RU168223U1 - HEAT EXCHANGER - Google Patents

Abstract

The utility model relates to the energy industry and can be used in heat exchangers, in particular in refrigeration and cryogenic plants. The heat exchanger includes covers (1) and tube sheets (2), each of the covers (1) with one of the tube sheets (2) forming two insulated volumes (3) and (4). The volume (3) is connected to the inlet pipe of the cooled medium (5), and the volume (4) is connected to the pipe (6) for the cooled medium. Both isolated volumes (3) and (4) are connected to the tube bundle (7). The heat exchange tubes (8) forming the tube bundle (7) are fixed and sealed in the tube sheets (2) and two isolated volumes (3) and (4) communicate with each other. In the central pipe (9), a coaxial pipe for introducing a cooled medium (5), radial channels (10) are made, communicating the isolated volumes (11) and (12) with each other. The insulated volume 11 is formed by a central pipe (9), a casing (13) and tube sheets (2). The insulated volume 12 is formed by a central pipe (9), an inlet pipe of a cooled medium (5), one of the pipe sheets (2) and a partition (14). The insulated volume (11) is connected to the pipe (15) for supplying a cooling medium, and the insulated volume (12) is connected to a pipe (16) to remove the cooling medium. The layers of pipes (17) of tube bundles (7) are wound in such a way that between the casing (13) and the adjacent layer of pipes (17), as well as between the adjacent layers of pipes (17) and between the central pipe (9) and the adjacent layer of pipes (17 ) there are radial gaps containing spirally curled wire (18). Radial clearances and spirally curled wire (18) form spiral annular channels (19). The technical solution allows to improve manufacturability and maintainability, as well as ease of operation of the heat exchanger. 4 ill.

Description

The utility model is intended for use in heat exchangers and can be used in the energy industry, in particular in refrigeration and cryogenic plants.

A known design of a coil heat exchanger [US Pat. 2402732 RF, MKI6 F28D 7/00, F 28F 9/013, publ. October 27, 2010], which has a plurality of pipes helically wound in one or more concentric layers around a central pipe forming a bundle of pipes, and a casing restricting the external space around the pipes, and also contains at least one heat transfer elastic element located inside the heat exchanger casing, radially outside the tube bundle.

The design disadvantages are large weight and size characteristics and relatively low heat transfer intensity, due to the implementation of a relatively less efficient flow pattern of cooling and cooled media (transverse current circuit), as well as due to the fact that the core surface is not used in the heat transfer process in this design.

The closest in technical essence and the achieved effect is the heat exchanger according to patent RU 159993, IPC F28D 7/00, publ. 02/27/2016), which has a plurality of pipes helically wound into one or more concentric layers around the central pipe, forming bundles of pipes, and a casing restricting the external space around the pipes, while the central pipe is divided by partitions into two volumes isolated from each other, each of which is connected with at least one branch pipe and with bundles of pipes, each of the plurality of pipes forming tube bundles communicating two isolated volumes of the central pipe with each other, and the pipes in all concentric layers are wound s with the same axial pitch so that spiral channels are formed between the turns of the tube bundles.

The disadvantages of the prototype are the complex manufacturing technology of the heat exchanger, due to the large number of welds for fastening spiral-wound tubes of the tube bundle in hard-to-reach places, as well as the output of the connecting pipes to both ends of the heat exchanger, which complicates the installation / disassembly and maintenance of the heat exchanger and requires a large free space around the installation, with the purpose of access to a separate heat-exchange element, which is impractical in cramped spaces, in particular for transport s facilities.

The technical result of this utility model is to increase the manufacturability, maintainability and ergonomics of servicing the heat exchanger by removing connecting pipes to the area of one end surface of the heat exchanger, as well as by reducing the number of places for welding and ensuring the availability of welding places.

The indicated technical result is achieved in that the heat exchanger, which has a plurality of heat exchange pipes helically wound into one or more concentric layers around a central pipe provided with an end wall, the spiral-wound heat exchange pipes forming bundles of pipes between which spiral annular channels are formed, contains also a casing limiting the external space around the pipes, and isolated volumes communicated with each other using pipes forming tube bundles, according to the claimed to the technical solution, the heat exchanger additionally contains two covers and two tube sheets, the heat exchange pipes forming tube bundles are fixed and sealed in the tube sheets, two insulated volumes of the heat exchanger are formed by each of the covers with one of the tube sheets, one of these insulated volumes is connected to the inlet pipe cooled medium, and the other with a nozzle for the cooled medium, and the pipe layers are wound in such a way that between the casing and the adjacent pipe layer, between adjacent pipe layers and between the central pipe and the adjacent layer of pipes has radial gaps containing spiral-wound wire, in the central pipe there are made radial channels communicating the insulated volume formed by the central pipe, the casing and the tube sheets, with a pipe for supplying the cooling medium, and the insulated volume formed by the central pipe, the cooled inlet pipe medium, a tube sheet and a partition, connected with a pipe to remove the cooling medium, and all the connecting pipes are located in the area of one end surface of the heat bmennika.

The essence of the utility model is illustrated by drawings, where:

in FIG. 1 is an end view of a heat exchanger;

in FIG. 2 shows a section through a heat exchanger according to BB in FIG. one;

in FIG. 3 is an enlarged view of A in FIG. 2;

in FIG. 4 shows a section through a heat exchanger according to BB in FIG. one.

The heat exchanger comprises the first cover 1 shown in FIG._oneand second cover 1₂, and also located on the side of the first cover 1_onethe first tube sheet 2 and located on the side of the second cover 1₂ the second tube sheet 2 (indicated by one position).

First cover 1_one with the first tube sheet 2 form an insulated volume 3, and the second cover 1₂  with the second tube sheet 2 form an insulated volume 4.

For the purposes of this utility model, the term "isolated" means "separate, separate, separated from the environment" and the nozzles are connecting nozzles.

The insulated volume 3 is connected to the inlet pipe of the cooled medium 5, and the insulated volume 4 is connected to the pipe 6 for the outlet of the cooled medium. Both insulated volumes 3 and 4 are connected to the tube bundle 7. The heat exchange tubes 8 forming the tube bundle 7 are fixed and sealed in the tube sheets 2 and communicate two insulated volumes 3 and 4 to each other.

In the central pipe 9, a coaxial inlet pipe of the cooled medium 5, from the side of the first tube sheet 2, radial channels 10 are made, communicating isolated volumes 11 and 12.

The insulated volume 11 is formed by a central pipe 9, a casing 13, a first tube sheet 2 and a second tube sheet 2 _.

The insulated volume 12 is formed by a central pipe 9, an inlet pipe of a cooled medium 5, a first pipe grid 2 and a partition 14.

The insulated volume 11 is connected to the nozzle 15 for supplying a cooling medium, and the insulated volume 12 is connected to the nozzle 16 to remove the cooling medium. The layers 17 of the pipes 8 of the tube bundles 7 are wound so that between the casing 13 and the adjacent layer of the pipes 17, as well as between the adjacent layers of the pipes 17 and between the central pipe 9 and the adjacent layer of pipes 17 there are radial clearances containing spirally curled wire 18, and the radial the gaps and spirally curled wire 18 form a spiral annular channels 19.

The inventive heat exchanger operates as follows.

Cooling medium, for example water, is pumped into the pipe 15, from which it enters the insulated volume 11 between the central pipe 9 and the casing 13, from which it is distributed and flows through the spiral annular channels 19, taking heat from the surfaces of the heat exchange pipes 8 of the tube bundle 7.

Then, the cooling medium, passing the annular spiral channels 19, through the radial channels 10 made in the central pipe 9, enters the insulated volume 12, flowing through which it cools the pipe 5 with a cooled medium, for example, with a refrigerant that moves countercurrent, then passing the insulated volume 12, the cooling medium is removed through the pipe 16.

In this case, the cooled medium, for example gaseous refrigerant, is fed into the pipe for supplying the cooled medium 5, passing through which it enters the insulated volume 3, from which it is distributed through the pipes 8 of the tube bundle 7. Moving in the tube 5 and inside the spirally curled tubes 8 of the tube bundle 7, the cooled medium gives off heat to the cooling medium. Then, having passed the tube bundle 7, the medium to be cooled is sent to an insulated volume 4, from which it is supplied to the nozzle 6. In the event that the medium to be cooled is gaseous refrigerant, a condensation process occurs during its movement through the cooled pipe channels and liquid is sent to volume 4 refrigerant phase.

The isolated volume 4 in this case serves as a collector of liquid refrigerant - receiver. The movement of the media is organized in such a way that each of them moves in a spiral, while the scheme of motion of the media is countercurrent.

Thus, this technical solution allows to improve manufacturability and maintainability, as well as ease of operation of the heat exchanger due to the output of the connecting pipes to the area of one end surface of the heat exchanger, as well as reducing the number of places for welding and the availability of welding places, due to the fastening and sealing of the heat exchanger tubes tube bundle, in tube sheets.

Claims (1)

The heat exchanger, which has a plurality of heat exchange tubes helically wound into one or more concentric layers around a central tube provided with an end wall, the spiral heat exchanging tubes forming bundles of tubes between which spiral tube sections are formed, also contains a casing restricting the external space around pipes, and insulated volumes, interconnected, characterized in that the heat exchanger additionally contains two covers and two tube sheets, heat exchange pipes, o forming tube bundles are fixed and sealed in tube sheets, two insulated volumes of the heat exchanger are formed by each of the covers with one of the tube sheets, one of these insulated volumes is connected to the inlet pipe of the medium to be cooled, and the other to the pipe of the medium to be cooled, and the pipe layers are wound so so that there are radial clearances between the casing and the adjacent pipe layer, between the adjacent pipe layers and between the central pipe and the adjacent pipe layer, containing spirally curled wire; radial channels are made in the central pipe, communicating the insulated volume formed by the central pipe, the casing and tube sheets with a nozzle for supplying a cooling medium, and the insulated volume formed by the central pipe, the cooling medium inlet pipe, tube sheet and baffle is in communication with the pipe for removing the cooling medium environment, and all connecting nozzles are located in the area of one end surface.

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