RU2699903C1 - Heat exchanger - Google Patents

Abstract

FIELD: heat exchange equipment.

SUBSTANCE: invention relates to heat exchange technology and can be used to create heat exchangers. Heat exchanger includes housing with inlet and outlet branch pipes for inlet and outlet of hot and cold flows, heat exchange elements made in the form of several coaxially installed shells located with respect to each other with annular gaps, which form annular cavities. Annular cavities of hot and cold flows regularly alternate. On end faces of shells there are end profiled bottoms fixed to each other and to the housing and forming in-series arranged annular cavities. Said bottoms have isolated channels connecting said end cavities through one another. Said annular cavities of heat exchange elements are connected to cavities of inlet and outlet branch pipes of cold and hot flows through the above butt-end cavities formed with profiled bottoms.

EFFECT: technical result is improvement of technical characteristics and expansion of functional capabilities of heat exchanger.

1 cl, 3 dwg

Description

The invention relates to heat exchange technology and can be used to create heat exchangers.

Known heat exchanger containing a housing consisting of an outer and inner wall mounted coaxially with an annular gap and forming a cavity for the working fluid, inlet and outlet manifolds with nozzles, heat exchange elements made in the form of two-layer cylindrical shells connected to each other and the housing using pylons installed at the ends of the heat-exchange elements, while in the pylons channels are made for the supply and removal of the working fluid (RF patent No. 2569990, Application No.: 2014149786/06 dated 12/09/2014, IPC: F28D 7/10 - protot n).

The proposed heat exchanger operates as follows. Heat carrier is supplied to the internal cavity of the heat exchanger. The coolant is evenly distributed in the cavity of the heat exchanger and moves in the annular gaps located between the heat exchange elements and the inner wall of the housing. The working fluid through the inlet pipe enters the inlet manifold and then into the annular gap located between the outer wall and the inner wall of the housing. In the annular gap, the working fluid is divided into two streams. The first flow of the working fluid passes in an annular gap between the outer wall and the inner wall of the housing, heats up and is diverted to the outlet manifold. The second flow of the working fluid flows through the pylons into the annular gaps located between the walls of the heat exchange elements. Passing through the annular gaps, the working fluid is heated, after which the flow of the pylons enters the outlet manifold. In the discharge manifold, two flows of the working fluid are mixed together. The working fluid exits the outlet manifold through the outlet pipe.

The main disadvantages are the design complexity, significant overall dimensions due to significant structural gaps between the ring heat exchange elements, uneven heating of the shells caused by the sequence of passage of the coolant from the peripheral shell to the central one, which ultimately reduces the efficiency of the heat exchanger.

The objective of the invention is to remedy these disadvantages, improve technical characteristics and expand the functionality of the heat exchanger.

The solution to this problem is achieved by the fact that in the proposed heat exchanger containing a housing with inlet and outlet nozzles for input and output of hot and cold flows, heat exchange elements made in the form of several coaxially installed shells located relative to each other with annular gaps forming annular cavities moreover, the annular cavity of the hot and cold flows uniformly alternate between themselves, according to the invention, at the ends of the shells are installed end profiled bottoms, fastened interconnected and with the body, and forming successively located end annular cavities, the axial dimension of the cavities being monotonously decreasing from the inlet pipe to the inlet part of the heat exchange elements, while in said bottoms insulated channels are made connecting the said end cavities through one with each other, and angular the position of the channels in the end profiled bottoms of the previous end annular cavity is different from the location of similar channels in the subsequent end annular cavity, when volume, said annular cavities of heat-exchange elements are connected with cavities of inlet and outlet nozzles of cold and hot flows through said end cavities formed by profiled bottoms, while in the central part of profiled bottoms, inside the central shell, heat-exchange elements are installed in the form of separately arranged tubes arranged in a spiral , the cavity of which is connected to the cavity of one of the flows, and the cavity inside the Central shell is connected to the cavity of the other stream.

The invention is illustrated by drawings, where in FIG. 1 shows a general view of a heat exchanger, a longitudinal section, in FIG. 2 - enlarged scale of the heat exchanger inlet, FIG. 3 - the output of the heat exchanger on an enlarged scale.

The heat exchanger comprises a housing 1 with input 2, 3 and output 4, 5 nozzles for the input and output of hot and cold flows, respectively. The heat exchange elements 6 are made in the form of several coaxially installed shells 7 located relative to each other with annular gaps 8 forming annular cavities 9 and 10 of hot and cold flows, respectively. The annular cavity of the hot 9 and cold 10 flows evenly alternate with each other. At the ends of the shells 7 there are installed end profiled bottoms 11, fastened together and with the housing 1, and forming successively located end annular cavities 12 and 13. In said bottoms 11, isolated channels 14 and 15 are made, connecting the said end cavities through one another. The annular cavities 9 and 10 of the heat exchange elements are connected to the cavities of the inlet 1, 3 and outlet 4, 5 pipes of the hot and cold flows, respectively, through the said end cavities 12 and 13 formed by the profiled bottoms 11. In the central part of the profiled bottoms 11, inside the central shell 7, heat exchange elements are installed in the form of separately arranged tubes 16, the cavities of which are connected to the cavity of one of the flows, while the cavity inside the central shell is connected to the cavity of another flow.

The proposed heat exchanger operates as follows.

The hot stream is fed into the housing 1 of the heat exchanger through the input pipe 2 of the hot stream and through the end cavities 12 and channels 14 enters the annular cavity 9 of the hot component. The hot stream passes through the annular cavity 9 and gives off heat to the walls of the heat exchanger elements 6, made in the form of several coaxially mounted shells 7. At the outlet of the heat exchanger, the hot stream is collected in similar end cavities 12 and through the similar channels 14 enters the outlet pipe 4 of the output of the hot stream .

The cold stream is fed into the housing 1 of the heat exchanger through the inlet pipe 3 of the cold stream and through the end cavities 13 and channels 15 enters the annular cavity 10 of the cold component. The cold stream passes through the annular cavities 10 and, due to heat transfer, removes heat from the walls of the heat exchanger elements 6, made in the form of several coaxially mounted shells 7. At the outlet of the heat exchanger, the hot stream is collected in similar end cavities 13 and through similar channels 15 enters output pipe 5 output hot flow.

The installation in the central part of the profiled bottoms 11, inside the central shell 7, of heat exchange elements in the form of separately arranged tubes 16, the cavities of which are connected to the cavity of one of the flows, the cavity inside the central shell of which is connected to the cavity of another flow, simplifies the design of the heat exchanger and allows heat exchange between streams.

The execution of the axial size of the cavities monotonically decreasing from the inlet to the inlet of the heat exchange elements will compensate for the component flow into the heat exchange elements and ensure the required flow rates.

The implementation of the angular position of the channels in the end profiled bottoms of the previous end annular cavity different from the location of similar channels in the subsequent end annular cavity will improve the mixing conditions,

Using the proposed technical solution will improve the technical characteristics and expand the functionality of the heat exchanger.

Claims (1)

A heat exchanger comprising a housing with inlet and outlet nozzles for the input and output of hot and cold flows, heat exchange elements made in the form of several coaxially mounted shells located relative to each other with annular gaps forming annular cavities, moreover, the annular cavity of hot and cold flows uniformly alternate with each other, characterized in that at the ends of the shells are installed end profiled bottoms, fastened to each other and with the body and forming successively laid end annular cavities, the axial dimension of the cavities being monotonously reduced from the inlet to the inlet of the heat exchange elements, while the said bottoms are provided with isolated channels connecting the said end cavities through one another, and the angular position of the channels in the end profiled bottoms of the previous end annular cavity different from the location of similar channels in the subsequent end annular cavity, while these annular cavities of the heat exchange elements are connected heat exchanging elements in the form of separately arranged tubes arranged in a spiral, the cavities of which are connected to the cavity, are provided with cavities of the inlet and outlet nozzles of cold and hot flows through the said end cavities formed by profiled bottoms, while in the central part of the profiled bottoms, inside the central shell one of the flows, and the cavity inside the Central shell is connected to the cavity of the other stream.

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