SU1086336A1 - Heat exchanger - Google Patents

Abstract

HEAT / PENNIK containing coaxial pipes, fastened in pairs by means of transverse semi-annular partitions-plugs located diametrically opposite on the opposite ends of the pipes, and alternating at each end of adjacent pipes, forming helical channel channels connected to the collector chambers separated a septum on the cavities connected to the corresponding inlet and outlet nozzles of the media, characterized in that, in order to intensify the heat exchange and facilitate the installation-demo platemaking work, each pair of pipe fittings connected to downcomers positioned along the length of the pipes at a predetermined pitch, perpendicular to their longitudinal axis and having at the ends of the oblique sections 45 ° with respect to the longitudinal axis of the pipes, with the cuts being directed in opposite directions both in adjacent fittings and in each individual fitting, and the collector chambers are connected to the outer pipe. (L O oa a 00 co a

Description

The invention relates to heat exchangers operating primarily on gaseous media and can be used in heating and ventilation systems of buildings, where the heat of vent emissions is used as a secondary energy resource.

A spiral heat exchanger is known, comprising twin plates rolled into a helix, studs, partition walls, inlet and outlet connections for heat exchanging media, end caps 1.

The disadvantages of this heat exchanger are the difficulty of making paired heat exchange helical elements; the complexity of the repair; uneven distribution of heat exchange media at the initial part of the entrance to the spiral, since the diameters of the inlet nozzles are several times smaller than the length of the heat exchanger (a significant part of the spiral is used inefficiently); the least effective associated movement of coolants; cumbersome; the possibility of accumulation and clogging of condensate in the lower areas of the helix; the need for close positioning of the supply and exhaust ducts, since the nozzles for supplying the media inside the heat exchanger are adjacent.

A heat exchanger is known that contains coaxial pipes and hollow rods connecting annular gaps between pipes and alternating with alternating pipes and arranged in predetermined pitch along the length of the pipes, providing a zigzag motion of the medium in annular gaps 2.

The disadvantage of the heat exchanger is the difficulty of assembly and disassembly.

A heat exchanger is known, containing co-axial pipes, which are fastened in pairs by means of transverse semi-ring non-town-caps, which are diametrically opposite on opposite pipe ends, and alternating at each end of adjacent pipes; I am waiting for the spiral-slotted Kana .ioii pipes connected to the collector chambers divided by cavities into the cavities connected to the corresponding pipe inlet and outlet of the media 3.

Disadvantages of the heat exchanger - the complexity of installation and dismantling and the inefficiency of the heat exchange process.

The purpose of the invention is to facilitate installation and dismantling and I1genicification of heat exchange.

The goal is enhanced by the fact that, in a heat exchanger containing coaxial pipes, fasten in pairs by means of transverse semi-circular bulkheads-plugs located on the opposite ends of the pipes, the diameter is opposite; and on each of the end pipes of the adjacent pipes - alternating, with the formation between the pipes of spiral slotted channels connected to the collector chamber. divided by cavities into the cavities connected to the corresponding inlet and outlet connections of the media, each pair of pipes is connected with overflow pipes located ennymi along the length of pipe a predetermined tagom perpendicular to their longitudinal axis and having at the ends of oblique slices at an angle of 45 ° relative

0 but in the longitudinal axis of the pipe, with the cuts being directed in opposite directions both in adjacent fittings and in each of the individual fittings, and the collector chambers are attached to the outer pipe.

FIG. 1 shows a suction heat exchanger, longitudinal section; in fig. 2 is a view A of FIG. one; in fig. 3 is a view B in FIG. one; in fig. 4 is a view A of FIG. 1 in the case of a polygonal embodiment of the cross section of pipes, in particular rectangular; in fig. 5 is a view B in FIG. 1 with a polygonal embodiment of a cross section of pipes, in particular rectangular; in fig. 6 - section of coaxial tubes of the suction heat exchanger with overflow valves; in fig. 7 - one of the spiral slotted channels with overflow valves equipped with baffles (partially).

The heat exchanger contains pipes 1, half-ring partitions-plugs 2, slotted channels 3, collector chambers 4-7, partitions 8 and 9, overflow nipples 10 with sections 11 and bump stops 12, studs 13, trap 14.

The heat exchanger operates as follows.

One of the media enters the collector chamber 4, passes through the slotted channels 3 and is discharged through the collector chamber 5, the other medium enters the collector chamber 6, passes through similar slotted channels 3, heat exchange with the first medium through the wall of the pipes 1. Channels 3 for workers

0 media are diametrically opposed, due to the diametrically opposed installation of n-ring partitions-plugs 2, which ensures the circulation of working media in a spiral, and the installation of overflow fittings 10 with environments 11

5 provides mixing of media in channels 3, which intensify the process of heat exchange.

If high humidity environments are used, reliable

condensate is provided

- cooling data environments kopdensatootvodchik 14.

This is a simple heat exchanger that is simple in its construction, efficient in operation and can work on environments with high moisture content, if it is used in heat utilization systems for running gases.

FIG.

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Claims (1)

HEAT EXCHANGER containing coaxial pipes fastened in pairs by means of transverse semicircular plug partitions located on opposite ends of pipes, is diametrically opposite, and alternating at each end of adjacent pipes, with the formation of spiral slotted channels between pipes connected to collector chambers separated by a partition on cavities connected to the corresponding nozzles of the inlet and outlet of the media, characterized in that, in order to intensify heat transfer and facilitate installation and dismantling work, each pair of pipes is connected by overflow fittings located along the length of the pipes with a given pitch, perpendicular to their longitudinal axis, and having oblique sections at the ends at an angle of 45 ° relative to the longitudinal axis of the pipes, while the sections are directed in opposite directions as in adjacent fittings, so is each individual fitting, and the collector chambers are attached to the outer pipe. OO o so o o