DE2050303A1 - Cooling tower - Google Patents

Description

The invention relates generally to mechanically and naturally generated traction Water cooling towers, and particularly one uncommon advantageous and economical cooling tower construction, which compared to known cooling tower constructions with a significantly higher water cooling capacity works.

In the cooling towers in use up to now, working with mechanical and natural drafts, lattice-shaped floors or packings are used to let the water run off and spray it, so that it can be cooled in a finely divided state by air currents which in a flow through the grids or packings in a generally horizontal direction. The floors or decks forming the packs normally extend uninterruptedly along each side of such a cooling tower in order to cause all of the air to flow from the outside of the cooling tower through the packs into the interior of the cooling tower - this arrangement has so far been used for the most economical cooling tower construction maintained, and it is believed that this design allows a very

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economical cooling method to be used. Here was for example, assume that with a gapless arrangement of the packs along the or each side of the cooling tower, a maximum value of the ratio between the effective contact area and the required floor space; under The contact surface is understood here to mean the available wetted surface of the pack, that of the air entering is exposed, while the term "floor area" denotes the floor plan area covered by the cooling tower.

However, it has been shown that the construction and

the mode of operation of the cooling towers that have been used up to now and that work with aecha W nisch generated train lead to certain difficulties and that these cooling towers do not work economically in every respect. For example, the length of the sections provided with the packings or fillings is limited to the length of the circumference of the cooling tower, so that the water cooling capacity of such a cooling tower is limited to a value which is below such a value; If blowers are arranged on the outside of such a cooling tower, the amount of packing or filling material is reduced as a result of the arrangement of the individual packing sections near the outlets of the ffleblase, so that the air flows unevenly enter the packing sections that in cold weather the There is a risk of the blower icing up as a result of the splashing of water droplets, and that there are unused gaps between the packing sections.

The invention has for its object to provide a with mechanical or produced naturally Z _u g operating cooling tower construction in which are avoided "culties the difficulties mentioned above and other non-mentioned difficulties, the inventive construction at the same time considerable advantages Provides that make it possible for a given cooling capacity to manage with a smaller base area of the cooling tower, whereby according to the invention it is effected that the air enters the interior of the cooling tower

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occurs in the form of a spiral or helical flow, and wherein the cooling tower can be operated at lower cost. Generally speaking, the E _x 1 invention provides a cooling tower construction that includes a set of fans spaced around the vertical axis of the cooling tower, and channels spaced around the cooling tower axis which are in the path of the fans conveyed gas are arranged, numerous packing sections, which are distributed around the axis mentioned at intervals and are arranged in the gaps between the channels so that their inlets are accessible from the outside and their outlets open inside the cooling tower, partition walls that the Gesstrom so introduce into the packing sections after the channels have taken in gas so that the resulting stream swirls about the axis of the cooling tower, and supply means for supplying water or other liquid, which is distributed in the packing sections, to flow through the gas flow passing through the sections to be cooled down. As a result of this arrangement, the channels cause the gas streams emitted by the blowers to be uniformly supplied to the pack sections and at the same time protect the G bubble from the water sprayed in the vicinity of the packs in order to prevent the blowers from icing up. Furthermore, the construction according to the invention makes it possible to accommodate regulating devices, doors or the like so that the supply of air to the cooling tower can be regulated as is necessary for operation in cold weather. The jacket of the cooling tower can be designed as a straight circular cylinder or as a botation hyperboloid or have another regular geometric shape.

In a typical construction according to the invention can the cooling tower must be provided with a certain number of upright partition walls, which are in the spaces between the pucking sections extend and serve for this purpose, the Forcing air into the packing sections via their inlets

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enter and inside the pack sections in lateral Direction to flow? these partitions extend 25.B. diagonally between the outer boundaries of the exit sides of the packing sections and the inner boundaries of the Entry sides of the packing sections so that they are the desired Generate helical flow. As can be seen from the following description, the fans are at a typical construction on the circumference of the cooling tower outside the spaces between the packing sections so arranged that they give off air currents in the direction of the diagonal partitions. Furthermore, the cooling tower construction can further Comprise partitions which cover the packing sections at their outer and inner ends.

To the further advantageous features of the invention includes the fact that fan shrouds are provided, each extending from the circumference of a fficbläses in such a direction on the adjacent packing portion that they form the cooling gas leading diffuser that further packing portions are provided which are in the form of a round ring are arranged around a vertical central axis, with their longitudinal axes extending generally radially, that in the channels or spaces between adjacent packing sections deflecting members or guide vanes are provided which are shaped so that they convey the gas conveyed by the blower to the "'Packing sectionsetL direct that air is provided can flow past the fans into the ducts when the fans are not in operation, so that the cooling tower with natural traction that water supply means can be operated are provided which include a water basin, which over the packing sections and the intermediate Spaces is arranged, with the basin only over the Packing sections are provided with water distribution openings • that an arrangement is provided that includes pipelines, which are provided with water outlets arranged to deliver water to the basin so that the water through the basin via the packing sections and

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the spaces in between flows away, and that under another basin in the trees between the packing sections is arranged, which serves to receive water coming from the P ;. ckungs sections in the form of 'splashes in the spaces entry. The operability of the known natural draft cooling towers, usually one Hyperboloid in shape is largely due to the moisture-containing air inside the cooling towers being a has a lower density than the ambient air, so that a train is generated and the air is set in motion For the pail, that the condition of the ambient air is unfavorable, so that there is no pulling effect that is sufficient to achieve the desired cooling effect cause the invention, however, sees Hj_lfsgebläse that make it possible to bring about the necessary air movement and to convey sufficient amounts of air. The use of fans can also be used to reduce the size of a cooling tower, if only a limited floor area is available.

The invention and advantageous details of the E _r invention are explained in more detail below with reference to schematic drawings of exemplary embodiments.

Pig. 1 shows a side view of an embodiment of a Kyhl tower according to the invention, which is based on mechanical Path generated Zg works.

Pig. 2 is part of the layout of the Pig cooling tower. 1, which has been partially broken away, to add more To make details recognizable.

Pig. 3 is an enlarged section along the line 3-3 in Pig. 2.

Pig. Figure 4 is an enlarged fragmentary section taken along line 4-4 of Pig. 2.

Pig. 5 shows a part of the K _o nstruktion according Pig in an enlarged side view. 2 when looking at the same

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from line 5 * -5 in Figure 2.

Fig. 6 is an enlarged partial section along the Line 6-6 in Fig. 2.

Fig. 7 shows schematically in plan a part of a modified embodiment of the invention. .

Figure 8 is a schematic plan view of one Part of a further modified embodiment.

In Fig. 1 to 6 one recognizes an according to the invention, a total of 10 designated water cooling tower with mechanically generated train works, and with the air in a horizontal direction in the lower part of the interior of the cooling tower is conveyed into it, whereupon the air in a chimney 11 in the form of an upright cylinder with a central axis 10a rises upwards. The chimney 11 is 1 in the form of a grid construction, and it has like the annular lower part 12 of the Cooling tower has a circular plan shape. Although it is said in the following that an air stream is used to cool finely divided water, it should be noted that it is within the scope of Invention is also possible to use a different gas and or other liquids to cool.

The cooling tower comprises a larger number of packing sections receiving the water to be cooled, each of which has an inlet side and an outlet side, the two sides being separated by a lateral distance generally in the longitudinal direction b-zw. are separated from each other in the direction of the bottom of the cooling tower. Referring to FIG. 2, the P have ckungsabschnitte 13 in a typical embodiment a rectangular Gründrißform, and their inlet sides separately 13a are shown the U _m circumferential direction by a distance of their outlet ends 13b. Furthermore, the packing sections 13 are arranged in the form of a ring around the vertical central axis 10a of the cooling tower so that they through

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Interstices 14 are separated through which air can be supplied to them. The air conveyed into these interspaces or channels 14a is deflected so that it flows through each of the packing sections 15 in the direction from its inlet side 13a towards its outlet side 13b and, after leaving the packing sections, is received by rooms 14b from which it enters the interior 100 of the cooling tower crosses. I _n Fig. 2 is the general course of the air streams indicated by arrows 15. According to FIG. 2, each air flow passing through a packing section 13 has a component 15a of considerable size which runs concentrically with the circumference of the cooling tower in the horizontal direction, so that the air flows entering the interior of the cooling tower and moving around the central axis 10a have a Induce whirling motion. This inevitably caused flow, which moves upwards along a helical path, leads to an increased mixing of the moisture-carrying air or gas, so that the density of the air or gas is reduced and the air or gas is stronger Effort shows to climb up in the cooling tower. With a typical construction, the

ο the condition of the air flow the condition of a turbulent Approximate the flow so that a closer contact between air and water is brought about; as a result, increases the degree of warmth of the escaping air, which increases the water cooling capacity is increased.

Partitions or guide elements are provided in the channels 14, to cause the incoming air to enter the packing sections 13 on the inlet side thereof and to flow through the pack sections in the manner described in the lateral direction. For example, perpendicular arranged partition walls 16 may be provided, which extend in a diagonal direction between the outer ends 17 of the outlet sides 13b of the packing sections 13 and the inner ends 18 of the inlet sides 13a of the packing sections. In addition, there are vertically arranged partition walls 19 and 20

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provided to the packing sections 15 on the outside or to cover the inside. These partitions can be Extend the full height of the packing sections to prevent air from flowing over the inner and outer ends of the Pack sections escapes.

In a typical construction, the similar packing sections 15 have one in the radial direction elongated shape, they extend horizontally inward, and the product of the total radial length of a Packing section and the number of sections provided exceeds the e.g. ^ along the circumference of the lower T.ils 12 of the cooling tower measured circumferential length, which is determined by the circumferential length of the pack sections on their outside and the number of pack sections. As a result, the invention enables a significantly higher value of the compared to cooling towers of known type To achieve the ratio defined above between the usable area and the ground plan area of the cooling tower.

5 and 6, fans 50 are in the form of a ring spaced around the central axis 10a; according to FIGS. 1 and 2, the fans are opposite the inflow channels 14a offset outwards and oriented in such a way that they inevitably Promote air into the ducts when the fan rotors are driven by the associated motors 51. Consequently the fans are arranged at a substantial distance from the packing sections 15 in order to prevent the rotor blades from icing up which could otherwise be caused by splashed water in cold weather. The channels 14a also have the effect that the air currents are supplied to the packing sections more evenly. The one with L..ufer ~ blades 52 provided fan 50 can opposite the ducts 14a be arranged so that air can flow freely through the fan into the channels when the The fan is not in operation, so that in certain weather conditions it is possible to use the cooling tower as an alternative '

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to operate only with natural pull. For example, the Cooling tower air over the spaces 33 (Fig.1) of the fan » blades are supplied, or the fan housing can be designed so that air can flow past the fans. The fan motors 31 can be arranged according to FIG. 6 on frames 34, each of which has a foot 34-a and a cross-piece 34b includes. .

The fan 30 can each have a venturi-shaped Sheath 35 be provided, the one receiving the (ffebläseläufer narrowest cross section 36 and a diffuser section 37 delimits in which the air flow expands until it reaches the whole vertical cross section of the associated channel 14a fills out. The jacket 35 can for this purpose according to FIG. 5 have an elongated shape in the direction of the vertical and towards the upper edge 381 <len lower edge 39 and the vertical side edges 40 and 41 of each channel 14a diverge.

Fig. 7 illustrates the use of additional deflection elements, e.g. The air currents given off by the blowers to the pvc sections feed evenly. In addition, control flaps or the like can be provided so that the air supply, e.g. when it is cold Weather can be regulated. As an example, FIG. 8 shows control elements 75 in the casing 35 with the aid of axes 76 are rotatably mounted.

According to Figs. 1 to 4, a liquid, e.g., water, is arranged to be supplied and in the packing sections 13 can be distributed to be cooled by the air flowing through the packing sections; with a typical In the construction, the water falls down in the form of small drops that hit the intermediate floor surfaces or strips and form a film of water on them. The intermediate floor or fillings can be designed in the most varied of ways;

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Jig. 4 shows, for example, a tightly filled section 13, such a filling, the parts of which are inclined downward in the direction of flow of the air indicated by the arrow 15, so that the water droplets tend to fall down within the pack at a corresponding angle against the solder. The parts of the tower structure which support the filling or packing comprise columns 55 »connecting members 56 and inclined struts 37» Near the outlet side 13b of each packing an upright droplet catcher 58 is arranged to prevent water droplets from being entrained by the exiting air flow.

So that the water to be cooled can be supplied, a hot water basin 60 (FIG. 4) is provided according to the drawings, which extends over the packing sections 13 and their spaces 14a and 14b. According to FIG. 3, the hot water can be pumped from a feed line 61 made of concrete via a riser pipe 62 upwards to a pipe or pipe 63 which, according to FIG. 2, extends inwardly transversely to the basin 60. The basin 60 has numerous outlets 64, each of which can be controlled by a separate valve 65; these outlets are arranged so that they leave the water to the tank 60, which is designed as an open channel, so that the water flows in the longitudinal direction of the basin via the ^Lg: length of the basin are distributed at intervals groups 66 of distribution apertures 67 which serve to supply the water to the packing sections 13; Above the spaces 14 between adjacent pack sections 13, the basin is not provided with such openings so that no water from the basin can get into the spaces 14 used for supplying air. Any water that ricochets off the packs and still gets into the chambers 14 falls into a collecting basin 69 at the Βε-sis of the cooling tower, and since the rooms 14 are inside the cooling tower, no blinds need to be provided. to hold back that splash.

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To complete the description, it should be mentioned that a catwalk 71 is provided over the pipeline 63 is and another catwalk 72 along the inner Edge of the basin 60 extends.

Claims;

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Claims (1)

PATENT A NSPE U CHE Λ.) With a mechanically generated draft cooling tower for cooling a liquid with a vertical axis, characterized by a set of fans (30) distributed around the vertical axis (10a) at intervals and offset outwards relative to the axis, wall means defining a set of channels (14a) which are spaced around the aforementioned axis and are arranged in the flow path of the gas conveyed by the fan and extend towards the interior (100) of the cooling tower (10), several P distributed at intervals around the axis mentioned; gaps (13) j which are each arranged in the gaps between the channels, with their inlet side (I3a) facing one of the channels, while their outlet side (13b) communicates with the interior of the cooling tower, the wall means dividing walls ( 16), which feed the Gc'S conveyed by the fan to the packing sections after flowing through the channels in such a way that the direction of flow of the gas has a component (15a) extending at an angle to the vertical axis, so that the gas after leaving the P Packing sections inside the cooling tower along a helical path flowing upwards around the vertical axis, and supply means (60) for supplying a liquid which is distributed in the packing sections to be cooled by the gas flow passing through the packing sections. 10981 8/1376 2. With a mechanically generated train cooling tower with a generally circular horizontal cross-section and a vertical axis, geke η η ■ ζ eic hn et by several upright packing sections (13) arranged in a ring at U catch intervals with an open inlet side (13a) and an open outlet end (13b) which are separated in the general calibration below the U _m fangs of the cooling tower (10) by a lateral distance, wherein said packing sections in said calibration Tung separated by distances and distributed around the vertical axis (1oa) around so that the gas moves the packing sections between the inlet side and the outlet side in such a direction j flows through that the flow has a significant component (15a) which runs parallel to the U direction of the catch, τη and wherein the packing sections are also offset radially outward from the vertical axis, perpendicular arranged partition walls (16), which in the spaces (14) of the packing sections are arranged and each diagonally between the outer ends (17) of the outlet sides of the Packing sections and the inner ends (18) of the inlet side of the packing sections extend so that they cause the gas to along a helical path around the vertical To flow around axis after the gas passes the packing sections and on the inside of the packing sections entered the interior (100) of the cooling tower (10) " is, with further partition walls (20, 19) at the ends lying radially further inward and those lying radially further outward Ends of the packing sections are provided in order to prevent the escape of gas at these points, several fans (30), which are arranged ao that they deliver pressurized gas to the .Räume (14a) on the inlet side of the packing sections release so that the packing sections are inevitably flowed through by the gas, as well as supply means (60) for supplying a liquid which is distributed in the packing sections in order to flow through the packing sections Gas to be cooled, with the flow of gas 1098 18/1376 along the helical path to a reinforced Mixing of the moisture-containing gas leads, so that the density of the ^ ases reduced, whereby the endeavor of the gas to rise in the cooling tower is enlarged. 3. Cooling tower according to claim 2, characterized in that the fan (30) on the circumference of the cooling tower (10) are arranged in such a way that they guide the gas conveyed through them against the diagonal partitions (16). 4. Cooling tower according to claim 3, characterized by * fan shrouds (35) »each of which differs from the circumference of the relevant fan from in the direction of the adjacent pack portion (13) extends so that it has a gas diffuser forms. 5. Cooling tower according to claim 4-, characterized in that the fan jacket (35) in the vertical Direction have an elongated shape. 6. Cooling tower according to claim 4, characterized in that the fan (30) directly outside the Spaces (14) are arranged between the pack sections (13). 7 · Cooling tower according to claim 3j, characterized in that in the mentioned spaces (14a) radially arranged inside the fan (30) are elongated, vertically extending guide vanes (44) which are shaped in such a way that that the gas flows to the corner sections (13) respectively. 8. Cooling tower according to claim 1, characterized in that g e k e η η ζ e i ch η e t that the fan (30) rotor blades (32) and are installed in relation to the associated ducts (14a) so that a Gf: s through the fans in can flow into the ducts when the fans are not in operation. 10 9 8 18/1376 9 · Cooling tower after. Claim 4, characterized through control flaps (75)> those in at least one fan jacket (35) "are movably arranged and allow the entering To regulate gas flow. 10. A natural draft cooling tower having a vertical axis for cooling a liquid characterized by a set of circumferentially spaced fans (30) distributed around the vertical axis (10a) and offset outwards with respect to this axis, Wall means defining a set of channels (14a) distributed around the vertical axis and directly in the flow path arranged of the gas conveyed by the fan are and extend in the direction of the interior (100) of the cooling tower (10), several at intervals around the vertical Axis distributed Ρε-backing sections arranged in the spaces between the channels (13)> whose kinlaßseiten (13a) face the associated channels, and their outlets (I3 "b) are in communication with the interior of the cooling tower, wherein the wall means comprise partitions (16) arranged to pass the gas conveyed by the fans over the Feed channels to the packing sections so that the direction of flow of the gas has a component (15a) which is below at an angle to the vertical axis so that the gas after exiting the packing sections inside of the cooling tower flows upwards along a helical path around the vertical axis, and supply means (60) for supplying a liquid which is distributed in the packing sections in order to flow through them Gas streams to be cooled. 11. With natural train operable cooling tower with a generally.kreisrunden horizontal cross-section and a vertical axis, geke η η ζ eic h η et by several upright arranged, circumferentially spaced, a ring-forming packing sections (13) with open inlet sides (13a) and open outlet sides (13by ₃ the general 1098 18/1376 in the direction of the perimeter of the cooling tower (10) through lateral ones Distances are separated, the packing sections in the Circumferential direction at intervals around the vertical axis distributed and arranged so that aie flow direction of the gas flowing through the packing sections between the inlet side and the outlet side has a considerable relative to the U ^ circumferential direction parallel component (15a), the packing sections also opposite the vertical axis are offset radially outward, perpendicular partition walls (16) in the spaces between the pack sections and extending generally diagonally between the outer ends (17) of the outlet sides of the packing sections and extending the inner ends (18) of the inlet sides of the packing sections to cause the supplied gas to to flow around the vertical axis along a helical path after it has passed the packing sections has happened and has entered the interior (100) of the cooling tower, with further partitions (20, 19) on the radially further inward ends and the radially further outward ends of the packing sections are provided to to prevent the escape of gas at these points, several fans (30), which are arranged so that they can be underneath Supply pressurized gas to the spaces (14a) on the inlet side of the packing sections so that the packing sections ^ are inevitably flowed through by the gas, as well as supply means (60) for supplying a liquid which is in the Packing sections is distributed to through which they ■ penetrate ücsströmme to be cooled, the flowing of the Gfc-ses along the screw! Linear Bi, Im a reinforced Mixing the moisture-containing Geses causes so that the density of the G; It diminishes and the desire to climb the cooling tower increases. 12. Cooling tower according to claim 11, characterized geke η η - \ is characterized in that the fan (JC) to U _m fang of the cooling tower are arranged (10) so as to direct the extracted gas to the diagonal partition walls (16). 10 9 8 18/1376 13. Cooling tower according to claim 12, characterized by blower jackets (35) »which thus differ from the scope of the the Gubläses (30) extend from in the direction of the adjacent packing section (13) that they form gas diffusers. 14. Cooling tower according to claim 13, characterized in that the fan jackets (35) in the Eichtung Verticals have an elongated shape. 15 · Kühltmäpm according to claim 13, characterized in that the fan (30) directly outside the spaces (14) are arranged between the packing sections (13), 16. Cooling tower according to claim 12, characterized in that elongated in the vertical direction Leitschaufelη (44) in the spaces (14a) radially inside the Air blowers (30) are arranged and shaped so that they control the gas flows lead to the packing sections (13). 17. Cooling tower according to claim 10, characterized in that the fan (30) Lauferschaufein (32) and are incorporated in relation to the ducts (14a) so that a gas passes through the fans into the ducts can occur when the fans are not in operation. 18. Cooling tower according to claim 13, characterized by ttegelklappen (75) or the like, which can be moved in at least one fan jacket (35) are arranged and in addition serve to regulate the incoming air flow. 1 0 9 8 18/13 7 6 Blank page