RU2260159C2 - Heat-exchange apparatus - Google Patents

Abstract

FIELD: heat-exchange equipment.

SUBSTANCE: heat-exchange apparatus has supplying and removing collectors integrated by group of heat-exchange tubes having protrusions at their surfaces. Protrusions are made in form of sheets connected by their side surfaces with surface of tube along the length being equal to 1,5-3,0 thickness of sheets. Protrusions are disposed tangentially to surface of tube tat the points of connection of those sheets with tubes. Several sheets are fastened to tube along the perimeter of cross-section to overlap each other. Protrusions on surfaces of heat-exchange tubes are made in form of several sheets of different lengths being fastened along their side surfaces by welding or soldering along the whole length of surfaces of heat-exchange tubes. Protrusions in form of sheets fastened to surfaces of heat-exchange tubes can be also made to have slots and curves relatively sheets at adjacent, neighboring parts.

EFFECT: improved efficiency of heat exchange; provision of adjustment of heat flow.

7 cl, 12 dwg

Description

The invention relates to the field of heat engineering, specifically to the designs of heat exchangers, which use heat exchange between the liquid circulating in the pipes and the gas in the space between the pipes.

Heat exchangers with collectors connected by pipes are known from the state of the art, see US Pat. No. 5,186,251, F 28 F 1/02, 1993. The pipes are made with sections in the form of flat ovals.

The low heat transfer rate forces the use of a large number of pipes, which increases the weight of the equipment and its cost. Also known is a design using flat oval cross-section pipes with protrusions on the inner surface of the pipes, see RF patent No. 2137053 C1, 6 F 24 H 3/08, F 28 F 1/2, 1/40, 1998. The protrusions on the inner surface serve flow turbolisers and increase the intensity of heat transfer, however, only on the inner surface.

The closest analogue of this invention is a heat exchanger according to the copyright certificate of the USSR No. 1399632 A1, IPC F 28 D 7/16; F 28 F 1/24, 1988. The analogue contains inlet and outlet manifolds connected by a group of heat exchange tubes with protrusions on their surface. The presence of protrusions allows to intensify heat transfer, and it is advisable to increase the number of protrusions, reducing their thickness, that is, making them in the form of thin plates, however, the manufacture of pipes with radial thin ribs causes great difficulties in the manufacture of pipes by pressing, rolling, when obtaining thicknesses less than 1 mm creates a number of difficulties, and in the manufacture by casting, when filling with liquid metal of long, thin gaps is difficult to ensure.

When welding thin radial ribs with the surface of the pipes, a weld zone with reduced thermal conductivity is created.

The objective of the invention is to provide increased efficiency of heat transfer on the surfaces of heat transfer tubes while also providing the ability to control heat flow.

This problem is solved in that in a heat exchanger containing inlet and outlet collectors connected by a group of heat exchange pipes with protrusions on their surface, protrusions on the pipe surface are made in the form of sheets connected by their side surfaces to the pipe surface at a length equal to 1.5 -3.0 thickness of the sheets, and are located tangentially to the surface of the pipe in the areas of connection of these sheets with pipes.

In addition, along the perimeter of the pipe section, several sheets are attached to it, for example, by welding into a patch.

In addition, the protrusions on the surfaces of the heat exchanger tubes are made in the form of several sheets of various lengths, fastened along from the side surfaces, for example, by welding or soldering along the entire length of the surfaces of the heat exchanger tubes.

In addition, the protrusions in the form of sheets attached to the surface of the heat exchanger tubes are made lengthwise split and bent with respect to the sheets in adjacent adjacent areas.

In addition, at least part of the sheets can be made in the radial direction wavy.

In addition, the heat transfer pipes can be equipped with clamps, for example, in the form of levers on hinges, with drives that allow the sheets to be pressed to the surface of the pipe. In such designs, the levers ensuring the pressing of the plates to the pipes can be made with a manual drive and fixed with permanent magnets.

It is the implementation of the protrusions on the surface of the pipes in the form of sheets connected by their lateral surfaces to the surface of the pipe at a length equal to 1.5-3.0 thickness of the sheets, and their location tangentially to the surface of the pipe at the junction of these sheets with pipes allows to increase the efficiency of heat transfer . In this case, it becomes possible to increase the heat transfer surface without increasing the overall dimensions of the heat exchanger. With fixed dimensions of the volume bounded by two given cylindrical surfaces, the tangential arrangement of the protrusions on the surface of the inner cylinder (sometimes called "ribs") allows their length to be maximized in comparison with the radial or overhead arrangement of the protrusions (ribs). The section of the weld due to porosity can have a reduced coefficient of thermal conductivity, by 30-60% compared with the base metal. Attaching a protrusion-rib to the pipe surface tangentially with a tangent orientation to the pipe surface with fastening to the pipe wall by welding (or soldering) at a length equal to 1.5-3.0 thicknesses of the protrusion allows (with a margin of up to 1.9) to compensate for decrease in thermal conductivity. The heat transfer area between the protrusion plate and the pipe surface is 1.5-3.0 times larger than the area corresponding to the thickness of the plate section, which can reliably compensate for a possible decrease in heat conductivity in the weld zone. Resistance welding or brazing can be used using various types of materials, such as steel pipes and aluminum sheets.

Reducing the length of the contact zone to less than 1.5 can lead to a decrease in the intensity of heat transfer due to reduced heat conductivity of the contact zone, and an increase of more than 3.0 will lead to an unnecessary increase in the cost of manufacturing the apparatus due to an increase in welding and soldering. This proves the optimality of the proposed interval.

To an even greater extent, one can increase the heat transfer rate by attaching several sheets to the pipe along its perimeter. You can use the tabs in the form of sheets of different lengths, fastening them along the side surfaces, for example, by welding or soldering, which allows you to effectively use the surface of each sheet.

When blowing pipes, for example, with air, significant advantages are provided by the implementation of the protrusions along the length of the split and bent with respect to the sheets in adjacent, adjacent sections, as well as the execution of part of the sheets in the radial direction wavy. In a stream of air, such sheets experience intense fluctuations, which significantly increases the intensity of their heat exchange with air.

The heat exchanger provides the ability to simply adjust the intensity of heat transfer by pressing the sheets with levers on hinges with drives for moving them. Simple and reliable is the design with hand-operated levers and fixed with permanent magnets.

The invention is illustrated by drawings, illustrating a specific example of its use. In Fig.1 shows a General view of the heat exchanger, Fig.2 is a cross section of a heat exchanger pipe, Fig.3 is a diagram for determining the gain in the heat exchange surface area, Fig.4 is an example of using an oval tube, Fig.5 is an example use of a pipe with two flat walls, FIG. 6 is an example of a structure in which several sheets are attached to the perimeter of the pipe in each section along the pipe perimeter, and FIG. 7 shows a cross section of a heat exchange pipe in which protrusions are made in the form of several sheets of different lengths , scr heated along their lateral surfaces, Fig. 8 shows a cross-section of a heat exchanger pipe for which sheets are attached to the surface of the pipe with both ends, Fig. 9 shows an example of making sheets split, Fig. 10 shows a pipe with clamps made in the form of levers on hinges in the position where the levers are retracted from the surface of the pipe, Fig. 11 shows the same pipe in the position where the levers are brought to the pipe and press the plate to its surface, Fig. 12 shows the levers with manual transmission and fixing with permanent magnets.

The heat exchanger comprises collectors 1 for supplying and discharging liquid and heat exchange tubes 2 attached to two collectors. On all heat transfer tubes, protrusions are made in the form of sheets 3.

The liquid is supplied through pipes 4, and gas (or liquid) is supplied through pipes 5, which transfers part of the heat of the liquid flowing through pipes 4. Gas is removed through pipes 6, and the liquid through pipes 7.

For a pipe with two flat walls, protrusions in the form of sheets 8 can also be located on the inner surface of the pipe. The plates 9, 10, 11 are attached with an overlay in each of the pipe sections, and the plates 12, 13, 14 are made of various lengths and are overlaid with their connection along the entire length along the side surfaces of the sheet 15; attached to the surface of the pipe at both ends. The sheets cut into sections 16, 17 and 18, 19 are shown in Fig.9.

The lever 20, pivotally mounted on the axis 21, and the lever 22 with gaskets 23 are connected by ropes 24 through blocks 25 with drive rope drums 26, 27. It is possible to use the fixation of the levers with permanent magnets 28, 29.

The heat exchanger operates as follows. The liquid enters the collectors 1 and makes a movement from the inlet to the outlet manifold through heat exchange pipes 2 with projections 3 on their surfaces.

The liquid is supplied through pipes 4, and the gas through pipes 5. The gas is removed through pipes 6, and the liquids through pipes 7. When using this heat exchanger as an air heater, heated water flows through pipes 2 and heat transfer to the colder air located in the space between the pipes. Then, partially or completely cooled water is discharged through pipes 7, and gas, in this case air, heated by means of heat exchange with the surface of pipes 2, with protrusions 3, is removed through pipes 6 (Fig. 1) into the atmosphere of a heated room or to a pipeline with fans .

When using a heat exchanger as a gas cooler in compressor equipment, water with a low temperature of 15-30 ° C, which is heated by heat exchange with gas, is supplied to pipes 2 with protrusions 3. Liquid, usually water, enters through pipes 4, and is discharged through pipes 7, and gas at 170-270 ° C is supplied through pipes 5 and, after cooling to 25-35 ° C, is discharged through pipes 6.

Figure 2 shows the tangential arrangement of rectilinear protrusions in the form of sheets 3, oriented tangentially to the surface of the pipe 2.

If you specify the inner and outer radii r and R, see figure 3, then with a radial arrangement of the ribs its length l ₀ = Rr and is equal to the segment BC. The length of the protrusion (ribs) 1 with its tangential location is equal to the segment VD, that is

It follows that

Table 1 shows the results of calculations by the formula (1) for different values of r / l ₀ :

Table 1 r / l ₀ 0.5 1,0 1,5 2.0 2,50 3.0 3,5 4.0 l / l ₀ 1.41 1.73 2.00 2.2 2.45 2.65 2.83 3.0

It is seen that the gain in the heat transfer area with the tangential arrangement of sheets 3 can be very significant, for example, with r / l ₀ = 1.5; l / l ₀ = 2.0. The use of the space between two cylindrical surfaces, see figure 3, with the tangential arrangement of the ribs is much better than with a radial.

Pipes for the implementation of heat transfer processes may not be round, but elliptical, oval, see figure 4, which in some cases can reduce fluid flow.

As can be seen from figure 5, the protrusions 8 can intensify the heat transfer on the inner surface of the pipes 2, and it is possible to weld the sheets 8 to a flat sheet, and then molding from a sheet of a closed section of the pipe and its welding with a longitudinal (or inclined) seam. The tangential arrangement of thin (0.1-0.5 mm) sheets 8 makes it possible to easily attach them to a sheet with a thickness of 1-3 mm, and then deform them together, which would not be possible with a radial arrangement of long ribs on the inner surface of the pipes.

In Fig. 6, sheets 9, 10, 11 are attached to the pipe 2 in one section with an overlay, for example, by contact welding, which significantly increases the heat transfer in this section. The heat to the surface of the pipe near the "y" axis is supplied not by one, but by three sheets 9, 10, 11. They have a different configuration, allowing you to cover a significant portion of the space around the pipe 2 (where the gas is suitable). These sheets 9, 10, 11 are in contact with each other and with the surface of the pipe only in cross section along the y axis. If you weld the sheets along the entire surface of their contact, like sheets 12, 13, 14 in Fig. 7 (for example, by contact welding), then it is possible to form protrusions of different thicknesses along their length, which in some cases may be appropriate (see N .M. Belyaev "Fundamentals of heat transfer." Kiev. "Vysha school", 1989, pp. 305-314).

On Fig shows a design in which the plate 15 is attached to the surface of the pipe 2 at both ends, which can be done by welding (soldering), pre-stamped (curved) sheet. With a significant length of the heat exchange tubes for better cooling of the gas passing between the protrusions of the pipes, it is advisable to make these protrusions split along their length, as well as curved with respect to adjacent sections in Fig. 9 with respect to the sections of the protrusions of sheets 16 and 17, subsequent sections 18 and 19 offset and curved. This enhances the turbulence of the air flow and its heat exchange with the plates and pipes.

This design makes it possible to quickly control heat transfer without changing the temperature of the coolant.

For example, when using heat exchangers as heaters for heating rooms, if the temperature of the atmosphere rises, it is advisable not to open the windows and vents, which leads to heat loss to the atmosphere, but to reduce the amount of heat transferred from pressing the tangentially located protrusions - sheets, which, when their small thickness (0.1-0.5 mm) is easily feasible.

You can press the sheets to the pipe and fix in this position manually using a cable or chain.

Figure 10 shows a design with levers 20 on the axis 21 and 22. The levers are equipped with gaskets 23 made of fluoroplastic, polyethylene or other material.

Ropes 24 through blocks 25 are connected to drums 26, 27 provided with wires, for example, hydraulic.

If in Fig. 10 the levers are shown in the open position and the elastic sheets are free and fully realize heat transfer over the entire surface, then Fig. 11 shows the extreme position of the levers 20 and 22 when they are turned to the extreme position and press the sheets 3 to the surface 2. Pressing it is carried out not by the metal surfaces of the levers 20 and 22, but through the gaskets 23 of softer material (fluoroplastic, polyethylene, textolite, etc.)

The levers are installed along the length of the heat exchanger pipe with a certain pitch, for example 500-750 mm.

It is advisable to use the drive for large pipes, for small ones it is advisable to use a manual drive with locking levers in the closed position by permanent magnets 28, 29 (see Fig. 12). The levers 20, 22 are turned manually and the permanent magnets 29 fix them in the closed position.

Claims (7)

1. A heat exchanger containing inlet and outlet collectors connected by a group of heat exchange pipes with protrusions on their surface, characterized in that the protrusions on the surface of the pipes are made in the form of sheets connected by their side surfaces to the pipe surface at a length equal to 1.5-3 , 0 the thickness of the sheets, and are located tangentially to the surface of the pipe in the areas of connection of these sheets with pipes. 2. The apparatus according to claim 1, characterized in that along the perimeter of the pipe section, several sheets are attached to it, for example, by welding. 3. The heat exchanger according to claim 1, characterized in that the protrusions on the surfaces of the heat exchanger tubes are made in the form of several sheets of various lengths bonded along their side surfaces, for example, by welding or soldering along the entire length of the surfaces of the heat exchanger tubes. 4. The heat exchanger according to claim 1, characterized in that the protrusions in the form of sheets attached to the surface of the heat exchanger tubes are made lengthwise split and curved with respect to the sheets in adjacent adjacent areas. 5. The apparatus according to claim 1, characterized in that at least part of the sheets are made in the radial direction wavy. 6. The heat exchanger according to claim 1, characterized in that each of the heat exchanger tubes is equipped with clamps, for example, in the form of levers on hinges with actuators that allow the sheets to be pressed against the surface of the pipe. 7. The heat exchanger according to claim 1, characterized in that the levers ensuring the pressing of sheets to the surface of the pipes are made with a manual drive and fixed with permanent magnets.

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