EA019810B1 - Heat exchange apparatus - Google Patents

Abstract

The invention relates to heat exchange apparatuses, in which mass exchange processes can be simultaneously performed, for example, absorption, condensation and can be used in thermal engineering, chemical and other branches of industry, for example in the production of carbamide. The technical result is an increase in the operating efficiency of a heat exchanger. A heat exchange apparatus is proposed which contains at least one inner heat exchange pipe with turbulence promoter, turbulence promoter is arranged near inlet hole of heat exchange pipe and represents a cylindrical vessel with holes for inlet and outlet of fluids, inside of which along with the fluid motion there are serially arranged jet-forming nozzle and resonator plate fixed as overhanging in cylindrical vessel with two projections, which are bowingly bent in opposite directions so that they tightly adjoin inner surface of cylindrical vessel, forming fixation of plate. Heat exchanger may comprises chamber of fluids introduction, which may be equipped with mixing and/or distributing devices. Cylindrical vessel of turbulence promoter may be represented by the section of heat exchange pipe, and additional holes may be arranged in wall of cylindrical vessel of turbulence promoter between inlet hole and jet-forming nozzle.

Description

Technical field

The invention relates to heat exchangers, in which mass transfer processes, for example absorption, condensation, can also be carried out.

State of the art

A heat exchanger is known, which includes an external casing and internal heat transfer tubes, containing swirls and inclined blades inside each heat exchanger tube with discrete turbulators in the form of ring wire rods placed on the ends of the blades and tightly adjacent to the inner wall of the pipe (KI 2150644, Ρ28Ό 7/00, P28P 1/40).

A heat exchanger is known, including an external casing and internal heat transfer tubes, containing turbulators inside each heat transfer tube, which are local resistances in the form of annular diaphragms (KI 2039922, P28E 7/00, P28P 1/40).

Closest to the proposed one is a well-known heat exchanger, including an external casing and internal heat transfer tubes containing inside each heat exchanger tube turbulators in the form of a spiral (KI 2238499, Ρ28Ό 7/00, Р28Р 1/42).

The disadvantages of this device include the difficulty in installing the turbulator.

Disclosure of invention

The problem solved by the invention is to improve the design of the heat exchanger and expand the range of heat exchangers equipped with flow turbulators.

The technical result of the invention is to increase the efficiency of the heat exchanger.

To solve this problem, a heat exchanger is proposed, including an external casing and at least one internal heat exchanger pipe with a turbulator, characterized in that the turbulator is located near the inlet of the heat exchanger pipe and is a cylindrical body with openings for the inlet and outlet of media, inside of which the motion of the medium is sequentially located jet-forming nozzle and cantilever mounted in a cylindrical body towards the movement of the medium plate resonator with two high upami arcuately curved in opposite directions so that they closely adjoin the inner surface of the cylindrical body, forming a fixing plate.

The heat exchanger may include a media input chamber, which may be equipped with mixing and / or distribution devices. A portion of the heat exchanger tube may serve as the cylindrical housing of the turbulator, and additional holes may be contained in the wall of the cylindrical housing of the turbulator between the inlet and the jet forming nozzle.

The proposed invention has a universal character and can be implemented in a wide variety of types of tube heat exchangers, which are selected from the standard range depending on the nature and conditions of the processes. The heat exchanger can be shell-and-tube (vertical or horizontal), pipes can be straight or shaped. By design, the heat exchanger may be a condenser, evaporator, refrigerator, etc. The invention can also be used in pipe-in-pipe heat exchangers, as well as in heat exchangers representing various combinations of the above structures (for example, sectional).

The technical result obtained consists in increasing the turbulization of the flow of a liquid or multiphase-containing liquid phase medium, increasing the mixing efficiency of the phases, which leads to an increase in the heat and mass transfer coefficients and, ultimately, to a reduction in the metal consumption, overall dimensions of the apparatus and the cost of the installation as a whole.

Brief Description of the Drawings

The invention is illustrated by the attached FIG. 1-9.

In FIG. 1 is a longitudinal sectional view of a vertical condensation heat exchanger in which gas and liquid media interact, FIG. 2 - in longitudinal section, part of the heat exchanger pipe with turbulator included in this heat exchanger; in FIG. 3 is a longitudinal sectional view of a turbulator; FIG. 4 is a longitudinal section through the turbulator shown in FIG. 3 along line AA, in FIG. 5 is a cross-sectional view of the turbulator shown in FIG. 4, along line BB; in FIG. 6 is a longitudinal sectional view of a vertical heat exchanger with C-shaped heat exchange tubes; FIG. 7 is a longitudinal section of a portion of a heat exchanger pipe with a turbulator included in the composition of this heat exchanger; in FIG. 8 is a longitudinal section through a horizontal heat exchanger; FIG. 9 is a longitudinal section of a portion of a heat exchanger tube with a turbulator included in the composition of this heat exchanger.

Embodiments of the invention

In accordance with FIG. 1 condensing heat exchanger consists of a vertical casing 1, a medium inlet chamber 2 with liquid inlet 3 and gaseous 4 reagents, a medium inlet chamber 5 with liquid inlet 6 and gaseous outlet 7 reaction products, inlet branch pipes 8 and coolant outlet 9, distribution device 10 heat transfer pipes 11 fixed in the pipe

- 1 019810 gratings 12, and turbulators 13 connected to heat transfer tubes 11 and located in the medium inlet chamber 2.

In accordance with FIG. 2-5, a turbulator 13 is located at the inlet of each heat transfer pipe 11. The turbulator includes a cylindrical body 14, inside which a jet forming nozzle 15 and a cantilever resonator plate 16 are installed, the free end of which is directed towards the jet forming nozzle 15. In the wall of the cylindrical body 14 between the inlet holes 18 are located in the hole of the turbulizer 17 and the jet forming nozzle 18. The resonator plate 16 is made of a flat T-shaped workpiece by arched bending in opposite directions Ov 19 plates, forming the crossbar of the letter T. These protrusions are bent so that in plan this part of the plate forms a contour that fits into the circumference of the cross section of the cylindrical body 14. Moreover, the diameter of the contour in the free state should slightly exceed the inner diameter of the cylindrical body 14 so so that the plate 16 can be inserted into the pipe, after compressing the bent protrusions 19. The plate 16 inserted into the cylindrical body 14 is held therein due to the elasticity of the protrusions compressed during insertion 19. The turbulator body is connected to the pipe by a thread; it is possible to connect these parts with other known methods (welding, pressing, using support grids, etc.).

During the operation of the heat exchanger, the flow of liquid medium enters the cylindrical body 14 of the turbulator through the inlet 17, and a gaseous medium accumulates through the openings 18 and accumulates in the upper part of the medium inlet chamber 2, then these flows pass together through the jet forming nozzle 15, which is made using a slotted hole forms a stream of fluid and directs it to the resonator plate 16 and further to the heat exchange tubes 11. The medium flow excites vibrations of the resonator plate 16, contributing to the growth of turbulization flow, mixing the medium and dispersing the phases of the multiphase flow.

When this heat exchanger is in operation, the gas-liquid flow enters the pipes 11 in the vertical direction from the bottom up.

In accordance with FIG. 6, the vertical heat exchanger consists of a vertical casing 1, a medium inlet chamber 20 and a medium outlet chamber 21 separated by a partition 22, equipped with an inlet port 23 and an outlet port 24 for the heat transfer fluid, inlet ports 8 and the outlet 9 of the heat transfer medium, I-shaped heat transfer tubes 25 fixed in the tube sheet 12, and turbulators 13.

Depicted in FIG. 7, a portion of the heat exchange pipe 25 included in the structure of FIG. 6 of the heat exchanger, differs from the heat exchange tube 11 shown in FIG. 2, oriented in space and rotated relative to it by 180 °, the turbulator 13 located at the inlet of the heat exchange pipe 25 does not have holes 18, and the cylindrical body 14 of the turbulator 13 is a portion of the heat transfer pipe 25.

The operation of this heat exchanger is carried out similarly to the above, with the difference that the input of the liquid flow into the pipes 25 is through the turbulator 13 in the vertical direction from top to bottom.

In accordance with FIG. 8, the heat exchanger consists of a horizontal casing 1, a medium inlet chamber 2 with a liquid coolant inlet 3 inlet, a medium 5 inlet chamber with liquid coolant inlet 6 outlets, inlet 8 outlets and a coolant outlet 9, heat exchange tubes 11 fixed to the tube sheets 12.

Depicted in FIG. 9, a portion of the heat exchange tube 11 included in the structure of FIG. 8 of the heat exchanger, differs from the heat exchange tube 11 shown in FIG. 2, only by orientation in space and rotated relative to it by 90 °, and the turbulator 13, which is fixed at the entrance to the heat exchange pipe 11, has no holes 18.

The operation of this heat exchanger is carried out similarly to the previous one with the difference that the input of the liquid flow into the pipes 11 is carried out through the turbulator 13 in the horizontal direction.

Industrial applicability

The invention can be used in energy, chemical and other industries, for example in the production of urea.

Claims (5)

1. A heat exchanger comprising an outer casing and at least one internal heat exchanger pipe with a turbulator, characterized in that the turbulator is located near the inlet of the heat exchanger pipe and is a cylindrical body with end openings for the inlet and outlet of media, inside of which the medium is moving the jet-forming nozzle and the cantilever plate with two protrusions curved arcuately bent into opposite sides so that they are adjacent to the inner surface of the cylindrical body, about - 2 019810 fanning the mounting plate. 2. The heat exchanger according to claim 1, characterized in that the cylindrical body of the turbulator is a portion of the heat exchanger pipe. 3. The heat exchanger according to claim 1 or 2, characterized in that it comprises a media input chamber. 4. The heat exchanger according to claim 3, characterized in that there are additional holes in the wall of the cylindrical body of the turbulator between the inlet and the jet forming nozzle. 5. The heat exchanger according to claim 3, characterized in that the medium inlet chamber comprises a mixing and / or distribution device.