WO2003008890A1

WO2003008890A1 - Moistening device

Info

Publication number: WO2003008890A1
Application number: PCT/DE2002/002225
Authority: WO
Inventors: Roland Weidner
Original assignee: Wegra Anlagenbau Gmbh
Priority date: 2001-07-14
Filing date: 2002-06-19
Publication date: 2003-01-30
Also published as: DE10134330C1; EP1407211A1

Abstract

The aim of the invention is to develop a moistening device for a heat exchanger with spiral shaped annular pipes which are arranged on top of each other which are not affected if the moistening device is not constructed in an exactly horizontal manner. According to the invention, the heat exchanger comprises spiral shaped annular pipes (9) disposed in the form of a bundle of pipes which are arranged on top of each other. The invention is characterised in that above the highest spiral shaped annular pipe (9) in the bundle of pipes of the heat exchanger, one or more spiral-shaped source pipes (1) are arranged and provided with source holes (2) disposed in the upper and/or lower half of the pipe. The spiral-shaped source pipe(s) (1) have the same radius distribution as the spiral shaped annular pipe(s) (9) of the heat exchanger disposed thereunder and cover(s) them along the whole length thereof. A plurality of inlets (3) are disposed on each spiral-shaped source pipe (1) and are connected together by one or more distribution pipes (4).

Description

Wetting device

The invention relates to a wetting device for heat exchangers with ring tube spirals arranged one above the other, for example for use in absorption refrigeration systems.

In many process engineering processes, in particular absorption and desorption in absorption refrigeration systems, the efficiency of the system is very much dependent on complete wetting of the tube bundle. In the prior art, trickling tanks or spray devices are used to wet the tube bundles in absorption refrigeration systems. This should be used to ensure that the tube bundles of the heat exchanger are wetted as evenly as possible.

However, the trickle troughs used to wet the tube bundle of the heat exchanger have the disadvantage that the small trickle bores which are introduced into the trickle troughs with great technological effort tend to clog in the operating state, since the solution used to wet the tube bundle with the solid particles carried in the solution only as a result of Gravity must pass through the trickle holes.

As a result of this blockage of the Rieselbohrungen an incomplete wetting of the tube bundle will inevitably take place, the less or non-wetted pipe sections not complete, or no longer in the heat transfer involved ^"are so affected more and more with increasing operating time of the plant efficiency The trickle trays in the containers must always be ideally horizontally aligned, since even small deviations in the horizontal alignment lead to a different level of the liquid level in the trickle tray, which results in an even wetting of the tube bundles inevitably severely impaired and a significant deterioration in the

System efficiency.

In order to ensure optimum maintenance of such trickle trays in addition to optimal fastening, both a high maintenance-friendly design and manufacturing effort and a high level of maintenance are required.

In order to eliminate the disadvantages existing with trickling tanks

Wetting the tube bundle used by heat exchangers spray devices.

The spray bores of these spray devices have to be aligned with high technological effort so that as little as possible

Liquid runs past the tubes, and that the tube bundle of

Heat exchanger are always wetted evenly.

This requires one such as that used, for example, in US Pat. No. 5,463,880

Spraying device, on the one hand, requires a great deal of construction, and on the other hand, due to the deterioration of the spray pattern associated with the wear of the spray nozzles and an inevitably associated deterioration in the system efficiency, it is also associated with very high maintenance and repair costs.

Another design of a spray device is described in DE 198 02 670 A1

Form of a centrally arranged nozzle for wetting a heat exchanger with ring tube spirals arranged one above the other.

But even with this design, in order to achieve an optimal efficiency of the

To ensure the heat exchanger, the spray device used there always generates a precisely defined spray pattern.

However, after a long period of operation, the above can also be used

Spray device due to wear on the spray nozzle bores no constant, exactly defined spray pattern can be guaranteed, so that Even with this design, the efficiency of the heat exchanger inevitably decreases depending on its operating time.

However, in order to counteract a deterioration in the efficiency of the heat exchanger even with this type of construction, regular repairs are required which, in addition to a maintenance-friendly design and an increased production outlay, also require a high maintenance outlay.

Another significant disadvantage of these wetting devices, which are described in the prior art and are used in heat exchangers in absorption refrigeration systems, is that the flow rate cannot be increased in a defined manner while ensuring uniform wetting at the same time, in order to optimize the wetting of the ring tube spirals of the heat exchanger arranged one above the other depending on To ensure the respective operating state and thereby achieve a significant improvement in the cooling capacity of the respective absorption refrigeration system.

The invention is therefore based on the object of developing a wetting device for heat exchangers with ring tube spirals arranged one above the other, which does not have the aforementioned disadvantages of the prior art, is insensitive to a not exactly horizontal installation of the wetting device, clogging of the liquid outlet openings by, for example, in the solution excluded solid particles, is characterized by a simple, robust construction, low manufacturing costs and simple assembly with a high level of functional reliability, also guarantees optimal efficiency of the heat exchanger over long periods of operation with minimal maintenance and, in addition, a defined increase in the flow rate at the same time guaranteed, more uniform Wetting the one above the other Ring tube spirals made possible in order to achieve a significant improvement in system efficiency.

According to the invention, this object is achieved by a wetting device for heat exchangers with the features of the main claim of the invention.

The wetting device according to the invention for heat exchangers with stacked ring tube spirals, in particular for use in absorption refrigeration systems, is characterized in that one or more source tube spirals with source holes arranged in the upper and / or lower tube half are arranged above the uppermost ring tube spiral of the tube bundle of a heat exchanger, and the source tube spiral (s) has the same radius profile as the underlying ring tube spiral (s) of the heat exchanger and cover / cover the entire length thereof, with several inlets being arranged on each of the source tube spirals, which are connected to one another via one or more distributor tubes are connected.

The multiple inflow from the distributor pipe (s) via the inlets into the source pipe spiral (s) ensures a uniform swelling pattern and thus an even sprinkling of the ring pipe spirals of the heat exchanger. It is also essential to the invention that the source tube spirals are arranged centrally above the ring tube spirals of the heat exchanger, and the outside diameter of the source tube spiral and its inside diameter correspond approximately to the outside or inside diameter of a ring tube spiral of the heat exchanger.

On account of this technical arrangement chosen according to the invention, the wetting device according to the invention is insensitive to a not exactly horizontal installation of the wetting device and is characterized by a simple, robust construction with high functional reliability, low manufacturing costs and simple assembly, the optimal arrangement due to the arrangement according to the invention of robust source tube spirals, preferably in connection with upwardly directed large source holes

Efficiency of the heat exchanger can be guaranteed over long operating periods with minimal maintenance.

The solution according to the invention enables a defined increase in the

Trickle strength with simultaneously guaranteed, uniform wetting of the ring tube spirals arranged one above the other, so that when this newly developed wetting device is used, a further noticeable improvement in the system efficiency can be achieved by increasing the trickle strength.

Even blockages in the swelling holes due to the coarser solid particles that may be carried in the wetting agent can be removed at any time by briefly varying the operating pressure of the wetting agent.

According to the source bores are dimensioned and spaced from each other so that in continuous operation in the source tube spirals

There is overpressure.

As a result of this overpressure, the swelling holes become smaller as they pass through

Solid particles are constantly flushed out so that no blockages can occur.

In addition, the constant system overpressure prevailing in the arrangement according to the invention at the same time brings about a uniform, independent of the exactly horizontal alignment of the source tube spiral

Wetting the ring tube heat exchanger.

The special design according to the invention of the source tube spiral (s) arranged above the ring tube spirals of the heat exchanger with the same

Radius course like the underlying ring tube spiral (s)

Heat exchanger, which covers them in their entire length / cover, ensures even wetting of all coil coils of the heat exchanger even with downward swelling holes. By means of a variation of the operating pressure of the wetting agent in the distributor pipe according to the invention, a uniform flow rate can also be varied in a defined manner in order to achieve a significant improvement in the cooling capacity of the respective absorption refrigeration system in conjunction with an optimization of the wetting of the ring tube spirals arranged one above the other by means of the wetting device according to the respective operating state of the ring tube heat exchanger to achieve. It is also characteristic that the source tube spiral (s) preferably has an integral number of turns, in particular for production reasons, with an inlet being arranged at the start and end points, and preferably after each full turn of the source tube spiral, and all inlets preferably via a manifold are connected.

This design of the solution according to the invention ensures a uniform, optimal loading of the source tube spiral (s) with minimal manufacturing and assembly effort.

Another feature of the invention is that the source tube spiral (s) are arranged on a frame above the ring tube spirals of the heat exchanger. The frame serves for an exact optimal positioning of the arrangement according to the invention above the ring tube spirals arranged one above the other in the heat exchanger.

It is also essential to the invention that, in special designs, an outer and an inner drip plate can be arranged on the frame such that the source tube spiral (s) and also the upper / n spiral tube (s) of the heat exchanger are limited on the inner and outer circumference. This arrangement of the drip plates according to the invention has the effect that, even with a very high wetting agent throughput, the entire wetting agent provided for sprinkling the ring tube spirals of the heat exchanger is directed exclusively over the ring tube spirals, whereby a high

Plant efficiency can be guaranteed.

It is also characteristic that above the source tube spiral / n one with the

Frame connected cover with the source tube spiral (s) associated

Flow guide grooves can be arranged, which in the upward direction

Well drilling even the very high operating pressures

Wetting agent, which then emerges in a jet from the nozzles upwards, is deflected in a defined manner in order to sprinkle the ring tube spirals of the heat exchanger.

In addition to the wording of the claims, further features, details and advantages of the invention also result from the following explanations of the

Embodiments.

Show:

Figure 1: the wetting device according to the invention without cover in section in a side view; Figure 2: the wetting device according to the invention without a lid in plan view; Figure 3: the wetting device according to the invention with a lid in the

Side view, in section perpendicular to the distributor pipe; Figure 4: the wetting device according to the invention with a lid in

Section in side view; Figure 5: the wetting device according to the invention with cover and

Side view of drip tray in section.

In FIG. 1, the wetting device with source tube spirals 1, inlets 3 and a distributor tube 4 is arranged above the ring tube spirals 9 shown a heat exchanger. The liquid used for wetting is conveyed into the distributor pipe 4 by means of a pump and fed to the source pipe spirals 1 via the individual inlets 3. The source tube spirals 1 are preferably in their geometric shape as well as one of the

Levels of the ring tube spirals 9 of the heat exchanger are formed and arranged symmetrically directly above this.

FIG. 2 shows the top view of the wetting device from FIG. 1.

This wetting device consists of two analogue, in one plane as

Double spiral arranged, on the upper side provided with swelling holes 2, robust swelling spiral 1.

Due to the arrangement of this wetting device immediately above the

Due to the continuous, jet-free "swelling" of the wetting agent from the upward swelling bores of the swelling pipe spirals, annular pipe spirals 9 of the heat exchanger become optimal wetting of the

Ring tube spirals guaranteed.

The two source tube spirals 1, which are arranged in one plane and start inwards at a point on the outer circumference, are around one another

Offset 180 °.

Each of the two source tube spirals 1 is arranged in the radial spaces between the other source tube spiral 1 and has an integer

Number of turns.

At the beginning as well as at the end points of the two source tube spirals 1 arranged one inside the other, as well as after each full turn, an inlet 3 directed upwards is arranged on the source tube.

All of these inlets 3 are arranged one inside the other in one plane

Source tube spirals 1 are connected to one another via a common distributor tube 4.

Because of this arrangement, a uniform, optimal loading of the two source tube spirals 1 arranged one inside the other is minimized

Manufacturing and assembly costs guaranteed. Both source tube spirals 1, as shown in Figure 2, on one

Frame 5 arranged.

This frame 5 serves for an exact, optimal positioning of the

Wetting device in the heat exchanger above the ring tube spirals arranged symmetrically one above the other.

This wetting device shown in FIGS. 1 and 2 is characterized by a simple structure and a low design, with high functional reliability

Manufacturing costs.

Due to the special source tube spirals, which are provided with source holes pointing upwards, and their arrangement directly above the

Ring tube spirals of the heat exchanger is a high efficiency

Heat exchanger for a long time even if the installation position is not exactly horizontal

Operating periods guaranteed with minimal maintenance and high cooling capacity.

Even blockages of the nozzles can be increased by a short time

Operating pressure of the wetting agent can be "blown free" again at any time, so that a continuously constant one with minimal maintenance

Cooling capacity of the absorption refrigeration system can be guaranteed.

In particular, as part of a maintenance-friendly

Construction to be observed, increased manufacturing costs for

Wetting devices are not required with this design.

The relatively large source bores 2 are spaced apart in their diameters and also dimensioned such that a continuous, jet-free upward swelling of the wetting agent from the source tube spiral occurs in continuous operation under an operating pressure that is optimal for the respective system.

Due to the variations in the operating pressure in the manifold,

Continuous operation of the volume flow of the wetting agent can be varied depending on the respective operating state so that an optimal one

Wetting of the ring tube spirals arranged one above the other with uniform Trickle strength is guaranteed, whereby a further, significant improvement in the system efficiency of the respective absorption refrigeration system can be achieved.

FIG. 3 shows the wetting device with a cover 7 assigned to it in a sectional view with a section perpendicular to the distributor pipe 4 in a side view.

The distributor pipe 4 is, as shown in this figure 3, with the

Source tube spirals 1 connected by the inlets 3.

The above the source tube spirals 1 with the frame 5 by means of several

The design of the screwed connection of detachably connected cover 7 is provided with flow guide grooves 8 assigned to the source tube spirals 1.

This provided with flow guide 8 cover 7 ensures

Source tube spirals with upwardly directed source bores, that even under very high operating pressures occurring in the source tube spirals 1, the wetting agent then emerging from the nozzles in a defined manner defines

Irrigation of the heat exchanger is deflected.

In FIG. 4, the wetting device arranged on a frame 5 is connected to the frame 5 by means of a screw connection 10

Cover 7, shown in section through the manifold 4 in side view.

After each full turn there is an inlet 3 from each of the two source tube spirals 1 (in this half section on one) of the two source tube spirals

Distribution pipe 4 arranged.

This multiple inflow into each of the source tube spirals 1 ensures a uniform source image with minimal manufacturing and assembly work, so that even at different operating pressures an optimal and uniform sprinkling of the ring tube spirals of the heat exchanger

Basic requirement for an improvement in the efficiency of the

Heat exchanger and thus the cooling capacity of the absorption refrigeration system can be guaranteed. FIG. 5 shows the wetting device in a symmetry section through the frame 5 and the cover 7 arranged on the frame by means of a screw connection 10. In this special embodiment, 5 drip plates 6 are arranged on the frame, which at least also the upper one

Enclose annular spiral 9 of a heat exchanger.

As can be seen from Figure 5, the source tube spirals 1 are centered over the

Ring tube spirals 9 of the heat exchanger arranged.

The outside diameter of the source tube spiral 1 as well as its

The inside diameter corresponds approximately to the outside or inside diameter of one of the ring tube spirals 9 of the heat exchanger.

The central arrangement of the specially dimensioned wetting device above the ring tube spirals 9 arranged one above the other

Heat exchanger ensures uniform wetting of all

Ring tube spirals 9 of the heat exchanger.

In order to ensure the functional reliability of the heat exchanger even under extremely high sprinkling levels, the wetting device is provided with an outer and inner drip plate 6, as shown in FIG.

This arrangement of the drip plates 6 causes that even at very high

Wetting agent throughput all for sprinkling the ring tube spirals

9 of the heat exchanger provided wetting agents exclusively via the

Ring tube spirals 9 is passed, whereby a high system efficiency can be guaranteed, so that even under extreme operating conditions, a high cooling capacity of the absorption refrigeration systems is guaranteed with high efficiency.

By means of the solution shown, one has thus succeeded

Wetting device for heat exchangers arranged one above the other

To develop ring tube spirals, which is insensitive to a not exactly horizontal installation of the wetting device, clogging the

Well drilling through, for example, larger ones carried in the solution Excludes solid particles, is characterized by a simple, robust construction, low manufacturing costs and simple assembly with a high level of functional reliability, also guarantees optimal efficiency of the heat exchanger over long operating periods with minimal maintenance and, in addition, a defined increase in the flow rate with constant, uniform wetting ring coils arranged one above the other enables a significant improvement in the overall system efficiency.

BezugszeJchenzusammenstellung

1 source tube spiral

2 swelling hole

3 inflow

4 manifold

5 frames

6 drip tray

7 lids

8 flow guide grooves

9 spiral tube

10 screw connection

Claims

claims

1. Wetting device for heat exchangers with ring tube spirals (9) arranged one above the other in the form of tube bundles, characterized in that one or more source tube spirals (1) are arranged in the upper and / or lower tube halves above the uppermost annular tube spiral (9) of the tube bundle of a heat exchanger Source bores (2) are arranged, the source tube spiral (s) (1) having the same radius profile as the underlying ring tube spiral (s) (9) of the heat exchanger and / or covering this over its entire length, with each of the source tube spirals (1) a plurality of inlets (3) are arranged, which are connected to one another via one or more distributor pipes (4).

2. wetting device for heat exchangers with stacked ring tube spirals (9), according to claim 1, characterized in that the source tube spirals (1) have an integer number of turns, at the start and end points of the source tube spiral (s) (1), as well as after an inlet (3) is arranged for each full turn, all inlets (3) preferably being connected to one another via a common distributor pipe (4).

3. wetting device for heat exchangers with superimposed ring tube spirals (9), according to claim 1, characterized in that the source tube spirals (1) above the ring tube spirals (9) of the heat exchanger are arranged on a frame (5).

4. wetting device for heat exchangers with stacked ring tube spirals (9), according to claim 1, characterized in that on the frame (5) an outer and an inner drip plate (6) are arranged such that the source tube spiral (s) (1) as well as the upper / n spiral tube (s) (9) of the heat exchanger are limited by these on the inner as well as on the outer circumference.

5. wetting device for heat exchangers with stacked ring tube spirals (9), according to claim 1, characterized in that above the source tube spiral (s) (1) with the frame (5) connected cover (7) with the / the source tube spiral (s) (1 ) assigned flow guide grooves (8) is arranged.