SU1523864A1 - Evaporator - Google Patents

Abstract

The invention relates to refrigeration engineering, in particular to shell-and-tube evaporators of refrigeration units with in-line boiling of the refrigerant. The purpose of the invention is to intensify heat exchange by reducing the hydraulic resistance in the first row of heat exchanger pipes along the course of the refrigerant. This goal is achieved by supplying the evaporator with a collector 9 for dispensing refrigerant with capillary tubes 10 fixed on the inner surface of the heat exchanging tubes 11 of the first row along the movement of the refrigerant with a finely cellular wetted mesh 12, which allows to intensify the heat exchange. 3 hp f-ly, 2 ill.

Description

one

(21) i 326726/23-Ob

(22) 11/09/87

() 11/23/89. Bul G “Z (75) V.M.Shleinikov (53) 621.57 (088.8)

(56) Koshkin N.N. Refrigerating machines. L .: Mechanical Engineering, 1985, p. 320. (5) EVAPORATOR

(57) The invention relates to refrigeration engineering, namely to shell-and-tube evaporators of refrigeration units with in-tube boiling of the refrigerant. The purpose of the invention is to intensify

heat exchange due to a decrease in the hydraulic resistance in the first row along the course of the coolant flow of the heat exchange pipes. This goal is achieved by supplying the evaporator with a collector 9 for distributing refrigerant with capillary tubes 10 fixed on the inner surface of the heat exchange tubes 11 of the first row along the coolant movement with the help of a finely cellular wetted mesh 12, which allows to intensify the heat exchange, 3 s. . f-ly, 2 ill.

(/)

The invention relates to refrigeration engineering, in particular to shell-and-tube evaporators of refrigeration units with in-line boiling of the refrigerant.

The aim of the invention is to intensify heat exchange by reducing the hydraulic resistance in the first row of heat exchanger tubes along the course of the refrigerant.

1 shows a schematic of an evaporator; 2 shows a communication node for a liquid refrigerant manifold with two capillary tubes forming

parallel turns with free final boiling pressure of the refrigerant

l it

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thirty

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tsami on various length of heat exchange tubes.

The evaporator includes a horizontal housing 1 welded to tube grids 2 closed at the ends of the bottoms 3 with partitions forming sections, inlet and outlet connections of heat exchanging currents k - 7, an additional outlet 8 for feeding a portion of liquid refrigerant from the condenser 25 into the collector 9, to which capillary tubes 10 of various lengths are attached, placed in the heat exchange tubes 1 of the first along the coolant flow row of heat exchange tubes and pressed to their inner surface by finely waxy, wetted grids 12.

Capillary ;; the tubes can be made in the form of spirals with parallel turns (figure 2), in the form of spirals with intersecting turns (not shown) or in the form of straight tubes.

The evaporator works as follows.

The coolant enters the annular space of the evaporator 1 through the pipe C, and leaves it after cooling through the pipe 7. The liquid-liquid mixture after the throttle valve enters the pipes 11 fixed in the tube sheets 2 of the first course of the heat exchanging pipe the evaporator through the pipe 5 in the bottom 3 with partitions for multi-pass movement of the refrigerant. Since the vapor content in the mixture is insufficient for ring flow, a part of the liquid refrigerant from the condenser is fed through pipe 8 to the collector 9 under condensing pressure. From it, the liquid passes through capillary tubes 10 (one and more in each heat exchange tube) located in heat exchange tubes.

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pipes 11. The largest amount of liquid in the initial heat exchanger tubes 11, which is their steam content, and contributes to the growth of the efficiency of heat transfer. Passing through all the moves of the amplifier, the refrigerant vapor goes out of the pipe 6 into the compressor cooling the installation. The technical and economic effect is achieved due to the reduced evaporator thalamide and energy consumption to the installation due to its hydraulic resistance

Claims (3)

1. An evaporator containing a full body with divided packings on the bottom sections, heat pipes fixed in tr gratings, and inlet pipes and heat exchanging media, differing from the fact that, due to a decrease in the hydraulic resistance, the first in the course of the agent's movement is a series of heat-exchange tubes, additionally equipped with wets with nets, a coolant distribution manifold and a capillary tube of various lengths connected to the end with the collector, while the latter is installed between the bottom of the tube sheet , before the first movement of the refrigerant near the heat pipes, and to the internal surface of the latter, the capillary tubes with free ends are pressed with finely cellular pipes. 2. The evaporator according to claim 1, distinguished by the fact that the capillary tube is made in the form of a spiral in parallel turns. 11 in the form of straight tubes, twisted with parallel coils or intersecting, pressed against the smooth walls of pipes 11 or arranged in their grooves, covered with a finely meshed mesh or not, terminating at different lengths of pipes 11 to evenly maintain steam content and reduce hydraulic resistance. The passage of the capillary tubes, the liquid is cooled with a simultaneous drop in its pressure so that at the outlet of the tubes 10 its pressure becomes equal to f l It 0 0 five five 0 five 0 five pipes 11. The greatest amount of heat the liquid gives in the initial sections of heat exchange pipes 11, which increases the steam content in them, and this contributes to the growth of the efficiency of heat transfer. Pass through all the evaporator strokes, the refrigerant vapor is discharged through pipe 6 into the compressor of the refrigeration unit. The technical and economic effect is achieved due to a decrease in the heat intensity of the evaporator and energy consumption for the installation due to lower hydraulic resistance. Invention Formula 1. An evaporator containing a horizontal body with divided partitions on the bottom sections, heat exchange pipes fixed in tube sheets and inlets and outlets of heat exchanging media, characterized in that, in order to intensify heat exchange by reducing the hydraulic resistance in the first the coolant movement is a series of heat exchange tubes, it is additionally equipped with wetted nets, a liquid coolant distribution manifold and capillary tubes of various lengths connected at the end to the collector, the latter is installed between the bottom and the tube sheet, in front of the first along the coolant, a series of heat exchange tubes, and capillary tubes open with free ends are pressed to the inner surface of the latter with finely meshed grids. 2. An evaporator according to claim 1, characterized in that the capillary tubes are made in the form of spirals with parallel turns. 3. The evaporator according to claim 1, wherein the capillary tubes are made in the form of spiral coils with intersecting turns. A evaporator according to claim 1, characterized in that the capillary tubes are straight. Fm.1