DE3045731A1 - Flow regulator for heat exchanger tube - is plastics insert to restrict flow to outer zone for improved heat transfer - Google Patents

Abstract

The heat exchange device such as an absorber, resorber evaporator, condenser etc. operating on the counterflow principal, has a tube bundle with members inside the tubes (28) to reduce the internal volume of the tubes. These throttling members cause the flow to take place only over the tube walls, for greater heat transfer, and efficiency. The members can be hollow tubes (24) supported inside the outer tubes by radial spacers (26) and their ends (30) are closed. Alternatively, solid rods which may be triangular in section can be used, supported by their edges. These hollow or solid members are of plastics material.

Description

'Heat exchanger'

The invention relates to a heat exchanger, in particular a tube bundle heat exchanger, having at least one of one Heat transfer medium through which heat exchange pipe can flow.

If heat exchangers of this type are to be used to transfer heat in as pure countercurrent as possible, as is desired for use in air conditioning refrigeration technology, for example as an absorber, resorber, condenser or evaporator, in which a non-azeotropic refrigerant mixture or a multi-component solution cycle is used, As a result, not only the temperatures of the cooling or heating medium but also the temperatures of the refrigerant slide along the flow path, this results in very long heat exchange tubes in particular when large temperature changes in the heat transfer media, especially in connection with small temperature differences r between these media should be achieved. In these cases

• Due to the long heat exchange tubes, it is hardly possible to use them to be accommodated in a single heat exchanger. In order to obtain the desired heat exchange surface, it is therefore necessary to use the heat exchange tubes to be divided between several heat exchangers connected in series. However, this division causes high costs in manufacture and large space requirements for installation.

The invention is therefore based on the object of a heat exchanger of the type mentioned in such a way that at

"Ό constant power significantly reducing the length of the Heat exchange tubes is possible. The heat exchanger should be simple and therefore inexpensive to manufacture and in structure moreover, be able to fully meet the requirements of the company.

According to the invention, the solution to this problem consists in that at least one displacement body is arranged in the heat exchange tube in such a way that the interior of the heat exchange tube the heat transfer medium can only flow through in the area bordering the pipe wall. Through this training the flow becomes of the heat carrier to the periphery and thus in the vicinity of the heat exchange surfaces with the result that, based on same flow velocity, the length of the heat exchange tubes proportional to the ratio of the remaining flow area to the flow area without internals, which leads to leads to a reduction in the number of heat exchangers connected in series.

The displacement body is advantageously rod-shaped formed and extends in the longitudinal direction of the heat exchange tube.

A simple design of the displacement body is given when it is a polygonal, in particular an approximately equilateral triangular or square profile, with the edges of the profile on the inner wall of the heat

• the exchange tube is supported at least in some areas and forms flow channels between the side surfaces and the tube wall.

A particularly preferred development of the invention can consist in that the displacement body has an approximately circular profile has and between itself and the inner wall of the heat exchange tube a flow channel in the form of an annular gap forms. In this case, it is recommended that the displacement body through the radially extending, the annular gap penetrating spacer is supported on the inner wall.

In order to apply the heat transfer medium to the inner wall as uniformly as possible, the displacement body is advantageously the same axially arranged in the heat exchanger pipe.

To save material and weight, it is advisable to design the displacement body as a hollow body. Know this If the displacement body is in the form of a tube, it is necessary to close at least one end of the tube in order to exclude a flow through the pipe.

Because of the flowing heat carrier axial forces on the displacement body are transmitted, it is recommended that the displacement body to divert such flow forces is supported in the axial direction.

The material of the displacement body depends on the particular application adapt, in an advantageous manner, however, the displacement body will be made of plastic.

Further advantages and features of the invention emerge from the following description of exemplary embodiments in conjunction with the schematic drawings. Here show:

. Figure 1 is a longitudinal section through the left end

a shell and tube heat exchanger according to the
Invention in detail,

Figure 2 shows a cross section according to the cutting line

II-II through the subject of Figure 1,
with parts lying behind the cutting line
are not shown and

Figure 3 shows an embodiment variant of the object

of Figure 2.

The same parts are provided with the same reference symbols in the individual figures.

Figure 1 shows the left end of a tube bundle heat exchanger 10 in longitudinal section and as a detail. Thereafter, the casing tube 12 is closed with the tube sheet 14 at its left end.
This has a large number of bores into which the heat exchange tubes 16 are welded or rolled, see above
that they open into the collecting chamber 18. This is limited by a cover 20 which is fastened to the tube sheet 14 by means of a flange 22 with the aid of screws.

In each of the heat exchange tubes 16, a displacement body 24 in the form of a tube is concentric or with the heat exchange tube arranged at least approximately coaxially. To fix this position, the displacement bodies have at least three am Perimeter evenly distributed spacers 26, which

are supported on the inner wall 28 of the heat exchanger tube. In the longitudinal direction of the displacement body there are several such spacers with mutual spacing and each arranged in one plane. The displacement bodies can consist of individual sections arranged one behind the other.

• Since the displacement body 24 as a hollow body, in the present If designed as pipes, at least one of the pipe ends is closed to prevent a flow, For this purpose, a cap 30 is arranged on the displacement body at the left end of the displacement body 24. At this are simultaneously axially extending struts 32 in the form of rods fastened, which the displacement body 24 with the Connect cover 20 or only support it on the cover so that the displacement bodies are fixed in the axial direction and "10 cannot be moved by flow forces.

During operation, the heat transfer medium flows from right to left through the annular gap into the collecting space 18, on the other hand the second medium involved in the heat exchange in the jacket tube 12 flows in countercurrent, that is to say from left to right, and the heat exchange tubes 16 acted upon from the outside (see. Fig. 1).

Figure 2 shows a cross section through a heat exchange tube according to the invention in more detail and on a larger scale.

The radial support and can be seen particularly well Fixing of the displacement body 24 in the form of a tube with the aid of the spacers 26 on the. inner wall 28 of the heat exchange tube 16. The spacers 26 here consist of radially extending round metal rods or of continuous ones Longitudinal ribs, in the case of a production of the displacement body 24 from plastic, the spacers can be used as short ribs or also as continuous ribs in one piece with the displacement body 24. How on As can be clearly seen from FIG. 2, the arrangement of the displacement body 24 has resulted in an annular gap 32, which adjoins the inner wall of the heat exchange tube 16. In this way the flow of the heat carrier is close to that Wall brought up through which the heat exchange takes place and the flow cross-section is greatly reduced.

In Figure 3 is a variant of a displacement

. body 24 shown in a representation corresponding to FIG. The displacement body 24 here has the profile of an isosceles Triangle, the circumference of which is identical to the inside diameter of the heat exchanger tube 16. A special radial one Support and fixation of the displacement body 24 is therefore not necessary in the present case, since the edges 34 are supported on the inner wall 28 of the heat exchange tube 16. This support can take place over the entire length of the displacement body 24, it can also be carried out only in certain areas by the edges 34 of the displacement body 24 being flattened or broken in intermediate areas.

In the present embodiment, the heat transfer medium flows between the side surfaces 36 of the displacement body and the inner wall 28 in three channels, each of which has the cross-sectional shape of a segment of a circle.

In the exemplary embodiment according to FIG. 3, the displacement body is shown as a solid, it could just as easily be a hollow body be designed according to FIG. It would also be possible to have the displacement body with four corners or if necessary to be formed with even more corners and to be arranged in the heat exchanger tube 16 in accordance with the teaching of FIG.

The displacement bodies 24 extend approximately over the entire length of the heat exchange tubes 16. The reduction in cross section of the interior of the heat exchange tube 16 is in each case approximately 50 to 80%, preferably 70%.

The extent to which the heat exchange tubes are shortened in an education according to the invention can be clearly seen from the following.

For a heat exchanger tube without a displacement body, the following relationship applies to the flow length:

L __ w c-o-At • * · *
• «*« · · · • · <♦ # * »* · d. 4 q.
i ι * * A * * *
• # <t · ♦ WM
• * ft * * · • Here mean:
5

L = length of the heat exchange pipe through which flow d. = Inside diameter of the heat exchange pipe w = flow velocity of the heat transfer medium c = specific heat capacity of the heat transfer medium ξ = density of the heat transfer medium

t = required temperature change of the heat transfer medium Heat flux density b 'heat exchange tube.

q. = heat flow density based on the inner surface of the

For a heat exchanger tube with a displacement body according to the invention results (see Fig. 2):

L _ w «c?« A t

d. 4-q. · ¹

where d _{v is} the outer diameter of the displacement body. The influence of the spacers 26 is neglected here.

For a heat exchange pipe with an inside diameter d- = 21 mm

and an outer diameter d _v = 18 mm of the tubular displacement body results in a value of 0.2 65 for the factor in the square brackets. The heat exchanger tube can be shortened by this factor in the case of the design according to FIG

Claim 4 (Fig. 2). 30th

• The following numerical example makes this even more evident :

In the case of a heat transfer tube with an inner diameter of

21 mm and a wall thickness of 2 mm, pipe designation accordingly

25 χ 2, can have a heat transfer coefficient without a sinker

2 (based on the outer surface) of k = 1500 kcal / m hk is achieved will. With a temperature difference of 4 k with pure countercurrent this then results in a surface loading of

• 2

° t = 4 χ 1500 = 6000 kcal / mh based on the outer surface of the pipe or Q. = k χ F / F. = 6000 χ 1.2 = 7200 kcal / mh related ■ ι ι aa ι

on the inner surface of the pipe.

If one chooses the flow velocity with consideration of the pressure drop to W = 0.7 m / s then with the material values S = 1000 ks / m and C = I kcal / kg k as well as At = 27 k: L / d _i = 2362 and it

L = 49.6 m

This length of pipe cannot be accommodated in a single heat exchanger.

If, on the other hand, the displacement body according to the invention is used with an outside diameter of 18 mm, the length of the heat exchange pipe is shortened with the same surface area and the same flow velocity by a factor of 0.2 65 to an amount of 13.15 m can still be accommodated in a single apparatus.

The heat transfer value in the annular gap is increased by about 20 % compared to a heat exchanger tube without a displacement body, the heat transfer coefficient k increases by about 7% as a result. 30th

In order to be able to transfer a certain amount of heat, accordingly a lot of heat exchanger tubes are connected in parallel, the result is a short heat exchanger of the appropriate thickness compared to a thin long heat exchanger without a displacement body in the prior art.

-X- -1

• Of course, the displacement body also takes effect when a coolant flows through it. Merely for the sake of simplification, the term "heat carrier" was used in the foregoing, but the invention encompasses heat exchange tubes through which cold carriers or heat carriers flow.

As can be seen from the above, the inventive Training achieved a substantial shortening of the heat exchange tubes, so that they can be accommodated in a single apparatus let or the number of devices can be reduced, whereby the effort is reduced. As a side effect will in addition, the heat transfer is increased.

Claims (9)

Expectations lj heat exchanger, in particular tube bundle heat exchanger, with at least one heat exchange pipe (16) through which a heat transfer medium can flow, characterized in that at least one displacement body (24) is arranged in the heat exchange pipe (16) in such a way that the interior of the heat exchange pipe (16) is only in the the region bordering the pipe wall (28) can be traversed by the heat transfer medium. 2. Heat exchanger according to claim 1, characterized in that the displacement body (24) is rod-shaped and extends in the longitudinal direction of the heat exchange tube (16), 3. Heat exchanger according to claim 2, characterized in that the displacement body (16) is a polygonal, in particular has an approximately equilateral triangular or square profile, with the edges (34) of the profile on the inner Wall (28) of the heat exchanger tube at least partially supported and between the side surfaces (36) and the inner Pipe wall forms flow channels (Figure 3). 4. Heat exchanger according to claim 2, characterized in that the displacement body (24) has an approximately circular profile and between itself and the inner wall (28) of the heat exchange tube a flow channel in the form of an annular gap (32) forms (Figure 2). 5. Heat exchanger according to claim 4, characterized in that the displacement body (24) by radially extending, the spacer (26) penetrating the annular gap is supported on the inner wall (28). 6. Heat exchanger according to one of claims 2 to 5, characterized in that the displacement body is equiaxed is arranged in the heat exchange tube.
10 7. Heat exchanger according to one of claims 1 to 6, characterized in that the displacement body (24) as Hollow body is formed (Figure 1 and 2). 8. Heat exchanger according to one of claims 1 to 7, characterized in that the displacement body (24) for Derivation of axially acting flow forces in an axial direction Direction is supported. 9. heat exchanger according to one of claims 1 to 8, characterized characterized in that the displacement body (24) and optionally the spacers (26) are made of plastic.