DE3030410A1 - Sprinkle-type heat exchanger - has distribution channel with slot-shaped wall opening and protrusions from bottom part - Google Patents

Abstract

The heat-exchanger is particularly for an absorption- refrigeration or heat-pump system, having a liquid-distribution channel (10) extending horizontally above the heat-exchange surface (12), openings being formed in the channel walls (28). The openings are slots (30) extending from top to bottom and ending short of the channel bottom (32). There are protrusions (34) on the bottom part of the channel walls, extending towards the heat-exchange surface. The slot width can be small in relation to the clear width of the channel, pref. in a proportion of between 1:10 and 1:20.

Description

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BRO W N, BOVERI & CIE AKTIENGESELLSCHAFT Mannheim 8 Aug 1980

Mp.no. 591/80 ZFE / Pl-Wg / Ma

Circulation heat exchanger

The invention relates to a sprinkling heat exchanger, in particular for an absorption refrigeration or heat pump system, with at least one liquid distribution channel arranged horizontally above the heat exchange surface, in which Channel wall openings are provided.

A known heat exchanger of this type has a horizontally running liquid distribution pipe above the heat exchange surface on. Nozzles are arranged in the pipe wall, which are aligned with the heat exchange surface. With this arrangement however, only then is a uniform application to achieve the heat exchange surface with liquid when the liquid is under pressure and with a constant mass flow rate Nozzles is fed. In the case of changing mass flows

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and / or in the case of an unpressurized inflow of the liquid and / or in the case of very small mass flows, an uneven loading occurs the heat exchange area, the efficiency the heat exchanger is reduced (US-PS 20 12 183). The known heat exchanger is therefore particularly suitable for absorption refrigeration and / or heat pump systems of low power, for example 5 to 20 KW, hardly suitable. Because here correspondingly small and changing refrigerant and absorbent flows are uniformly directed towards the heat exchange surfaces ■ distribute jO.

The invention is therefore based on the object of a sprinkling heat exchanger of the type mentioned in such a way that under all operating conditions, in particular

• J5, however, with low liquid flows, an even sprinkling the heat exchange surfaces. The effort required for this should be low, so that the sprinkling heat exchanger can be manufactured inexpensively. Furthermore should this be able to fully meet the requirements that arise in the company

The solution to this problem is according to the invention that the openings of the distribution channel are formed by slots which run in the channel wall from top to bottom and with End spacing in front of the channel bottom, and that the channel wall has projections in the lower area, which onto the heat exchange surface are aligned. The one in the longitudinal direction of the distribution channel Evenly distributed and equally designed slots act like overflow weirs,

3Q which are identical to one another depending on the fluid level Allow large amounts of liquid to escape. In order to ensure that this even discharge of liquid is uniformly applied, of the heat exchange surfaces are to be implemented in the deepest area the duct wall provided the outer projections. These act as dripping noses for the liquid and as a result

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the even distribution of the projections is in cooperation with the even supply of liquid the desired uniform application of the heat exchange surface is achieved through the slots. 5

In order to promote the even distribution of the supplied liquid on the individual slots, it is recommended that the slots each have a width which is small in relation to the clear width of the distribution channel, preferably in a ratio of 1:10 to 1:20.

A preferred development of the invention, according to which the individual slots are designed identically in a simple manner can be, consists in that the slots consist of incisions that are transverse, preferably perpendicular, to the longitudinal axis of the Distribution channel are arranged in the channel wall.

The slots are advantageously arranged inclined at an angle di of 45 to 70 ° to the longitudinal axis of the Verceilkanals. Compared to the vertical arrangement, the passage cross-section of each slot is enlarged, so that there is sufficient passage cross-section for the liquid even with larger fillings of the distribution channel.

If the heat exchange surface consists of one on top of the other, horizontally extending pipes, so can according to another advantageous development of the invention on the undersides the tubes each have further projections and be aligned with the next lower tube. This also means that in the Maintain the even distribution of the liquid in the area of the heat exchange surface «

• For the formation of the projections, which are arranged in the deepest area of the duct wall or the pipes, there are different Options. The easiest way to do this is that

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the projections are formed by a corrugation of the channel wall or pipe wall.

A "different, structurally simpler training regarding the projections consist in that they are formed by a serrated plate attached to the channel wall. Here are preferred the individual prongs arranged approximately below the deepest points of the individual slots »

Another recommendable formation of the projections consists in the fact that they are separated from the lower prongs one in the longitudinal direction of the distribution channel running zigzag-shaped wire, the upper prongs of which are at the deepest area of the channel wall are attached. In order to ensure that the liquid exiting the slots and running down the channel wall is uniform To be able to distribute on the projections, the attachment points of the upper prongs of the wire are each below the lowest point of the slots.

Very little construction effort requires a formation of the projections, which is characterized in that it is formed by a wire which helically encompasses the distribution channel is. Here, the arrangement is advantageously made so that below the deepest point of the slots each have a projection comes to rest.

Further advantages and features of the invention emerge from the following description of exemplary embodiments in conjunction with the schematic drawings. Here show: 30

Figure 1 is a vertical longitudinal section through a

irrigation heat exchanger according to the invention according to the section line I-I of Figure 2,

Figure 2 shows a cross section through the subject of

Figure 1 according to the section line II-II, wherein parts lying behind the cutting line are not shown.

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figure 3

the view of a section of the distribution channel as a detail and on a larger scale,

Figure 4

a section through the object of the figure according to the section line IV-IV,

Figure 5

an embodiment of the distribution channel in a representation corresponding to Figure 3,

Figure 6

a cross section through the object of Figure 5 according to the section line VI-VI,

Figure 7

Figure 8

a further embodiment of the distribution channel in a representation corresponding to FIG Figure 3,

a section through Figure 7 according to the section line VIII-VIII,

Figure 9 Figure 10

another embodiment of the distribution channel in a representation corresponding to Figure 3 and

a cross section through Figure 9 according to the section line X-X.

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

According to Figures 1 and 2, the sprinkling heat exchanger according to the invention, the horizontally extending and juxtaposed distribution channels 10, among which the heat exchange surface 12 is located. This consists of three double rows of horizontally extending tubes 14,16,18. The distribution channels 10 and the tubes 14,16,18 are each in a vertical plane. At the ends of the tubes 14,16,18 are

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vertically extending collecting channels 20 are provided which are provided with diagonally arranged connections 23.

A housing 22, which is approximately rectangular in cross section, surrounds the distribution channels 10 and the heat exchange surface 12 and closes the heat exchange space 24 to the outside. To fluid the distribution channels To be able to supply 10, upwardly directed nozzles 26 are arranged which penetrate the housing 22.

Each distribution channel 10 has in its channel wall 28 a series of slots 30 which are uniform in the longitudinal direction are arranged distributed. The slots 30 are narrow in proportion to the clearance of the distribution channel 10 and they each run at an angle cC of approximately 45 to 70 ° inclined to the longitudinal axis 33 of the distribution channel. The slots 30 extend in the tube wall 28 from top to bottom and end at a distance a in front of the channel bottom 32. This distance a is approximately one Fifth to one third of the clear width of the distribution channel 10. As can be seen in particular from FIG is, in the present exemplary embodiment the slots 30 consist of incisions made in the channel wall 28 are attached from above.

On the undersides of the distribution channels 10, which consist of pipes, there are projections 34 in the longitudinal direction in the deepest area of the distribution channels arranged one behind the other and evenly distributed. As can be seen in particular from Figure 2, run these projections 34 in vertical planes in which the distribution pipes 10 and the pipes 14,16,18 are arranged, the projections are thus aligned with these tubes. The projections 34 here have a vertical height that is equal to a maximum of about half the clear width of the distribution channels.

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The adjacent pairs of tubes 14 and 16 of the heat exchange surface 12 also point at their deepest Areas further projections 36, which are each aligned with the underlying tube. In terms of The explanations relating to the projections apply to the dimensioning and formation of these further projections36 34 were given.

During operation, the heat exchange surface 12 is through the Connections 23 are supplied with a heat exchange medium, for example cooling brine. The liquid used for sprinkling the Heat exchange surface 12 is provided, for example a liquid refrigerant enters the distribution channels 10 through the nozzle 26. As a result of the horizontal arrangement the distribution channels 10 and the uniform design of the slots 30, this liquid occurs in the longitudinal direction of the distribution channels evenly distributed through the slots 30. The liquid then runs as a film on the channel wall 28 down to the projections 34, from which it drips off and reaches the tubes 14.

A film of liquid is also formed here, which is attached to the The tube outer wall flows downward with heat exchange and through the projections 36 onto the tubes 16 arranged below where this game is repeated accordingly. Liquid that drips off the pipes 18 reaches the bottom of the housing 22 and is attached to a recess through a drainage port 38 discharged.

The interaction of the slots 30 with the projections 34 means that even small amounts of liquid are applied evenly the heat exchange surface 12 arranged underneath is distributed and this heat exchange surface is thus optimally used.

In FIGS. 3 to 10, sections from distribution channels with different design variants of projections 34 are shown in FIG larger scale in view or, shown in cross section »

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According to FIG. 3, the projections 34 are formed by corrugations 40 at the deepest point of the channel wall 28. These curls are approximately sinusoidal and have an amplitude of about one fifth to one tenth of the light width of the distribution channel 10. The downwardly directed deepest points 42 of the corrugation are in each case below the deepest point 44 of a slot 30. As a result, the liquid emerging from the slot 30 becomes passed in a trouble-free way to the point 42, from which it drips.

FIG. 4, which shows the section IV-IV through FIG. 3, shows the course of the slot 30 in the profile of the distribution channel. The slot 30 here consists of an incision which is not made horizontally in the pipe wall 38, but runs at an angle ρ to the horizontal. The depth of the incision is indicated here by the dashed line 46. Through this arrangement the liquid flows out of the distribution channel 10 only on one side, but there is the advantage of a more uniform exit of the liquid compared to a horizontal arrangement of the slot. In principle, however, the slot could also be arranged horizontally in the channel wall 28.

In the embodiment variant according to FIG. 5, a serrated plate running in the longitudinal direction is at the deepest area of the channel wall 28 48 is provided, the lower prongs 50 of which are each located below the deepest point 44 of a slot 30. That The profile of the serrated plate can be clearly seen in the cross section VI-VI, which is shown in FIG.

In the embodiment according to FIG. 7, instead of the serrated plate In FIG. 5, a wire bent in a zigzag shape is attached to the deepest region of the channel wall 28. The top Prongs 52 are here attached to the channel wall 28, on the other hand

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the lower protruding prongs 54 form the projections 34. The upper prongs 52 are each below the deepest Position 44 of the slot 30 arranged. The liquid emerging from the slots 30 thus passes over the upper prongs 52 on the zigzag bent wire 56, flows to the prongs 54 and drips off there. The cross section of the zigzag wire can be seen from Figure 8, which shows the section along the line VIII-VIII Figure 7 shows.

In the exemplary embodiment according to FIG. 9, the projections 34 are formed by the deepest points 58 of a wire 60, the Is wound helically around the distribution channel 10. The deepest point 58 is in each case arranged below the deepest point 44 of the slots 30. The wrapping of the The distribution channel 10 through the wire 60 can be clearly seen in FIG. 10, which shows the cross section X-X through FIG.

It is clear that any desired irregularity Acting on the heat exchange surface 12 by appropriate Arrangement of slots 30 and projections 34 can be achieved. As the number of slots increases and projections per unit length of the distribution channel 10 is an increasing impact on the underlying heat exchange surface achieved. A simple way is thus shown, such as a uniform and possibly non-uniform application the heat exchange surface of a sprinkler cooler can be achieved.

It should also be noted with regard to FIGS. 1 and 2 that the lowermost pair of tubes 18 can optionally be designed without projections 36. The thickness of the projections 34 and 36 is approximately 1/20 to 1/10 of the diameter of the associated tubes _t with a height of 1/3 to 1/10 of the diameter of the tubes.

Claims (4)

Mp. »No. 591/80 Aug 8, 1980 ZFE / Pl-Wg / Ma A η s ρ r ü ehe [1.1 Sprinkling heat exchanger, especially for a Absorption refrigeration or heat pump system, with at least one horizontally positioned above the heat exchange surface (12) .jQ arranged liquid distribution channel (10), in the channel wall (28) openings are provided, dadur ch marked that the openings are formed by slots (30) which run in the channel wall (28) from top to bottom and with End in front of the channel bottom (32), and that the channel ^ ₅ wall (28) in the lower area has projections (34) which are aligned with the heat exchange surface (12). 2. Sprinkling heat exchanger according to claim 1, characterized characterized in that the slots (30)% av; eils a Have width that is small in relation to the clear Width of the distribution channel 10, preferably in a ratio of 1: to 1:20. 3. Berieselungswämietauscher according to claim 1 or 2, _nr characterized in that the slots (30) are made of incisions, preferably perpendicularly, of the distribution channel are arranged in the channel wall (28) transverse to the longitudinal axis (33). _ΟΛ 4. Sprinkling heat exchanger according to one of claims 1 to 3, characterized in that the slots (30) are inclined at an angle d / of preferably 45 to 70 ° to the 'longitudinal axis (33) of the distribution duct. 8/8/1980 - 2 - 591/80 5. Sprinkling heat exchanger according to one of claims 1 to 4, characterized in that with a heat exchange surface (12) with horizontally extending tubes (14,16,18) arranged one above the other on the underside of the tubes (14,16) further projections (36) are provided and aligned with the next lower tube. 6. Sprinkling heat exchanger according to one of claims 1 to 5, characterized in that the projections (34,36) are formed by a corrugation (40) of the channel wall (28) or of the tube (14, 16). 7. Sprinkling heat exchanger according to one of claims 1 to 5, characterized in that the projections (34,36) are each formed by a serrated plate (48) attached to the duct wall (28) or to the pipe. 8. Sprinkling heat exchanger according to one of claims 1 to 5, characterized in that the projections (34,36) formed by the lower prongs (54) of a wire (56) bent in a zigzag shape, the upper prongs (52) of which each are attached to the deepest area of the channel wall (28) or the tube (14, 16). 9. 'Sprinkling heat exchanger according to one of the claims 1 to 5, characterized in that the projections (34, 36) from one of the distribution channel (10) or the pipe (14, 16) helically encompassing wire (60) are formed.