there is no need to provide a high useful temperature difference (10-17) ° С, it is enough to have (0, 5-3) ° C. The gas flow is capable of raising large flow rates of the solution in the form of a film, while providing a film thickness of 2-10 mm, which allows the large flow rates of secondary steam to evaporate from the liquid, which immediately condenses in the evaporation zone on the surface of the inner pipes, without creating axial velocity, and therefore , and increase hydraulic resistance, boiling point.

The presence at the lower ends of the nozzles for condensate drainage of secondary steam, placed with a gap along the length of the cylindrical pipes, drain pipes with a water seal, and in the upper part of the nozzles for condensate drainage on their side surface of the devices to provide rotational-translational movement of the vapor (gas)-liquid mixture provides, due to centrifugal force, the separation of droplets of solution from the secondary steam, which moves to the surface of the inner pipes, which allows working at high productivity on the secondary pair and pre deterred from entering the solution into the vapor condensate.

The placement of the nozzles for the removal of condensate of the secondary steam with a gap along the length of the cylindrical pipes allows you to provide the required flow rate of the secondary steam to create intensive rotation during passage between the plates and thereby allows you to effectively remove drops from the stream.

The presence at the lower ends of the nozzles for condensate drainage of a secondary pair of drain nozzles with a water seal provides a steady drainage of the condensate of the second pair along the turns of the inner pipes. Otherwise, such an apparatus is not operable due to the inevitable breakdown of the condensate film from the surface of the coils of the inner pipes by secondary steam and compressed gas rising upward, i.e. countercurrent.

Placing in the upper part of the nozzles for condensate drainage on their lateral surface of the devices, to create a rotational-translational motion of a vapor (gas)-liquid mixture, it is possible to provide centrifugal force, which, acting on solution droplets in a pair, throws them into the solution film, thereby preventing droplets falling into the condensate of the secondary steam, which increases the productivity of the apparatus by evaporated moisture, since it is possible to carry out the evaporation process at high steam load.

Figure 1 shows a film evaporator with an ascending film; figure 2 - cylindrical and inner pipe with a pipe for condensate drainage and a device for creating rotational-translational motion of a vapor (gas)-liquid mixture; figure 3 is a section of a cylindrical pipe along section AA.

The evaporator with an ascending film consists of a vertical cylindrical body 1 with a cover 2 and a bottom 3. The device is equipped with fittings for the input and output of solution 4 and 5, the output of the condensate of the secondary steam 6, the inlet and outlet of the coolant 7 and 8, the inlet and outlet of the refrigerant 9 and 10, inlet and outlet of compressed gas 11 and 12, auxiliary fittings 13. The film apparatus also has chambers for introducing a suspension 14 and discharging a concentrated solution and exhaust gas 15, a heating chamber 16, a chamber for discharging the condensate of the secondary steam 17. In The apparatus’s mustache has cylindrical pipes 18 and coaxially mounted inner pipes 19 made in the form of a coil of coils 20. In the annular cavities formed by the cylindrical 18 and inner 19 pipes, pipes are installed along their length to drain the condensate of the secondary steam 21. At the lower ends of these pipes located along the length of the cylindrical pipes with a gap relative to each other, drain pipes 22 are fitted with a water seal 23. Moreover, in the upper part of the pipes to drain the condensate of the secondary steam 21 to their devices for creating a rotational-translational motion of a vapor (gas)-liquid mixture, made in the form of inclined plates 24 mounted at an angle to the axis of the nozzle. In the lower ends of the cylindrical pipes 18, coaxially with a gap, liquid distributors are installed, made in the form of cylindrical sleeves 25, to form a solution film.

The evaporator with a falling film works as follows. Compressed gas through the nozzle 11 enters the chamber 17. At the same time, the solution through the nozzle 4 enters the chamber 14, where it is distributed on the lower horizontal partition of the chamber 14, and then flows into the annular gaps formed by the inner surface of the cylindrical pipe 18 and the outer surface of the sleeve 25. The gas transports a solution in the form of a film on the inner surface of cylindrical pipes. This allows the process to be carried out at high values of the heat transfer coefficient and a relatively low usable temperature difference. The solution, mixing vigorously, is heated through the wall of cylindrical pipes with a coolant entering through the nozzle 7 into the heating chamber 16, as a result of which it boils. A stream of secondary steam and droplets of solution are formed, torn from the surface of the film. The vapor-liquid mixture enters the annular gaps formed by the inner surface of the cylindrical pipes 18 and the outer surface of the nozzles 21, passes through the inclined plates 24, acquires rotational translational motion. As a result, a centrifugal force arises which casts droplets of the solution onto the film surface. The film at the outlet of the cylindrical pipes rises into the chamber of the concentrated solution 15 and is discharged through the nozzle 5. The secondary vapor released from the droplets condenses on the surface of the inner pipes 19, into the cavity of which cooling water is supplied through the nozzle 9. The cooling water is discharged through the nozzle 10. Condensate formed through the turns 20 of the inner pipes 19 flows into the cavity of the nozzles 21 and then through the drain pipes 22 is removed through the nozzle 6. The condensate located in the valve 23 prevents the penetration of gas into the floor the drain pipe 22 and thereby provides a continuous drain of condensate.

The use of the inventive film evaporator with an ascending film can increase the productivity of the apparatus and reduce the usable temperature difference, which reduces capital and operating costs, and therefore the cost of the product.

Information sources

1. USSR author's certificate No. 1579515, M.cl. B01D 1/22.

2. USSR author's certificate No. 1745278, M.cl. B01D 1/22, 1992, BI No. 5.

Claims (1)

A film evaporator with an ascending film, consisting of a vertical cylindrical body with a lid and a bottom, equipped with technological fittings, a heating chamber and chambers for introducing a suspension and withdrawing a concentrated solution, secondary steam condensate, pipelines for introducing and discharging refrigerant, cylindrical and inner pipes, pipes for draining the condensate of the secondary steam, with the formation of a gap relative to the surface of the cylindrical and inner pipes, characterized in that the chamber for removing condensate is second egg steam is equipped with a fitting for injecting compressed gas, and drain pipes equipped with a water seal are hermetically installed on the lower ends of the secondary steam condensate pipes located along the length of cylindrical pipes with a gap relative to each other, and in the upper part of the pipes for condensate drain on their side devices that provide rotational-translational motion of a vapor (gas)-liquid mixture are placed on the surface, and a nozzle for discharging gas is made on the lid of the apparatus.

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