NL8005180A - Evaporative water-air cooler - demister of high efficiency increases heat transfer - Google Patents

Abstract

The cooler consists of at least one horizontal Venturi-tube with its associated spray jet device or individual jets respectively, a downstream mixing chamber, an air outlet arrangement including demister and a sump for the recovery of the water. The spray jet device covers the throat of the Venturi by a multitude of elliptical diverging jets provide the pumping action and bring about effective mixing of air and water. The demister consists of a multitude of shaped vertical strips and a arrests the water by impingement onto its baffled surface. The film running to the sump is additionally cooled contributing to the overall efficiency of the system.

Description

- 1 - N.O. 28,761

Division of patent application 71 * 08352, Ned. , filed 17-1-1971.

- Evaporation heat exchanger -

The invention relates to an evaporative heat exchanger comprising a housing with an air inlet, an air outlet and a substantially horizontal flow path with a throat disposed therebetween, spray nozzles for spraying water into that throat, and a water collecting tray arranged near the air outlet .

In heat exchangers of this type, the air is drawn in through the water spray patterns emerging from the nozzles. A water seal is formed over the throat. The air drawn in intimately mixes with the water droplets. Evaporative cooling takes place because part of the water evaporates and the necessary evaporative heat is extracted from the rest of the water. This rest falls into the water collection bin. It is important that an efficient separation between air and water is established near the outlet of the house.

According to the invention, for this purpose, spraying means are provided near the water basin, consisting of an assembly of elongated strips arranged parallel to and at a distance from each other, each having two flat edge parts and an intermediate curved central part.

Such a design of the nebulizers causes a very small air resistance. A good separation contributes. that the 20 surfaces of the strips are wet during use. The separated under the water can flow freely in the water container located in the misting elements.

At high supply speeds of the mist, there could be a risk of it being partly driven by the misting elements without complete separation having taken place. To significantly reduce this hazard, at least a first group of strips may extend substantially perpendicular to the horizontal, while at least a second group of strips located downstream of the first defines a gap with that first group.

Preferably, said second group is angled relative to the vertical to define a vertical cross-section between the two groups.

The invention will now be explained in more detail with reference to the figures, in which two exemplary embodiments are shown.

Fig. 1 shows a vertical longitudinal section of a heat exchanger according to the invention.

Fig. 2 shows an end view of that heat exchanger.

A fl n κ 1 o λ - 2 -

Fig. 3 is a sectional view taken on the line III-III in FIG. 1.

Fig. 4 shows a vertical longitudinal section of one slightly modified embodiment.

Fig. 5 shows a section of the haze removal means in 5 section.

The device of Figure 1 has a housing with a mouth 10 for admitting air, a throat 11, and a diffusion or expansion zone located downstream of the throat 12. Water to be cooled is supplied from a vessel 13 to a number of horizontal conduits 14, each of which is provided with nozzles 15 which are spaced apart along the longitudinal dimension of the respective conduit. Water is sprayed through the nozzles 15, thereby drawing air into the mouth 10 of the device. In a manner to be described further, the distances between the nozzles 15 are chosen and 15 the shape of the jets from those tubes is such that a water seal is established over the throat 11. The air which is drawn into the mouth 10 and which goes through the throat 11, intimately mixes with the droplets of water. The flow continues through the diffusion zone 12. Cooling by evaporation takes place, because part of the water 20 is evaporated and the heat of evaporation is extracted from the remaining water, which flows from left to right in fig. 1 into a collection container 16, from where it is extracted by the pipeline 17

Air is exhausted from the tower by a group of nebulizers 18, which separate any remaining water, so that air substantially free of droplets of water is exhausted from the devices 18 to the outside air via blades 19 · These blades ensure that the air flows up from the cooling tower, avoiding recirculation of hot exhaust air to the area of the mouth 10. The vanes 19 also have the task of counteracting the action of strong crosswinds, 30 which can counteract the air flow through the unit. Under certain circumstances, these blades can be omitted.

It can be seen from FIG. 1 that the top wall 20 of the diffuser section 12 has a different slope from the bottom wall 21, while the side walls 22 are vertical as shown in FIGS. 2 and 3. This has been done to advantage. draw from the action of gravity on the way of the water streams coming out of the nozzles 15. Due to the action of gravity, the upper expansion angle, ie the angle between the horizontal and the upper limit 20 of the expansion zone 12 of the tars, is smaller than the lower expansion angle, which is the angle 40 between the horizontal and the lower limit 21 of the expansion zone 12 8005180 -3- ψ * of the tower. By thus arranging the walls 20 and 21, the greatest possible effect of expanding the air-water mixture is ensured, as well as the greatest possible contact between water and air.

It should be noted that the entrance to the mouth 10 is in the form of a clock to reduce air resistance. The top wall 23 at the defining edge of the mouth is curved, as shown in Figure 1. A trough 24 defining the bottom edge of the bell-shaped mouth has a narrow slit, at 24 ', which extends over the full IQ width of the mouth 10, but sufficiently narrow not to affect the incoming airflow. This gutter 24 is connected at its left end, as shown in Fig. 2, with a pipe 25, which is connected to a sewer discharge pipe 26.

All evaporative cooling towers require some amount of the recirculating water to be drained to the sewer to prevent excessive build-up of mineral salts.

In the present construction, the lower supply conduit 14 to a nozzle (see Fig. 2) is connected by a conduit 27 to the end of the trough 24 which is opposite the end to which the discharge 2Q of the trough 24 is attached. This means that water discharged from the system is hot water, ie, part of the water supplied to the tower for cooling, and this water flows over the entire bottom of the air inlet mouth so as to discharge the discharge pipe. thing to achieve. Thus, this warm water is in heat exchange with the metal of the trough 24 and by conduction with neighboring metal parts. When the turret is closed and the water is drained from the pipes 14, part of it falls into the region of the slot 24 'in the gutter 24. To ensure this takes place, small protrusions 28 are located under each of the nozzles 15 present (see fig. 1, 4 and 5). The protrusions 28 can be provided with a single piece of metal extending in the longitudinal direction of the conduit 14, or they can be separate pieces under each nozzle. In all cases, the position and length are selected in such a way that influencing of the air flowing in is avoided. These protrusions 28 have the task of preventing water from escaping from the mouth 10, so that finally leakage water from the nozzles is taken up somewhere along the length of the slot 24 '.

In winter, during standstill or operation, leaking water entering slot 24 'is prevented from freezing by the heat of the water flowing through conduit 27 and gutter 24 ft onr 1 fi n - 4 - to the drain lines 25 and 26. This hot water prevents freezing when the water is drained from the collector after shutdown.

The amount of water required to prevent ice build-up is very small and can possibly be discharged to the drain pan without significantly affecting the capacity of the tower. The heat exchange effect of the blowdown water in the gutter 24 is useful in winter weather even when the water collector is not discharged after shutdown, because it keeps the lower part of the throat warm and prevents icing.

The drain pipe 26 is connected to an elbow 28 'and a short pipe 29, which protrudes into the drain pan above the water level. This short pipe 29 has a dam 30 at one end, which dam is sufficiently high that water coming from pipe 25 does not flow over the dam, but if there is an error in the regulation of the water level or if there is blockage in the main cold water outlet 17, flooding water is discharged. These details are shown in Fig. 11.

The drain pan is provided with the usual sieve 31 and a water supply 32, which is controlled by a float 33. When the water level drops below a certain height, the falling float 33 will open a shut-off valve 32, after which additional water is supplied to the system.

Figures 1, 2 and 3 illustrate a baffle 12a, which is used with units of significant width to prevent cross-flowing wind from displacing misty water droplets so that they escape from the air inlet end of the unit. Although a single bulkhead is drawn, it should be noted that the number of bulkheads may be a function of the width of the unit. Baffle 12a extends from a plane tangent to conduits 14 slightly beyond throat 11 (see FIG. 1).

The nozzles 15 are spaced relative to each other along the respective pipes 14 so that the side edges of the spray lips touch each other approximately in the throat (see Figure 2). Air drawn into the mouth 10 flows between the various water jets, but the lock formed in the throat 11 is so complete that under normal operating conditions there is no tendency to blow back air.

The mixture of water and air flows to the nebulizers 18. The high flow rate of air and water makes the work 40 that the nebulizers have to do very difficult. In Fig. 1 8005180 - 5 - two sets of such devices 18 are used, which are used for average amounts of water flowing through per unit time and average pressures. In some applications, where the nozzle pressure is very low or the amount of water flowing through per unit of time is smaller than average, a single row of atomizers can be used to separate water droplets from the air. Usually, however, the speeds in the heat exchanger are greater than those that a single row of atomizers can handle. The speed of the water exiting the nozzles is very high and this water collides in large quantities with the first set of vanes. Therefore, the first face and a large portion of a second are fully wetted to then continue to act as a normal wet surface, which can contribute to heat transfer in cooling water and obtain very small differences between the temperature of the discharged water and 15 that of exhaust air. This is of course very important to obtain the greatest possible heat transfer and the best useful effect, especially with a heat exchanger with parallel flow.

The design of the de-misting devices can be seen from fig.

3 and 5.

The drawn construction provides a very effective misting device with a very low air resistance. Since the device is wet, the surfaces also act as a wet surface. Both of these features contribute greatly to a high thermal useful effect of the device.

The devices are arranged such that the bottom edges remain open for free drainage of water to the drain pan 16 (see Fig. 1).

Under temperature conditions that allow for very large amounts of water to be used, two units of deaerators of FIG. 3 may not be sufficient to separate entrained water from the air stream. When the amount of water supplied per unit time is increased, the supplied energy will be increased proportionately, with the result that the amount of air flowing per unit of time is considerably higher. An apparatus for controlling large volumes of water is shown in Fig. 4. This figure shows a heat exchanger which is basically the same as that of Fig. 1, with the exception of the deaerating devices. Fig. 4 shows three rows of nebulizers 34, 35 and 36. In cross-section, each has the same shape as that shown in Fig. 5. Due to the action of gravity on the flowing water in the diffusion zone 12, it is clear that at the time the water is in 8005180

Claims (3)

1. Evaporative heat exchanger comprising a housing having an air inlet, an air outlet and an essentially horizontal flow path therebetween with a throat, spray nozzles for spraying water into that throat and a water collecting tray disposed near the air outlet, characterized in that that for the separation of air and water 8005180-7, nebulizers are provided adjacent to the basin, consisting of an assembly of elongated strips arranged parallel to and spaced from each other, each having two flat edge portions and an intermediate curved central portion. j- Evaporative heat exchanger according to claim 1, characterized in that at least a first group of strips extends substantially perpendicular to the horizontal and at least a second group of strips located downstream of the first, with a spacing between said first group limited. 3. Heat exchanger according to claim 2, characterized in that said second group is placed at an angle to the vertical to define a triangular interspace between the two groups. 15 ---------- 8005180