HU188608B - Device for promoting the heat and/or material transfer between gas and fluid - Google Patents

Abstract

The present invention is a gas and liquid heat and / or material transfer device especially for cooling towers and degassers, wherein one medium, e.g. water flows vertically downwards, while the other fluid, e.g. air, vertically upwardly, and with the structure itself, the grid surfaces (1) of parallel and perpendicular vertical strips (1) and, on the other, vertical channel systems (2) formed of membrane-like plate strips alternately follow each other. Between two adjacent grid surfaces (1) there is the delicate channel system, which the grids protect from the external impact, but also ensure the liquid is distributed horizontally. Μ I I M e t t t 7. 7 -1

Description

The invention relates to a device for promoting heat and / or material transfer between a gas and a liquid, in particular for cooling towers consisting essentially of vertical lattice surfaces and a channel system.

In heat and metabolic processes between gases and liquids, the liquid is e.g. water and gaseous media, e.g. In order to achieve air-to-air contact, it is a common practice to guide the liquid through relatively fluid surfaces, preferably asbestos-cement sheets, by means of suitable liquid-spraying nozzles, while flowing the gas along the flat surfaces. On a large surface, the dripping liquid film thickens and the total mass of the dripping liquid is not intensively contacted with the upstream gas, e.g. air. A further disadvantage of this solution is that some liquid droplets can pass between the plates without contacting the plates. Finally, this solution has the disadvantage that asbestos cement sheets have to be made to a certain thickness for strength reasons, which increases the weight of the structure and the air-side resistance.

For this purpose, grid-like structures have been proposed, such as are described in Hungarian Patent Application No. 180,015. In a grid-like solution, more gratings are placed on top of each other, thereby interrupting the fluid film flowing from the top down to the grid from time to time, thus causing intense contact between the liquid and the gas. However, this solution also has the disadvantage of providing the grids with a certain thickness in order to ensure proper rigidity! however, an extension perpendicular to the direction of gas flow increases the gas resistance of the structure substantially, e.g. for cooling towers, either a larger fan or a higher draft chimney for natural draft towers should be used to move the air.

The object of the present invention is to provide a heat and material transfer device which does not suffer from the above-mentioned disadvantages, while ensuring an intense fluid-gas connection and thus good heat transfer. According to the invention, this can be achieved by alternating the film-like vertical channel system with very low gas-side resistance and the lattice surfaces for interrupting and distributing the liquid film. The passage of fluid between the grid system or channels is prevented by the channels alternating from bottom to bottom in a wave form and / or at an angle from 0 to 45 ° and / or vertically;

The invention thus provides a device for facilitating the transfer of heat and / or material between gas and liquid, in particular cooling towers and degassers, which have grid and sash-like contact surfaces. The invention is characterized by lattice surfaces consisting of parallel and perpendicular vertical slats on the one hand, and a rectangular or trapezoidal cross-section of bottom-up wavy and / or non-vertical and / or vertically perpendicular channels, on the other. The lattice surfaces employed support and protect the channel system consisting of a very thin sheet, preferably plastic, and the fluid distribution trough system at the upper edge of the lattice provides for the interruption of the fluid film flowing vertically downwards from the channel system and for re-distributing the fluid horizontally.

In a preferred embodiment of the invention, the size of the cross-sectional area of each channel of a parallel channel system, e.g. half or quarter. By such an arrangement, either each or every second or every fourth channel wall is located in the same direction below the vertical lath of the grid system. The bottom-up wave channels are formed so that they are lower and upper, i.e. the inlet and outlet sections are vertical. Similarly, the canal system has a vertical lower and upper entry section when it extends from the bottom upwards at an angle other than the vertical, i.e., when the parallel walls of the canal system are inclined at an angle greater than 30 ° to the horizontal.

The above measures are intended both to reduce the gas resistance of the structure and also to control the flow of top-down liquid.

It is also desirable to have waves, small turbulence-forming protrusions, which are perpendicular to the direction of fluid flow, on the walls of the channels of the channel system. However, the wall thickness of each channel is always less than 1 mm. Such a thin-walled structure with low projections is preferably made of plastic by vacuum forming.

The lower edge of the channel system may be horizontal, but it is preferred that channels that do not correspond to the grid surface divisions, i.e., which have a smaller division than the grid surface divisions, have their lower edges curved or oblique and facing the centerline of the adjacent lattice surface.

The lattice surface, which is an integral part of the structure according to the invention, which consists essentially of vertical slats, contributes to the good mixing between the liquid and the gas by the narrow liquid distribution trough system extending along the upper edge of the lattice slats. The trough system not only collects water from the sewer system above it, but also distributes the water horizontally in the event of uneven fluid distribution and compensates for any inequalities that result from the uneven operation of liquid spray nozzles over the entire heat and material transfer structure.

In a preferred embodiment of the lattice surfaces, at different points of the lattice surfaces, such as corners, legs that are contiguous or independent of the lattice surface have a height greater than the sum of the height dimensions of the channel system between two superposed lattice surfaces. The legs in question may be snapped into holes in the upper section of the grilles below them. The feet can thus form a compact heat and material transfer structure, the strength of which is formed by the lattice surfaces snapped together by the feet, and the lattice tops protect the channel system formed from very thin and fragile membrane plates with low gas resistance. Thus, the structure is an array with a grid surface at its lowest and highest planes, which protect the grid surfaces and duct systems alternating between them.

188 608 'It is possible to provide an embodiment of the structures in which the channel system is located above a grid surface, so that after the grid surface there is a channel system. Alternatively, it is possible that the duct system is partially or wholly within the grid subdivision.

It is a possible variant of the structure according to the invention that the overlapping channel systems can alternately be formed in a wave shape and formed at non-vertical angles or vertically extending channels.

The structure of the present invention will now be further understood from the embodiments illustrated in the drawings, wherein:

Fig. 1 is a cross-sectional view of a portion of the structure of the present invention in a wavy-channel system;

Figure 2 is a plan view or sectional view of the detail of Figure 1, a.

Figure 3 is a sectional view of an embodiment of a structure according to the invention with a non-vertical channel system;

Figure 4 is a sectional view of an embodiment of a structure according to the invention with a vertical channel system;

Figure 5 is a top view of the detail of Figure 4,

Fig. 6 is a schematic drawing of a possible embodiment of a complete heat and material transfer device according to the invention.

Fig. 1 is a cross-sectional view of a detail of the structure of the invention with a substantially lattice lattice surface 1 with a wavy parallel channel channel system 2 below, followed by a lattice surface 1 and a channel system 2 below. At the upper edge of the laths forming the lattice surface, a fluid distribution trough system 3 provides a horizontal distribution of fluid dripping from a channel system 2 guided from the direction or above a trough system, and a thickened liquid film on the wall of the channel system 2. The function of the structure is thus that from above the direction A, the liquid, e.g. water, while from below B the other medium involved in heat and metabolism is gas, e.g. air, flowing. The grid system at points suitably selected, for example, the corners contiguous or separate the grid surfaces are four projecting legs which is greater than the grating surfaces 1 m _r vertical size and the two channel system of _tube height with what height dimension of the sum. The legs 4 can be snapped into holes 5 formed in the upper part of the legs 4 of the grids 1 below them, which are provided by the pins 6 formed in the lower part of the legs 4. The figure also shows the possible turbulence-generating designs 9.

Figure 2 is a plan view or sectional view of the structure of Figure 1. On the right side of Figure 2, the plan view of the grid surfaces 1 shows that the gratings consist of parallel and perpendicular slats, the upper edge of which comprises the fluid distribution trough system 3.

2 is a plan view of the channel system 2 in the intersection plane below the grid surfaces 1 in the plane of the channel system 2. It can be seen that the channel system 2 is comprised of strips of sheet-like sheeting of thin film-like wall, generally less than 1 mm thick. The metal strips, so that the channel system 2 O _cs division, the embodiment of the drawing half the grid spacing _r O. Thus, the division of the channel system 2 corresponds to, is equal to or equal to the division of the lattice surfaces 1.

Fig. 3 is a sectional view of a possible embodiment of the device according to the invention, when the channel system 2, unlike the vertical, is approx. It extends to 45 °. Here, too, are the lattice surfaces 1 which follow each of the channel systems 2. Here, however, only the central section of the channel system 2 differs from the vertical, the lower and lower sections 7 and 8 of the channel system 2 being vertical, in order to reduce flow resistance and avoid sudden bending. There are 9 turbulence-forming protrusions.

Fig. 4 is a sectional view of another embodiment of the device according to the invention in which vertical channel systems 2 are located partially or completely between the grating surfaces 1 below.

In this solution too, the distribution O _{c of} the channel system 2 is based on the division O _{r of the} lattice surfaces 1, here half. Design solution in Figure 4. The special feature, however, also to the two channel system extends into the grid floats formulas 1 and so is less than the grating surfaces 1 m _r vertical size and the two channel system of _tube height with the two channel system of _tube height dimension, the sum.

Figure 4 also shows, on the wall of the side channel system 2, possible turbulence-generating projections 9 which are intended to further enhance heat and material transfer.

In Fig. 4, the tongue edge 10 of the bottom channel system 2 'is inclined and points in the direction of the center line of the adjacent grid surface 1.

Fig. 5 is a plan view of the structure of Fig. 4, again showing the channel system 2 and the arrangement of the turbulence generating projections 9, which are folded from very thin strips of ribs extending between the lattice surfaces 1 and the lattice surfaces.

Figure 6 is a schematic diagram of an embodiment of a complete heat and material transfer device according to the invention. It can be seen that there is a channel system 2 between the lattice surfaces 1 below each other, and on the suitably selected section of the lattice surfaces 1 in the example, the legs 4 are approximately joined together to form a complete array and thus mainly the lowest and highest lattice surfaces. protect the 2-channel systems formed from thin film-like strips.

Claims (13)

A device for promoting heat and / or material transfer between gas and liquid, in particular for cooling towers and degassers having lattice and sash-like contact surfaces, characterized by lattice surfaces consisting of parallel and perpendicular vertical slats, (1) a plurality of bottom-up waveforms formed of strips of rectangular or trapezoidal cross-section or / and channel systems (2) extending at an angle other than vertical or vertically extending. An embodiment of the device according to claim 1, characterized in that the bottom-up link 3 188608 system (2) the horizontal pitch _(cs 0) matches the grid surfaces (1) horizontal dividing _(r 0), equal to, half or quarter thereof. Embodiment according to claim 1 or 2, characterized in that the bottom and top sections (7, 8) of the bottom-up, wavy-channel system (2) are always vertical. Embodiment according to claim 1 or 2, characterized in that the wall of the channel system (2) extending from the bottom to the top at an angle other than vertical has a horizontal angle greater than 30 °, but the lower and upper sections of the channel system (2) (7, 8) vertical. 5. An embodiment of a device according to any one of claims 1 to 6, characterized in that there are turbulence-forming protrusions (10) on the membrane wall of the channel system. 6. An embodiment of a device according to any one of claims 1 to 3, characterized in that the channels of the channel system (2) have a wall thickness of not more than 1 mm. 7. An embodiment of a device according to any one of claims 1 to 4, characterized in that the leading edge (10) of the lower section (7) of the channel system (2) is curved or inclined. 8. Figures 1-6. An embodiment of a device according to any one of claims 1 to 4, characterized in that a fluid distribution trough system (3) extends at the upper edge of the grid surfaces (1). 9. Embodiment according to any one of claims 1 to 6, characterized in that the lattice surfaces 5 (J) extend into continuous or independent legs (4) having a height dimension (nij) greater than the height dimension (m _cs ) of the channel system (2) between the two lattice surfaces. and the sum of the height dimensions (m _r ) of the lattice surfaces. IQ Embodiment according to claim 8, characterized in that the legs (4) can be snap into holes (5) formed in the corresponding position of the grids below them. 11. An arrangement according to any one of claims 1-9, characterized in that a channel system (2) follows a lattice surface (1). 12. An embodiment of a device according to any one of claims 1 to 3, characterized in that the channel system (2) is partially or entirely divided by Is located between 20 (θτ). 13. An embodiment of a device according to any one of claims 1 to 4, characterized in that the superposed channel systems (2) can alternately be wave-shaped and then at an angle other than vertical. It consists of 25 formed or vertically extending channels.