RU182526U1 - MULTI-WAY SHELL-TUBE HEAT EXCHANGER - Google Patents

Abstract

The technical solution relates to heat exchange equipment and can find application in the energy, gas, metallurgical, chemical, food and other industries.

The technical result is achieved in that in a multi-way shell-and-tube heat exchanger, consisting of a cylindrical body, interconnected by means of flanges with gaskets of the bottoms and distribution chambers with partitions for the formation of coolant passages through tubes fixed in two tube sheets welded to the body, forming a tube bundle , partitions in the annulus, the inlet and outlet pipes of both coolants and supports welded to the body, and the partitions in the annulus v tubes of the tube bundle coaxially with partitions mounted inside the distribution chambers, each of the partitions in the space between the tubes a slit has a transverse slot in the portion to which the adjacent baffle in the distribution chamber.

Description

The technical solution relates to heat exchange equipment and can find application in the energy, gas, metallurgical, chemical, food and other industries.

Known two-way shell-and-tube heat exchanger of a rigid structure with cross current through the annular space, consisting of a casing, tube sheets, tube bundle tubes with a cover having a longitudinal partition along the tube space, and transverse partitions along the annular space, as well as nozzles for the entrance and exit of coolants moving into cross current through the pipe and annular space (Machines and equipment for chemical production / edited by A.S. Timonin. - Kaluga: Noosphere, 2014, pp. 450-451).

The reasons that impede the achievement of the desired technical result include insufficient productivity due to the cross current created by the transverse baffles for the coolant moving in the annulus relative to the longitudinal motion of the second coolant moving in the tubes of the tube bundle, since the transverse motion of the coolants reduces the driving force of the process heat transfer.

Known multi-pass shell-and-tube film-type heat exchanger, consisting of a bundle of pipes, the ends of which are fixed in special tube sheets by flaring welding, soldering, and sometimes on glands. A bunch of pipes is located inside the casing, with one of the coolants moving through the pipes, and the other in the space between the pipes. The liquid coolant does not fill the entire cross section of the pipes, but flows down the film on the inner surface of the pipes.

The reasons that impede the achievement of a given technical result include either straight-through or countercurrent movement of the second coolant in the annulus relative to the first coolant moving in the tube bundle. This leads to a decrease in productivity due to a decrease in the useful temperature of the coolants (driving force) in the passages with their flowing motion [Planovsky AN, Ramm V.M., Kagan S.Z. - Processes and devices of chemical technology, 5th ed., Stereotype., 1986, p. 425].

Known shell-and-tube heat exchanger, in which in addition to the transverse partitions of the annular space in the chambers between them additionally placed longitudinal partitions with opposite twist angles [US Patent No. 395630, F28F 9/22, 1976]

The reasons that impede the achievement of the desired technical result is that with such a flow organization, part of the medium does not participate in the countercurrent flow around the tubes, but flows along them directly through the gaps in the openings of the intermediate partitions, which ultimately worsens the heat transfer.

The closest technical solution for the totality of features to the claimed object and adopted as a prototype is the design of multi-pass shell-and-tube heat exchangers (two, four, six and twelve-way), consisting of a cylindrical body (casing), in the middle part of which a lens compensator is welded, which serves to compensate for temperature expansion tubes. The casing has two bottoms, a distribution chamber, which are interconnected by means of flanges with gaskets, tube bundle tubes fixed in two tube sheets welded to the body. The distribution chamber, for example, of a two-pipe heat exchanger has a baffle, which serves to form two strokes through the tubes. Two fittings on the body serve to direct the second coolant into the annulus. To create a zag-like movement of the coolant in the annulus, partitions are connected by couplers. The apparatus is installed using supports welded to the body (Shapovalov Yu.N., Shein B.C. Machines and apparatuses of general chemical purpose. Textbook. Publishing House of Voronezh University. Voronezh, 1982, 108 pp.)

The reasons that impede the achievement of a given technical result include the cross movement of the coolant in the annulus relative to the axial movement of the coolant in each stroke of the tube bundle, which reduces the heat transfer performance from the hot coolant to the cold.

The technical result of the proposed design of a multi-pass shell-and-tube heat exchanger is an increase in productivity.

The technical result is achieved by the fact that in a multi-pass shell-and-tube heat exchanger, consisting of a cylindrical body interconnected by means of flanges with gaskets, bottoms and distribution chambers with partitions for the formation of coolant passages through tubes fixed in two tube sheets welded to the body, forming tube bundle, partitions in the annulus, the inlet and outlet nozzles of both coolants and supports welded to the body, and the partitions in the annulus are aligned along the tubes of the tube bundle coaxially with the partitions installed inside the distribution chambers, and each of the partitions in the annular space has a transverse slotted slot in the part adjacent to the partitions in the distribution chamber.

The installation of partitions in the annular space of the tube bundle, coaxially with the partitions installed inside the distribution chambers for the formation of coolant moves through the pipes, allows you to evenly distribute the coolant moving in the annular space, in proportion to the number of pipes in each passage of the coolant moving inside the pipes, which ensures a high heat transfer rate in each stroke of both heat carriers and promotes productivity growth.

The creation of a transverse slot in each baffle installed in the annular space along the tubes of the tube bundle in the area adjacent to the septum in the distribution chamber ensures countercurrent movement of both heat carriers for each stroke, i.e., when the direction of the coolant in the tubes of the tube bundle changes, it changes to the opposite direction of the coolant in the annulus, and the countercurrent movement of the coolants allows, as you know, to cool the hot coolant to lower t temperatures, and a cold heater to higher temperatures, which increases the average driving force of the heat transfer process and leads to increased productivity.

In FIG. 1 shows a diagram of a two-way shell-and-tube heat exchanger of the proposed design, FIG. 2 - three-way heat exchanger, in fig. 3 - four-way heat exchanger.

A multi-way shell-and-tube heat exchanger consists of a cylindrical body 1, a bottom 2, distribution chambers 3 with partitions 4 for the formation of coolant moves in the tubes 5 of the tube bundle. The bottom 2 and the distribution chambers 3 are connected to the casing 1 by means of flanges 6 with gaskets 7 by releasable connections (bolts with washers and nuts). The ends of the tubes 5 of the tube bundle are hermetically fixed in the tube sheets 8 welded to the housing 1. Inside the annular space coaxially with the partitions 4 installed inside the distribution chambers 3 for the formation of coolant moves through the tubes 5 of the tube bundle, along the tubes 5 are partitions 9 for the formation of coolant moves in the annular space of the pipes 5 of the tube bundle. Each of the partitions 9 has a transverse slotted slot 10 in the zone adjacent to it of the partition 4 in the distribution chamber 3, so that when changing the flow direction of one coolant in the pipes 5 of the tube bundle, change the flow direction of the other coolant in the annulus, allowing countercurrent movement of the coolants in each stroke of a multi-pass shell-and-tube heat exchanger. The nozzles of the inlet 11 and the outlet 12 on the distribution chamber 3 for the coolant moving in the pipes 5, and the nozzles of the inlet 13 and the outlet 14 for the coolant moving in the annulus are made on the housing 1.

Multi-pass shell-and-tube heat exchanger operates as follows.

A first coolant is supplied through a pipe 11, which flows from the distribution chamber 3 from top to bottom through the pipes 5 of the first stroke, and a second coolant flows from the bottom to the top of the annulus of the first stroke through the pipe 13 (streamlines with arrows of both coolants are shown in Figs. 1-3) .

Leaving the cover 2, the first heat carrier unfolds and reverses the direction of movement, that is, it moves upward from the second stroke of pipes 5. Since the partitions 9 installed in the annular space along the pipes 5 are aligned with the partitions 4 of the distribution chambers 3, they have a transverse cut 10 area adjacent to the partition 4 in the distribution chamber 3, then in this slot the second heat carrier rotates and changes the flow direction to the opposite, therefore, in each stroke of the multi-pass shell-and-tube heat exchanger both heat carriers move countercurrently relative to each other, and the first heat carrier, respectively, comes out from the last pipe passage 5 of the tube bundle along the pipe 12, and the second from the last pipe passage along the pipe 14.

Thus, the installation of the partitions 9 in the annular space along the pipes 5 of the tube bundle coaxially with the partitions 4 of the distribution chambers 3 and the creation in each partition 9 installed in the annular space of the transverse slotted slot 10 in the area adjacent to the partition 4 in the distribution chamber 3, provides the number of strokes in the annulus is the same as the number of strokes in the tube bundle and the countercurrent movement of the coolants in the pipes and the annulus in each stroke of the multi-pass shell-and-tube heat exchanger and that leads to increase in the average driving force intensification of heat transfer processes and higher productivity for coolants.

Claims (1)

A multi-way shell-and-tube heat exchanger, consisting of a cylindrical body, interconnected by means of flanges with gaskets of the bottoms and distribution chambers with partitions for the formation of coolant moves through tubes fixed in two tube sheets welded to the body, forming a tube bundle, partitions in the annulus, nozzles the entrance and exit of both coolants and supports welded to the housing, characterized in that the partitions in the annulus are installed along the tubes of the tube bundle coaxially with partitions installed inside the distribution chambers, and each of the partitions in the annulus has a transverse slotted slot in the part to which the partitions are adjacent in the distribution chamber.

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