RU2548290C2 - Horizontal gas cooler-moisture separator - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: horizontal gas cooler contains pipes in cylindrical shells. At that the cylindrical shells are fixed by tight tube plates and from two sides are enveloped by shells that at opposite sides are connected to tee. At that from third side to the tee the condensate gathering tank is connected, it is located under the gas cooler, and tee is provided with branch pipe of gas outlet.

EFFECT: decreasing of moisture content in gas at gas cooler outlet.

16 cl, 3 dwg

Description

This invention relates to the field of mechanical engineering, heat engineering, refrigeration industry and compressor engineering. It can be used in the production of domestic, industrial refrigerators, condensers, heat exchangers and compressors, later used in all industries.

Among the currently available analogues of the present invention, the “pipe-in-pipe” heat exchanger is known (RU 2035683), comprising an inner pipe with external cylindrical ribs and a turbulator installed therein in the form of a spiral tape wound on a rod, a tangential pipe for supplying the annular medium and a pipe for its output, the cylindrical ribs of the inner pipe are hollow, and their cavities are in communication with the cavity of the latter.

The disadvantage of this technical solution is its design, in which the input gas stream completely enters the outlet of the heat exchanger.

In addition, it is known "Shell-and-tube heat exchanger" (RU No. 2451887), containing identical sections interconnected, each of which contains a bundle of pipes mounted in the casing, fixed in the tube sheets, the collector chambers of the pipe and annular media, each section is equipped with end hard hollow covers, in the side walls of which perpendicular to the longitudinal axis of the section, through holes are made, while the sections are interconnected along the axes of the holes in the covers through sealing elements between between the side walls of the covers, the cavities of which form the collector chamber of the tubular medium, each section being additionally equipped with at least one rigid shell tightly enclosing the casing, located in the interval between the end caps, in areas adjacent to the tube sheets, in the side walls of which through holes are made at the same time with the casing, the axis of which lies in the same plane with the axes of the holes of the end caps, while the sections are additionally interconnected along the axes of the holes in the shell the nut and the casing through the said sealing elements between the side walls of the shell, the cavities of which form the collector chamber of the annular medium.

The disadvantage of this technical solution is its design, in which the input gas stream completely enters the outlet of the heat exchanger.

The specified invention is the combination of essential features of the closest system of the same purpose to the claimed invention. Therefore, it is adopted as a prototype of the claimed invention.

Disclosure of the invention.

The technical problem to be solved by the claimed invention is directed is the provision of moisture separation in gas coolers.

The technical result provided by the claimed invention is to reduce the moisture content in the gas at the outlet of the gas cooler.

The essence of the invention lies in the fact that the horizontal gas cooler-moisture separator contains pipes enclosed in cylindrical casings. In this case, the cylindrical casings are secured by sealed tube sheets and are enclosed by shells on both sides. It differs in that the shells from two opposite sides are attached to the tee. Moreover, on the third side, a condensate collection tank is connected to the tee. Moreover, the condensate collection tank is located at the bottom of the gas cooler, and the tee itself is equipped with a gas outlet pipe.

In addition, in this horizontal gas cooler-water separator, the diameter of the tee holes on the side of the shells may be larger than the diameter of the tee holes on the side of the condensate collecting tank. In addition, one shell using a backing ring can be connected to an elliptical plug in which the gas inlet pipe is located. In addition, in this horizontal gas-cooler-water separator, pipes can be made with longitudinal external fins, and displacers coming out of the pipes from one end can be placed inside them, while other pipe ends are closed with plugs. In this case, annular transverse slots can be made along the edges of the pipes. In this case, the displacers can be made in the form of longitudinal steel pipes. In addition, in this horizontal gas cooler-dehumidifier, one shell can be attached to the tee using a washer ring, and the other using a sealed tube separator. The tee can be equipped with a chipper, which can be made in the form of a metal curved sheet with a hole. The condensate collection tank can be made in the form of an elliptical plug, while a drain pipe with a sampling fitting for the condensate collected in the tank can be placed in it. The pipes in this horizontal gas cooler-dehumidifier can be made of aluminum alloy. In addition, the pipes can be equipped with rotary elbows. In this case, one of the elbows can be equipped with a purge tube with a stopper and an aluminum gasket. In addition, one of the pipes may be provided with a cooling water inlet pipe. In addition, in this gas cooler, one of the displacers with the end face emerging from the pipe can be connected to the cooling water outlet pipe, and the rest of the displacers can be connected with the rotary elbows at one end. In addition, in this gas cooler, one shell can be equipped with a boss for a pressure gauge, a fitting for a thermometer and a drive for a safety valve.

A brief description of the drawings.

The invention is illustrated by the following graphic materials.

The figure 1 shows a longitudinal section of the gas cooler (side view), figure 2 shows the gas cooler (side view, from the end). Figure 3 shows a longitudinal section of a condensate collection tank (side view).

Symbols of the structural elements of the invention depicted in the drawings: gas inlet pipe (1), gas outlet pipe (2), inlet shell (3), elliptical plug (4), washer ring (5), sealed tube sheet (6), outlet shell (7), hermetic tube sheet (8), tee (9), condensate collection tank (10), drain pipe (11), chipper (12), swivel elbow (13), purge pipe (14), fitting ( 15), run-off (16), boss (17), cooling water inlet pipe (18), cooling water outlet pipe (19), plug (20), cylinder sky casing (21), aluminum finned tube (22), the displacer (23), a nozzle (24).

The implementation of the invention.

The horizontal gas cooler-dehumidifier has an inlet shell (3), which is connected to the elliptical plug (4) using a washer ring (5) for better penetration of the metal. A gas inlet pipe (1) is placed in the elliptical plug (4). The input shell (3) is connected to the tee (9) using a sealed tube sheet (6). The tee (9) is connected to the output shell (7) using a backing ring (5) for better penetration of the metal. The diameter of the tee holes (9) on the side of the shells is larger than the diameter of the tee hole on the side of the condensate collecting tank, in order to reduce the metal-consuming characteristics of the gas cooler. In the output shell (7), tee (9), inlet shell (3) there are four cylindrical shells (21), which are secured by a dividing hermetic tube sheet (6) and a hermetic tube sheet (8). The input (3) and output (7) shells cover cylindrical casings (21) on both sides. In the tee (9) there is a gas outlet pipe (2) and a condensate collection tank (10). The condensate collection tank (10) is located at the bottom of the gas cooler to achieve the flow of condensed moisture (water) into it under the action of gravity. The condensate collection tank (10) is made in the form of an elliptical plug and is equipped with a drain pipe (11) to drain the collected condensate. The drain pipe (11) is made with a fitting (24) for collecting condensate. Inside the tee (9), an opening from the side of the condensate collecting tank (10) is closed by a chipper (12) made in the form of a sheet with a hole bent inwardly from the condensate collecting tank (10). The chipper (12) prevents re-capture by the gas stream of liquid from the condensate collecting tank (10) .. An aluminum finned tube (22) is enclosed in each cylindrical casing (21) to ensure a high coefficient of heat transfer from gas to the pipe. Along the longitudinal ribs of each aluminum finned tube (22), annular transverse slots are made to create a turbulent air flow inside the cylindrical casing (21). Inside each aluminum finned tube (22), a displacer (23) is placed, emerging from each aluminum finned tube (22) from one end, while its other end is closed by a plug (20) to create a counterflow of cooling water inside the aluminum finned tube (22). Each displacer is made in the form of a longitudinal steel pipe. One aluminum finned tube (22) is connected to the cooling water inlet pipe (18). All four aluminum finned tubes (22) are connected to three rotary elbows (13) for the consecutive transition of cooling water from the displacer (23) of one pipe (22) to the space between the other pipe (22) and the displacer (23) located in this pipe . In this case, one of the displacers (23) exiting from the pipe (22) end is connected to the cooling water outlet pipe (19), and the rest of the displacers (23) are connected by one end to the rotary elbows (13). One of the rotary elbows (13) is equipped with a purge tube (14) to eliminate air congestion inside aluminum finned tubes (22). The purge tube (14) is made with a stopper and an aluminum gasket for tightness. The output shell (7) is equipped with a fitting (15) for a thermometer, a drive (16) for a safety valve, a boss (17) for a pressure gauge.

Description of the invention

Gas enters through the gas inlet pipe (1) into the space of the inlet shell (3) and the elliptical plug (4), fills it, then passes in the space between the cylindrical shells (21) and aluminum finned tubes (22), after which it enters the outlet space shell (7) and tee (9), fills it and exits through the gas outlet pipe (2). At the same time, it is intensively cooled by heat exchange with cooling water, which enters through the cooling water inlet pipe (18), goes in the forward direction in the cavity between the first aluminum finned tube (22) and the displacer (23), and abuts the plug (20), then in the opposite direction passes through the displacer (23) and through the first rotary elbow (13) it enters the next aluminum finned tube (22). Thus, the cooling water passes through the cavities between all four aluminum finned tubes (22) and the displacers (23), abuts the plugs (20), then goes in the opposite direction along the last displacer (23) and exits through the cooling water outlet ( 19). At the same time, air accumulated in aluminum finned tubes (22) is periodically discharged through a purge tube (14). In addition, in the inner space of the outlet shell (7) and the tee (9), part of the cooled gas condenses into moisture (water), which flows along the inner surface of the walls of the outlet shell (7) and the tee (9) to the chipper (12), then through the bump hole (12) enters the condensate collection tank (10). From the condensate collecting tank (10), the collected moisture (water) is discharged using a drain pipe (11) with a fitting (24).

Thus, it follows that in this claimed invention, the claimed technical result - reducing the moisture content in the gas at the outlet of the gas cooler - is achieved by pipes enclosed in cylindrical casings. In this case, the cylindrical casings are secured by sealed tube sheets and are enclosed by shells on both sides. In this case, the shells from two opposite sides are connected to the tee. Moreover, on the third side, a condensate collection tank is connected to the tee. The condensate collection tank is located at the bottom of the gas cooler, and the tee itself is equipped with a gas outlet pipe.

Since the design of the prototype of the claimed invention is such that the gas inlet stream completely enters the outlet of the heat exchanger, the moisture content in the gas at the outlet of this heat exchanger is greater than the moisture content in the gas at the outlet of the gas cooler of the invention, in which there is a moisture separation function, carried out by means of a condensate collecting tank, its placement at the bottom of the gas cooler.

Industrial applicability.

The author made a prototype of the claimed invention, tests of which confirmed the achievement of the claimed technical result.

The inventive horizontal gas cooler-moisture separator is implemented using industrially produced devices and materials, can be manufactured at any machine-building enterprise and will be widely used in the refrigeration industry.

Claims (16)

1. A horizontal gas cooler-dehumidifier containing pipes enclosed in cylindrical casings, while the cylindrical casings are secured by sealed tube sheets and are enclosed by shells on both sides, characterized in that the shells are attached to the tee on two opposite sides, while on the third side to the tee a condensate collection tank is connected, and the condensate collection tank is located at the bottom of the gas cooler, and the tee itself is equipped with a gas outlet pipe. 2. The horizontal gas cooler-moisture separator according to claim 1, characterized in that the diameter of the tee holes on the side of the shells is larger than the diameter of the tee hole on the side of the condensate collection tank. 3. The horizontal gas cooler-dehumidifier according to claim 1, characterized in that one shell using a washer ring is connected to an elliptical plug in which the gas inlet pipe is located. 4. The horizontal gas cooler-moisture separator according to claim 1, characterized in that the pipes are made with a longitudinal external ribbing, with displacers exiting the pipes from one end, while the other ends of the pipes are closed with plugs. 5. The horizontal gas cooler-moisture separator according to claim 4, characterized in that annular transverse slots are made along the edges of the pipes. 6. The horizontal gas cooler-moisture separator according to claim 4, characterized in that the displacers are made in the form of longitudinal steel pipes. 7. The horizontal gas cooler-dehumidifier according to claim 1, characterized in that one shell is connected to the tee by means of a washer ring, and the other by means of a sealed tube sheet. 8. The horizontal gas cooler-moisture separator according to claim 1, characterized in that the tee is equipped with a chipper, while the chipper is made in the form of a metal curved sheet with a hole. 9. The horizontal gas cooler-dehumidifier according to claim 1, characterized in that the condensate collection tank is made in the form of an elliptical plug, while a drain pipe with a fitting is placed in it. 10. The horizontal gas cooler-moisture separator according to claim 1, characterized in that the pipes are made of aluminum alloy. 11. The horizontal gas cooler-moisture separator according to claim 1, characterized in that the pipes are provided with rotary elbows, while one elbow is provided with a purge tube with a stopper and an aluminum gasket. 12. The horizontal gas cooler-water separator according to claim 1, characterized in that one of the pipes is equipped with a cooling water inlet pipe. 13. The horizontal gas cooler-dehumidifier according to claims 4 or 11, characterized in that one of the displacers, the pipe outlet facing the pipe, is connected to the cooling water outlet pipe, and the remaining displacers are connected at one end to the rotary elbows. 14. The horizontal gas cooler-moisture separator according to claim 1, characterized in that one of the shells is equipped with a boss under the manometer. 15. The horizontal gas cooler-moisture separator according to claim 1, characterized in that one of the shells is equipped with a fitting for a thermometer. 16. The horizontal gas cooler-moisture separator according to claim 1, characterized in that one of the shells is provided with a drive for a safety valve.

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