NL8500033A - Heat exchanger using liq. drip contact with pipes carrying medium - in housing where drip liq. supply tube has openings and is surrounded with clearance by mantle having transverse capillary gaps over pipes - Google Patents

Abstract

The heat exchanger comprises a housing containing (horizontal) pipes to transport a medium and means to produce heat transfer by supplying a liquid in the form of drops on to the pipes. These means comprise liquid (22) supply tubes (13) with small openings (21) longitudinally spaced in their walls and mantles (18) which surround the tubes with clearance over most of their length and are provided with narrow transverse gaps (20) such that the liquid (22) passing through the openings (21) collects (23) in the lower part of the mantles and passes (24) through the gaps through capillary action. The mantle may consist of rings (18) axially pressurised to leave only capillary gaps between them. If the tube is e.g. 150 cm long with 20 mm outside diameter, the rings preferably have an internal diameter of 22 mm and 10 mm width.

Description

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V.0. 6640 -1-

Title: Heat exchanger

The invention relates to a heat exchanger, comprising a housing and a number of transport members running through the housing for transporting a medium through the housing, as well as means arranged in the housing for dripping the transport members with a liquid supplied by those means.

Such a dripping heat exchanger is generally known and is used, for example, as an absorber or as a desorber or evaporator in an absorption-resorption heat pump. A liquid or a gas flows through the conveying means for a suitable medium, which can for instance take the form of tubes or hollow plate-shaped elements. The liquid, for example water, in which ammonia gas is dissolved drips onto these transport members. When used as a desorber or evaporator j, when this liquid comes into contact with the transport members j, gas is released from the liquid. This requires heat, which is pulled on the medium which is passed through the transport members.

The liquid thus depleted is discharged from it in a suitable manner, for instance via a pipe at the bottom of the heat exchanger. The released gas is for instance discharged via a pipe connected at the top of the housing of the heat exchanger.

When used as an absorber, gas is fed into the heat exchanger via a suitable pipe. This gas is absorbed in the liquid dripping on the transporters, whereby heat is released, which is dissipated by the medium which is passed through the transporters.

The thus enriched liquid is again discharged therefrom in a suitable manner, for instance via a pipe at the bottom of the heat exchanger.

A number of constructions are already known for dripping.

A construction is a flat plate with a large number of openings in it. Liquid supplied above such a plate drips down through these openings. The disadvantage of such a plate with holes is that the plate must be arranged horizontally, because otherwise the liquid flows to one side and dripping only takes place on one side, because the openings are on the higher side! the plate will be "dry". It has also already been proposed to use an 8500033 i -2- * \ container with openings at the bottom, through which the liquid is passed under pressure. With such a construction, pressure differences occur in the container, as a result of which more liquid is often forced through the openings in the bottom on one side than on the other side.

The object of the invention is to provide a device in which dripping can take place in a very uniform manner, so that the transport members are dripped in almost the same way everywhere. The object set is achieved according to the invention with a device 10 in which the means for dripping consist of a pipe or tube, in which small openings are arranged at suitable distances from each other, through which liquid supplied by that pipe or pipe outside that pipe or pipe can emerge, as well as from a sheath arranged over the major part of the length of pipe or tube, which sheath has inner dimensions which are larger than the outer dimensions of the pipe or tube and which sheath is provided with a number of slits which are substantially transverse to the axis of the conduit or tube, which are sized such that liquid exiting the conduit or tube and entering the inner surface of the jacket 20 can exit the jacket by capillary action through those slits. In the device according to the invention, in operation, the supplied liquid first drips on the inner surface of the jacket at different locations, depending on the locations where openings are made in the pipe or tube. Even if the drip member is not horizontally disposed, this still leads to an even dripping of the transport members under the drip member, since a drop, at least an amount of liquid, which has landed on the inner surface of the jacket then in the adjacent gap or crevices. Since the slits are substantially transverse to the axis of the pipe or tube, a flow of liquid over the inner surface of the jacket to one side when the element is not horizontal is largely avoided. The regularity of the dripping is further promoted in that the drops emerge from the dripper without pressure.

In a preferred embodiment of the device according to the invention, the jacket is built up from a number of annular elements, 8500033 i J.

The annular elements being held against each other such that only capillary gaps exist between the elements.

Suitably, the annular elements can be held pressed to the end or ends of the number of elements by means of one or more spiral springs. In an embodiment of the device according to! In the present invention, a tube of about 150 cm in length and an outer diameter of 20 mm was used, further using annular elements with an inner diameter of 22 mm and a width of about 10 mm.

In another suitable embodiment of the device according to the invention, the jacket is constructed from a spiral-wound material strip, which winding is such that only a capillary gap exists between adjacent parts of the wound strip.

In both above-mentioned embodiments, a wire or other suitable arrangement may suitably be arranged between the conduit or tube molded body are arranged to maintain a fixed distance between conduit or tube and jacket at the location of that body. In addition, that body and the pipe or tube may consist of one piece. The body may, for example, be in the form of an upright edge or collar extending in the longitudinal direction of the pipe or tube. When such a body is used, the annular elements can already be held in place so firmly that a spring for pressing of those elements is superfluous. When the device according to the invention is used as an absorber or desorber in a system in which water with ammonia is used as medium, the pipe or conduit of the dripper may consist of stainless steel, aluminum or another suitable material.

The casing of the dripping member can then consist of Teflon or another suitable material which is not attacked by the medium used.

The invention will be elucidated with reference to the drawing, in which: Fig. 1 is a cross-sectional view of an embodiment of the device according to the invention; 8500033

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Fig. 2 shows a cross-section of the device according to Fig. 1 taken along the line II-II; fig. 3 shows a cross-section of a part of the device according to fig. 1, taken along the line III-III; Fig. 4 shows a detail of the device according to Fig. 1; FIG. 5 is a cross-sectional view through part of the dripper in the apparatus of FIG. 1; FIG. 6 is a section through the dripper of FIG. 5 taken along line VI-VI; and FIG. 7 shows a similar section to that of FIG. 6 of another embodiment of the dripper.

The figures are the same parts with the same reference numerals.

The embodiment of the device according to the invention shown in Figures 1 and 2 comprises a cylindrical housing 1, which is closed on either side by a tube plate 2, respectively. 3. Between the pipe plates 2 and 3 a large number of pipes or pipes run through the housing. 4. In operation, a suitable medium is transported through the pipes 4, with which heat can be supplied to or removed from the device, depending on the device as evaporator or if absorber is used. In the illustrated embodiment, 45 pipes 4 are used in a block-shaped arrangement of five pipes wide and nine pipes high.

Via the pipe plate 2, the pipes 4 open out into a rectangular collecting chamber 5, which is sealed and sealed outside the pipe plate 2, and which is divided into a number of compartments by partitions 6.

A supply line 7 for the transport medium opens into the bottom compartment of the collection chamber 5.

Via the pipe plate 3, the pipes 4 open into a rectangular collecting chamber S, which is sealingly attached outside the housing 1 to that pipe plate 3, which is also divided into a number of compartments by partitions 9. A discharge conduit 10 for the transport medium opens into the upper compartment of the collecting chamber 8. As can be seen from Figures 1 and 2, the division of the collecting chambers 5 and 8 is by means of the partitions 5 and 5, respectively. 9 in such a way that medium which is supplied via line 7 is led in a zig-zag-wise manner through pipes or lines 4 to higher-lying compartments of the collecting chambers until the medium can finally be removed via line 10.

The liquid with which the system of pipes or pipes 4 is to be dripped into the housing 1 is supplied via a pipe 11, 5 which connects to a block-shaped distribution chamber 12 in the present embodiment. A number of pipes or pipes 13 run through the distribution chamber 12. the pipe sheet 2 to within the housing 1. The number of pipes 13 is preferably equal to the number of columns of pipes 4 in the device and the pipes 13 extend in the housing 1 such that a pipe is preferably located above each vertical series of pipes 4 or tube 13.

The tubes or pipes 13 each form part of a dripper for dripping the pipes or lines 4. For this purpose the pipes 13 reach to the tube plate 3, where they are supported.

The end of each pipe 13 is closed on the side of the pipe plate 3. A possible construction is shown in detail in fig.

4. At the location where a pipe 13 ends near the pipe plate 3, a pipe stub 14 is welded to the pipe plate 3. Fig. 4 shows the welding bead 15. The end of the pipe 13 rests in the pipe stub 14.

2U The end is sealed by means of a suitable plate 16 fixed in that end, for example by welding (shown in welding bead 17).

A casing consisting of rings or segments 18 of a suitable material, for instance teflon, is fitted around each of the pipes or pipes 13. At the end of the pipe 13 near the pipe plate 3 the last ring 18 rests against the pipe stub 14. The rings 18 are pressed against each other by means of a spiral spring between the last ring on the side of the pipe plate 2 and that tube sheet. The pressing of the rings or segments 18 is such that only a capillary gap 20 exists between adjacent rings.

In each of the conduits or pipes 13, apertures 21 are spaced appropriately from one another within the jacket formed by the rings or segments 18. Fluid 22 supplied through conduit 13 exits through conduits 21 outside conduit 13 and forms a layer on the inner surface of the jacket formed by the rings or segments 18, as indicated at 23 in FIGS. 5 and 6. Through capillary 8500033

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Slits 20 penetrates the liquid 23 and drips therefrom, as indicated by the arrows 24 in Fig. 5. The action of the dripping member thus built up is self-regulating to a certain extent. As more liquid 23 gets on the inner surface of the mantle 5, a larger part of each capillary slit 20, which slit runs all around, is used to drain that liquid again, so that droplets are formed more quickly under the mantle and from there fall on the underlying pipes 4.

Fig. 7 shows a variant of the dripping member according to Figs. 5 and 6. In this variant, a filamentary body 25 is arranged between the conduit 13 and the segments or rings 18. As a result, the rings 18 are properly held in place and cannot move in the plane of their cross section, so that no leaks can occur. The wire 25 can be fixedly connected to the conduit 13. Instead of a wire 25 use can also be made of an upright edge which is fixed to the pipe 13 in the longitudinal direction.

The liquid introduced into the housing through the drippers is collected at the bottom thereof and can be drained from there via a tap 26 or similar mechanism. Likewise, at the top of the housing 1, one or more taps 27 or similar mechanisms are provided for venting vapor or gas released from the liquid or for introducing gas or vapor into the housing in order to pass that gas or vapor through the liquid into the housing 1 absorb. All this will depend on the purpose for which the device is used, either evaporator or desorber or absorber.

It will be clear that in the device according to the invention the jacket of the dripping member does not necessarily have to be constructed from annular segments. The jacket can also be built up from a spiral-wound strip of material, provided that the winding is such that only a capillary gap is present between adjacent parts of the strip. Also, ring-shaped in connection with the segments of the jacket is not to be understood as merely a shape with a circular cross-section. Another cross section is of course possible. It is only important that in the mantle, how. 8500033 -7- are also constructed, a relatively large number of capillary gaps are present so that dripping occurs as evenly as possible over all transport lines arranged below the dripping members.

In the above-described embodiment, the transport pipes 5 are in the form of pipes or tubes. Plate-shaped or differently shaped transport pipes are of course also possible.

8500033

Claims (7)

A heat exchanger, comprising a housing and a number of conveying members running through the housing for transporting a medium through the housing, as well as means arranged in the housing for dripping the transporting members with a liquid supplied by these means, with the characterized in that the means for dripping consist of a conduit or tube, in which small openings are arranged at suitable distances from each other, through which liquid supplied by said conduit or tube can escape outside said conduit or tube, as well as an overwhelming majority part of the length of conduit or tube casing disposed around it, which casing has inner dimensions greater than the outer dimensions of the conduit or tube and which casing includes a number of slits that are substantially transverse to the axis of the conduit or tube which are sized such that liquid exiting from the conduit or tube is deposited on the inner surface of the jacket comes through capillary action through those slits outside the jacket. 2. Heat exchanger according to claim 1, characterized in that the jacket is built up from a number of annular elements, the annular elements being kept pressed together such that only capillary gaps exist between the elements. Heat exchanger according to claim 2, characterized in that the annular elements are pressed together by means of one or more spiral springs at the end of the number of elements. Heat exchanger according to claims 2-3, characterized in that when using a tube with a length of the order of 150 cm and an outer diameter of 20 mm, annular elements with an inner diameter of 22 mm and a width of approximately 10 mm are used. 5. Heat exchanger according to claim 1, characterized in that the jacket is built up from a spiral-wound material strip, which winding is such that only a capillary gap exists between adjacent parts of the wound strip. 8500033 -9- Heat exchanger according to claims 1-5, characterized in that a wire-shaped or otherwise suitably shaped body is arranged between the pipe or tube and the jacket in order to maintain a fixed distance between the pipe or tube and jacket at the location of that body. Heat exchanger according to claim 6, characterized in that the body and the pipe or tube consist of one piece. ] 8500333