DE19905689C2 - Heat exchanger for a gaseous fluid - Google Patents

Description

The invention relates to a heat exchanger in which a gaseous fluid a number of to tube bundles summarized, closely spaced tubes in flows around a main flow direction, in the flow path the fluid is arranged at least one obstacle, the surface of which the fluid flows has turbulence in of fluid flow generated without changing the To cause the main flow direction of the fluid.

Gases of this type can be heated or can also be dried. For this purpose the gases at a certain speed by at least one Bundles of tubes arranged closely adjacent, which have a much higher temperature than that respective gas fluid. Depending on the requirement, several such tube bundles in the direction of flow of the fluid be arranged one behind the other so that they are separated from the fluid are flowed through in succession. That the pipes gas flowing around is released by the pipes Heat warmed.

When flowing through the tube bundle arise due to Turbulence in fluid flow noises. this applies especially if the Reynolds number (Re = u × d / ν; with u = flow velocity, d = pipe diameter, ν = kinematic viscosity of the medium) by the  Number of pipes predetermined flow conditions reached certain values. Under these conditions you can especially when the pipes are aligned the rows of tubes and behind the respective tube bundle stable vortex zones, similar to Kármán's Vortex street arise. Create such vortex zones tonal excitation frequencies or narrowband Excitation spectra. Depending on the channel geometry, these can be too Resonance phenomena lead to a considerable Cause noise pollution.

Another with the creation of spinal zones an accompanying problem is that the individual, in different densities of contact with the pipes coming and accordingly heated differently Partial flows of the fluid are insufficiently mixed become. As a result, only a limited amount Gas is heated so that the total fluid flow only a reduced amount of heat is supplied. On Heat exchanger, between the individual pipes or Pipe bundles vortex zones arise, therefore has one reduced efficiency.

To solve the problems discussed above have been proposed in front of the tube bundle obstacles Provide form of baffles through which the inflowing gas flow in a certain flow direction is distracted. This distraction can over the Cross section of the heat exchanger determined distribution of the speeds of the in the heat exchanger inflowing gas are equalized. To this  Way is an equally uniform flow of Pipes with the consequence ensures that the effectiveness of the heat exchanger compared to such heat exchangers that have no baffles, is improved. In practice has also shown that the installation of Baffles significantly reduce noise emissions to let.

Another suggestion to improve effectiveness of a heat exchanger by avoiding stable ones Vortex zones, the subject of so far not published patent application DE 198 37 677 exists therein, the pipes around which the fluid flows itself one to give appropriate form. This special shape can also avoid dead zones become.

In addition to the prior art explained above it is known from US 4,064,934 to a pivot axis in the Flow path of the fluid adjustable baffles to arrange a heat exchanger between two To be able to adjust operating modes. In the first In operation, the fluid flows through the heat exchanger direct path through in a straight line from the Flow path arranged openings without it at the Cooling tubes of the heat exchanger is passed. In the guide plates are in this operating state aligned substantially horizontally so that the fluid the openings in question can pass unhindered. In the second mode of operation guide the baffles to the Heat exchangers flowing essentially horizontally Fluid flow, however, twice around 90 °, so that he the  Flow through the cooling tube bundle and is cooled thereon, before leaving the heat exchanger again. The baffles are consequently in the state known from US 4,064,934 the technology exclusively for the targeted redirection of the Fluid flow depending on the selected one Operating state used.

The installation of baffles or the use specifically shaped tubes to improve efficiency and to reduce noise emissions have been found then difficult if existing systems, for example due to tightening Noise protection regulations are to be converted. Is too the interpretation of the shape of the respective obstacles or of the pipes, because, as mentioned above, the Emergence of stable vortices of both properties of the flowing fluid itself as well as structural Conditions depends.

The object of the invention is a To create heat exchangers in which the Increased efficiency and reduced noise emissions can be.

This task is based on a heat exchanger initially mentioned type solved in that a Adjustment device is provided, by means of which the position the surface of the obstacle that the fluid flows against is changeable.

According to the invention, the obstacle is designed that the location of its flowed surfaces by a  Adjustment device can be changed. Because of the location of the flowed surfaces in relation to the on them fluid flow hitting is through the obstacles caused change in the flow direction of the fluid and associated with the emergence of the turbulence in the essentially determines which the emergence of stable Prevent swirl zones.

According to the invention, the location of the surfaces concerned the obstacle by an adjustment device can be adjusted, the effectiveness of the Obstacles in operation can be optimized. this makes possible it, under realistic conditions that position to determine the areas of the obstacle which the meets the respective requirements. Should be one if possible high efficiency with minimized Noise emission can be achieved, so that of the Obstacle generated turbulence just adjusted be that on the one hand noises are avoided that on the other hand, the pressure loss at the obstacle is not gets too big. In contrast, there are particularly high requirements placed on the soundproofing, so the location of the Areas of the obstacle in favor of a stronger one Turbulence of the flow can be adjusted. Vice versa can be the location of the relevant surfaces of the obstacle can of course also be aligned so that a further improved effectiveness of the heat exchanger reduced noise protection is given.

Since in the respective optimization of the invention Heat exchanger inevitably both the structural as well by the properties of the fluid itself  given boundary conditions can be taken into account the optimal operating position can be found, without complex advance calculations or - planning is required. This fact makes it Invention particularly suitable for existing systems convert heat exchangers according to the invention to this Way to optimize their efficiency and their To minimize noise emissions if necessary.

One in terms of retrofitting existing systems is a particularly advantageous embodiment of the invention characterized in that the adjusting device is detachably coupled to the obstacle and that the location the areas of the obstacle regardless of the Adjustment device can be fixed. With such a The heat exchanger can be removed when the optimal operating position of the surfaces the obstacle is determined. That way they can Costs for the manufacture or retrofitting of such systems be reduced, with a one-off optimization due to no longer significant in further operation changing operating conditions is sufficient.

A particularly practical, cost-effective one Heat exchanger according to the invention can thereby establish that the obstacle by at least one yourself transverse to the longitudinal axis of the main flow direction of the fluid extending baffle is formed, which around his Longitudinal axis is pivotable. To improve the The effectiveness of the obstacle can also be several spaced-apart baffles available are. The effort for setting the location of the  Baffles can also be reduced by the fact that the baffles are hinged together. At this configuration is only an adjustment device required to locate the respective baffles to be able to change together.

Further advantageous embodiments of the invention can are taken from the description below, in which the invention based on an embodiment illustrative figures is explained. Show it schematic:

Figure 1 shows a heat exchanger in a longitudinal section.

Fig. 2 shows a detail of FIG. 1 in an enlarged view.

The heat exchanger 1 has a channel-like, rectangular housing 2 with an inlet 3 and an outlet 4 . Two tube bundles 5 , 6 are arranged in the housing 2 in the flow direction F one behind the other and at a distance from one another.

Each of the tube bundles 5 , 6 consists of tubes 7 a - 7 f, which are positioned in rows 8 a - 8 h of several tubes 7 a - 7 f in a plane arranged normal to the longitudinal axis Y of the housing 2 . In practice, the number of tubes 7 a - 7 f is much larger than shown in the figures.

In each case a certain number of rows 8 a - 8 h arranged in closely adjacent normal planes form one of the tube bundles 5 , 6 . A heating medium, for example hot water, flows through the tubes 7 a - 7 f and heats them up in the process.

In the flow direction F in front of and behind each of the tube bundles 5 , 6 , groups 9 , 10 , 11 , 12 of obstacles 9 a- 9 d are arranged. The barriers 9 a- 9 d of the groups 9, 10, 11, 12 each in the form of fins and are supported spaced from each other about its longitudinal axis X pivotable. The longitudinal axes X of the obstacles 9 a - 9 d belonging to one of the groups 9 , 10 , 11 , 12 are each arranged together in a plane which is also oriented normal to the longitudinal axis Y of the housing 2 .

The arranged in the flow direction F beyond the respective tube bundle 5, 6 groups of 10, 12 a- obstacles 9 9 are preferably only provided d, when the number of rows of tubes 8 8 a- h is greater than a threshold value.

The number of the obstacles 9 a- 9 d assigned to one of the groups 9 , 10 , 11 , 12 is dependent on the flow velocity or the Reynolds number of the gas flowing through the heat exchanger 1 , the diameter d and the distances L and H of the tubes 7 a- 7 f determined. In the present example, accordingly respectively obstacles a- 9 9 d groups 9, 10, 11 have been assigned, 12th It is from these obstacles 9a-9d, respectively a first pair 9 a, 9 b the upper three tubes 7 a- c 7 or a second pair 9 c, 9 d the lower tubes 7 d -7f been allocated.

The respective position of the longitudinal axis X of the barriers 9 a- 9 d in relation to their respective next adjacent tubes 7 7 a- f, its width l, and the distance b, which the obstacles 9 a, 9 b and 9 c, 9 d of the respective obstacle pairs to one another are also determined as a function of the flow velocity or the Reynolds number of the gas flowing through the heat exchanger 1 , the diameter d and the distances L and H of the tubes 7 a - 7 f.

At their front edge 9 f in the direction of flow F, the respective obstacles 9 a - 9 d of groups 9 , 10 , 11 , 12 are connected in an articulated manner to an adjusting rod 13 in each case. The respective adjusting rod 13 is guided through an opening of the housing 2 and is detachably coupled to an adjusting device 14 , 15 , 16 , 17 . The adjustment devices 14 , 15 , 16 , 17 are also releasably attached to the outside of the housing 2 and connected to an evaluation and control device, not shown.

To set the swivel angle α, in which the surfaces 9 e of the obstacles 9 a - 9 d, which are essentially swept by the gas, are aligned with respect to the gas flow, the obstacles 9 a - 9 d of groups 9 , 10 , 11 , 12 pivoted about its longitudinal axis X by raising or lowering the adjusting rods 13 . In this way, additional turbulence is generated in the gas flow. This prevents the formation of excitation frequencies, which would otherwise result from stable vortex zones, and thus prevents or reduces the generation of noise due to resonance phenomena. The increase in turbulence caused by the obstacles also leads to an improvement in the thermal efficiency of the heat exchanger, since the turbulence mixes the gas particles better and improves the possibility of the gas flow coming into contact with the surface of the hot pipes.

REFERENCE SIGN LIST

1

Heat exchanger

2nd

casing

3rd

Inlet

4

Outlet

5

,

6

Tube bundle

7

a-

7

f pipes

8th

a-

8th

h rows of pipes

7

a-

7

f

9

a-

9

d obstacles

9

e essentially swept by the gas Area of the obstacles

9

a-

9

d

9

f front edge of the obstacles

9

a-

9

d

9

,

10th

,

11

,

12th

Groups of obstacles

9

a-

9

d

13

Control rod

14

,

15

,

16

,

17th

Adjustment devices
α swivel angle of the obstacles

9

a-

9

d
b distance of the obstacles

9

a-

9

d
d diameter of the pipes

7

a-

7

f
F flow direction
l width of the obstacles

9

a-

9

d
L, H distance of the pipes

7

a-

7

f
X longitudinal axis of the obstacles

9

a-

9

d
Y longitudinal axis of the housing

2nd

Claims (10)

1. Heat exchanger in which a gaseous fluid flows around a number of tubes ( 7 a - 7 f), which are combined to form tube bundles ( 5 , 6 ), in a main flow direction (F), with at least one obstacle ( 9 a- 9 d) is arranged, the surface of which the fluid flows ( 9 e) generates turbulence in the fluid flow without causing a change in the main flow direction (F) of the fluid, characterized in that an adjusting device ( 14-17 ) is provided, by means of which the position of the surface ( 9 e) of the obstacle ( 9 a- 9 d) against which the fluid flows can be changed. 2. Heat exchanger according to claim 1, characterized in that the adjusting device ( 14-17 ) is detachably coupled to the obstacle (9a-9d) and that the position of the surface ( 9 e) of the obstacle ( 9 a- 9 d) is independent of the adjustment device ( 14-17 ) can be fixed. 3. Heat exchanger according to one of the preceding claims, characterized in that the obstacle ( 9 a- 9 d) is formed by at least one guide plate ( 9 a- 9 d) extending transversely to the longitudinal axis (Y) of the main flow direction (F) of the fluid . 4. Heat exchanger according to claim 3, characterized characterized in that the baffle by Swivel axis (X) is pivotable, which is perpendicular to Longitudinal axis (Y) is arranged. 5. Heat exchanger according to claim 3 or 4, characterized in that a plurality of spaced-apart baffles ( 9 a- 9 d) are present. 6. Heat exchanger according to claim 5, characterized in that the guide plates ( 9 a- 9 d) are connected to one another in an articulated manner. 7. Heat exchanger according to claim 4 and one of claims 5 or 6, characterized in that the pivot axes (X) of the guide plates ( 9 a- 9 d) are arranged parallel to one another in a plane perpendicular to the main flow direction (F). 8. Heat exchanger according to one of the preceding claims, characterized in that at least one obstacle ( 9 a- 9 d) is arranged in the flow direction (F) of the fluid in front of the tube bundle ( 5 , 6 ). 9. Heat exchanger according to one of claims 1 to 7, characterized in that a plurality of tube bundles ( 5 , 6 ) through which the fluid flows in succession are provided and that in each case an obstacle ( 9 a- 9 d) in front of the respective tube bundle ( 5 , 6 ) is arranged. 10. Heat exchanger according to one of claims 8 or 9, characterized in that a further obstacle (9a-9d) is arranged behind a tube bundle ( 5 , 6 ).