US20150276318A1

US20150276318A1 - Cmu cooling tower and method of construction

Info

Publication number: US20150276318A1
Application number: US14/670,796
Authority: US
Inventors: Ronald J. Marks; Mark B. Spring; Davin O. Spring
Original assignee: Ronald J. Marks; Mark B. Spring; Davin O. Spring
Current assignee: Syntech Towers LLC
Priority date: 2014-03-28
Filing date: 2015-03-27
Publication date: 2015-10-01

Abstract

A cooling tower structure and method of construction using multiples of standard concrete masonry units (CMUs) properly reinforced, using standard CMU construction methods and specifications, and using block masons of ordinary skill, costing less for construction and maintenance, requiring less heavy equipment, less transportation and lifting of heavy and large components, a smaller construction work site, and requiring significantly less time to construct and make operational.

Description

BACKGROUND OF THE INVENTION

This invention provides a method of constructing water cooling towers using concrete masonry units (CMUs) more quickly, at lower cost, requiring no heavy construction equipment, resulting in a more durable, fire-resistant, longer lasting and easier to maintain structure than is presently known.
Water cooling towers are well known, and are a common heat-exchange component in large commercial, medical, and industrial HVAC systems, in cooling for industrial processes, and aeration of water for other purposes. Cooling towers are a standard part of new construction of buildings or campuses of buildings. Many existing buildings also need replacement or supplemental cooling towers because of the inadequacy of present cooling towers due to increased demands, higher temperatures, consolidation into campus-wide HVAC systems, or deteriorating performance of existing cooling towers.
An under-performing cooling tower can be a large problem for commercial properties, medical facilities, and industries, affecting the efficiency and therefore the operating costs of HVAC and industrial systems, and affecting the comfort and therefore the satisfaction, health, and productivity of persons. Under such circumstances, existing cooling towers need to either be replaced or be supplemented with new cooling towers. But replacement requires taking an existing cooling tower out of service and waiting for the construction of a new cooling tower to be completed. And supplementation requires finding a new location for the new cooling tower, and then waiting for its construction to be competed.
One common type of industrial cooling tower is a counterflow tower where water falls by gravity through fill media from water nozzles positioned in the upper part of the cooling tower. A water collector pan is positioned below the fill layer. The water is directed to a downstream water basin, from where it is re-circulated back into the spraying nozzles on top. A source of moving air is mounted on or in the cooling tower, directing the cooling air toward the water.
Cooling towers exploit the evaporative cooling of water exposed to air. Therefore they are generally located outside. Cooling towers must provide a very large surface area for water to interact with air. Therefore cooling towers are very large structures—with at least a 20-square-foot footprint and at least 10 feet of height—and some many times that large. Powerful motorized fans are generally required to provide adequate air flow. Water is heavy, and powerful fans are heavy, and therefore cooling towers are heavy structures when in use, and the basic structure of the cooling tower must be capable of withstanding the internal forces of the heavy moving water and heavy moving fan, and the external forces of the outside environment.
Cooling towers must be located outside, take up a lot of space, can be noisy, and might generate some mist or vapor. They are typically placed on the roofs of high-rise buildings or in otherwise out-of-the-way locations on the grounds or the campus. Such locations present problems in the construction and installation of cooling towers. A heavy crane might be necessary—for months—in order to lift construction materials or pump concrete onto a rooftop or into an inaccessible area at ground level. There might be very little adjacent “laydown” or staging area for construction crews, materials, and equipment.
Industrial cooling towers made of wood in the traditional way are susceptible to fire and to rot and early deterioration in the constantly wet cooling-tower environment, requiring proper preparation and constant maintenance throughout the operational life of the cooling tower.
Cooling towers made of steel are known, but are very expensive, very heavy to transport and erect, and require highly skilled workers in the design phase, any pre-fabrication phase, and in the erecting or construction phase, in order to avoid potential failure, improper fitting of components, or even injury to persons and property. Also, steel is subject to rusting and deteriorating in the constantly wet environment if it is not properly prepared and constantly maintained throughout the operational life of the cooling tower.
Cast-concrete cooling towers can be built using the shuttering method, where sections of the building framework are built using wooden forms; then concrete is poured into the forms to make a first lateral row. After the concrete sets, the next lateral layer is formed, filled with concrete, and allowed to set. This process continues until the structure reaches the desired height. The construction of such a tower is a major undertaking requiring many months, even a year, to complete. The logistics and heavy equipment required are extensive. Such traditional towers have underground basins and require extensive engineering and design in advance of construction.
Fordyce and Fritz (U.S. Pat. No. 3,834,681 A) teach an open-frame, prefabricated, concrete cooling tower structure. Furlong, et al. (U.S. Pat. No. 3,917,765 A) teach a cooling tower shell of factory-made pre-cast concrete parts. Curtis (U.S. Pat. No. 5,227,095 A) teaches a cooling tower system consisting of individual modules, which can be built from fiberglass in a factory and then transported to and erected on site. Curtis and Oberlag (U.S. Pat. No. 5,545,356 A) teach a method of constructing a cooling tower structure by casting the concrete walls on site in a horizontal position and then raising the walls to a vertical position—a “tilt-up” construction, or by pre-casting concrete modular wall units off-site and transporting and erecting them on site.
There is some question whether “tilt-up” and some other concrete pre-fabrication methods are capable of producing stable structures generally. For example, concerns about, and even requirements to retrofit, such structures in earthquake-prone areas.
Concrete pre-fabrication, like steel, requires highly skilled workers in the design phase, the pre-fabrication phase, and in the erecting or construction phase, in order to avoid potential failure, improper fitting of components, or even injury to persons and property.
All of the presently known methods of constructing cooling towers have at least one of the disadvantages of being insufficiently durable, too expensive, too difficult to transport, too long to place into operation, too difficult to erect or construct without highly skilled labor and long-term use of heavy machinery, and too difficult to maintain over the operational lifetime of the cooling tower.
Concrete masonry units (CMUs) and proper construction methods and standards for their manufacture and erection are known in other fields of construction. The advantages of CMUs include very low cost, greater strength at lighter weight than cast or pre-cast concrete, and the ability of masons of ordinary skill to quickly build structures according to already well-known methods. In CMU construction, hollow concrete blocks are reinforced with steel rebar or similar material and filled with concrete, mortar, or grout, with construction proceeding layer by layer, continuously, without having to wait for each concrete layer to set.

SUMMARY OF THE INVENTION

The present invention provides a cooling tower constructed of multiples of standard concrete masonry units (CMUs) properly reinforced, using standard CMU construction methods and specifications, and using masons of ordinary skill, costing less for construction and maintenance, requiring less heavy equipment, less transportation and lifting of heavy and large components, a smaller construction work site, and requiring significantly less time to construct and make operational.

BRIEF DESCRIPTION OF THE DRAWINGS

Reference will now be made to the drawings, wherein like parts are designated by like numerals, and wherein

FIG. 1 is a partially exploded orthogonal perspective view of the invention and of the cooling components housed in the invention.

FIG. 2 is a partially cutaway side perspective view of the invention and of the cooling components housed in the invention shown in place.

FIG. 3 is a low perspective side view of the invention and of the cooling components housed in the invention as in use.

FIG. 4 is a perspective view of the types of CMU components used in the invention.

FIG. 5 is an illustration of the construction method for the deep lintel type of CMU used in the invention.

FIG. 6 is an illustration of the construction methods of the use of reinforcing rebar and of temporarily supporting the deep lintel types of CMUs used in the invention.

FIG. 7 is an orthogonal side view of the invention.

FIG. 8 is an orthogonal top view of the invention.

FIG. 9 is an orthogonal perspective side view of an embodiment of the invention.

FIG. 10 is an orthogonal perspective side view of the foundation and embedded rebar and conduit of an embodiment of the invention.

FIG. 11 is an orthogonal perspective side view of an embodiment of the invention.

FIG. 12 is an orthogonal perspective side view of the foundation and embedded rebar and conduit of an embodiment of the invention.

FIG. 13 is an illustration of the function of the invention in operation.

FIG. 14 is a perspective view of an embodiment of the invention having two connected cooling towers.

FIG. 15 is a perspective view of an embodiment of the invention having four cooling towers connected with the water-basins in the center.

FIG. 16 is a perspective view of an embodiment of the invention having four cooling towers connected with the water basins to the outside.

DETAILED DESCRIPTION OF THE INVENTION

Referring to FIG. 1 & FIG. 2 the counterflow type of cooling system known in the art comprises, from top to bottom, an optional drift eliminator 54 for the purpose of catching sprays and mists of water and retaining them in the cooling system, a nozzle array 53 that sprays water to maximize the available surface area of water droplets for evaporative cooling, a thick layer of porous fill media 52 to further spread out the water droplets and to prolong their exposure to the cooling stream of air, and a water collector 51 that catches and channels the cooled water but allows the flow of cooling air from below.
The forced-air counterflow type of cooling system known in the art further comprises a fan 22 driven by a fan motor 21 and surrounded by a fan shroud 24, with the fan assembly located below the rest of the cooling system, which puts the fan assembly closer to the ground or mounting surface, which is advantageous for maintenance purposes and for weight-distribution purposes. See FIG. 3.
The forced-air counterflow type of cooling system is necessarily very large, in order to move a great volume of air across a great surface area of water. The cooling system for which a preferred embodiment of this invention is designed is approximately 24 square feet across and 8 feet deep, with an approximately 20-foot fan. In order to move a sufficient amount of air, the fan 22 should be mounted far enough above the ground or mounting surface, and with as few structural restrictions as possible, in order to provide an open chamber 18 allowing sufficient air intake.
Water is heavy, and 20-foot fans are heavy, so cooling systems are heavy. The forced-air counterflow type of cooling system is therefore a very heavy structure that must nevertheless be mounted high off the ground or mounting surface, and remain stable for many years of operation despite internal stresses from the constant movement of water and air and the machinery that moves them, and external stresses from weather, maltreatment, accident, or other circumstances related to the cooling towers being placed outside on rooftops, in parking lots, or in other exposed places.
Every millisecond throughout its several-decades operational life, a cooling-tower structure is required to keep a wet, heavy, shaking machine nine feet higher off the ground than gravity would have it be.
Although a stable cooling tower structure might be achieved by adding to and reinforcing the supporting structure below the level of the fan, adding more material in that area would inevitably reduce the air intake flow. The requirements for strength and stability run counter to the requirements for height and openness. This invention solves that problem.
Cooling towers present another conundrum; they are usually located in places where it is difficult to set up a construction project and difficult to move materials and heavy equipment. This invention solves that problem, too.
Presently known cooling tower structures and methods of construction largely comprise some type of cast concrete or pre-cast, pre-stressed concrete either as large components or as pre-fabricated sections. It is difficult to move large amounts of just-mixed concrete from several trucks at street level up to the rooftop of a tall building, and even where access is not so limited, pouring concrete has to be done in stages and requires a lot of time for completion. Moving large concrete components and pre-fabricated sections to the rooftop of a tall building or other inaccessible or constricted location is similarly difficult and expensive. This invention solves that problem, too.
The present invention is a cooling tower structure 10 made entirely of multiples of 6 sizes or styles of standard CMU concrete blocks 71, 72, 73, 74, 75, 76, reinforced and installed using standard materials and methods. See FIG.4. The CMUs are cheaply and readily available everywhere, and a large number of masons everywhere know how to install them properly. CMUs, especially the autoclaved aerated ones, are relatively light for their strength, and can be handled by the single unit or reasonable-sized groups of units, and therefore can be transported, stored, and placed into position much more easily than other building materials.
In a preferred embodiment, FIG. 9, the cooling tower structure is 30 feet in the longer horizontal dimension, which includes the water basin 40 or reservoir, 26 feet in the shorter horizontal dimension, and 18 feet tall, supporting the fan 22 at about 9 feet off the ground surface and the other cooling-system elements above the fan. This embodiment accommodates a cooling system 24 feet by 24 feet wide and up to 10 feet deep, having a fan size of up to 24 feet, although a 20-foot fan would probably be sufficient. This embodiment uses 1576 8-by-16-by-8-inch CMUs 71, 26 8-by-8-by-8 CMUs 72, 234 deep-lintel 16-by-8-by-8 CMUs 74, 6 corner 16-by-8-by-8 CMUs 75 for terminating some of the bond beams 30, 37 perforated 8-by-8-by-8 CMUs 73 which allow collected cooled water to flow into the basin 40, and 209 capping 1-by-8-by-8 CMUs 76. Other than the reinforcing rods 90 and the cement 78, mortar, or grout, no other construction materials are needed except for fasteners to support and secure the cooling system in place in the cooling tower.
In a smaller embodiment, FIG. 11, the cooling tower structure is 18 feet in the longer horizontal dimension, 14 feet in the shorter horizontal dimension, and the same 18 feet tall, supporting the fan 22 at about 9 feet off the ground surface and the other cooling-system elements above the fan. This embodiment accommodates a cooling system 12 feet by 12 feet wide and up to 10 feet deep, having a fan size of up to 12 feet, although a 10-foot fan would probably be sufficient. This smaller embodiment uses 918 8-by-16-by-8-inch CMUs 71, 27 8-by-8-by-8 CMUs 72, 126 deep-lintel 16-by-8-by-8 CMUs 74, 6 corner 16-by-8-by-8 CMUs 75 for terminating some of the bond beams 30, 19 perforated 8-by-8-by-8 CMUs 73 which allow collected cooled water to flow into the basin 40, and 119 capping 1-by-8-by-8 CMUs 76.
In other embodiments, cooling tower support structures can be built or added onto together, sharing common walls, in several configurations. FIG. 14 shows a two-tower configuration having a footprint of 30 feet by 51.3 feet and requiring 2838 of the large CMUs 74. FIG. 15 & FIG. 16 show four-tower configurations having footprints of 51.3 feet by 59.3 feet and requiring 5214 of the large CMUs 74.
The large, unobstructed open chamber 18 of the invention is made possible by the use of very long bond beams 30 or lintels, spanning, for example, 22 feet each in 3 spans of a preferred embodiment.
Referring to FIG. 5, the cooling tower structure comprises six lateral bond beams 30 or lintels constructed from deep lintel CMUs 74 having a deep “U” shape that accommodates the placement of a reinforcement bar 90 such as steel rebar in a horizontal orientation spanning and connecting or bonding the units, and filling with cement 78, mortar, or grout in order to secure the CMUs 74 and the reinforcement bar 90 in place. Where a deep lintel CMU 74 sits over another CMU, such as at a corner, it can be vertically secured by placing a reinforcement bar 90 through a notch 77 in the face of CMU that is mounted downward.
Referring to FIG. 6, during construction of the lateral bond beams 30 or lintels, the blocks over the span can be temporarily supported with material such as lumber, such as 2-by-4 lumber 79. Such temporary support is only needed while the cement 78, mortar, or grout sets up and secures the supporting material. With such a temporary support, the placement of courses of CMUs above the bond beams 30 is allowed to proceed without waiting for any set-up of the bond beam. Alternatively, the bond beams may be constructed on an adjacent flat surface and subsequently hoisted into place.
FIG. 13 illustrates the normal use of the cooling tower structure with the cooling system in place. The fan motor 21 and fan 22 are supported on a fan pedestal 20 which is securely attached to the foundation 12 in order to withstand the weight and the torque of the fan, and which encloses the electrical supply for the fan. In the lower portion 14, the fan draws air from the large open chamber 18 and blows the air upward against the downward travel of water through the cooling system mounted in the upper portion 16. Water is taken from the above-ground water basin 40 and is pumped into the nozzle array 53 that sprays water over the porous fill media 52 through which the water droplets travel downward at a pace that is slowed both by the fill media and the counter-flow of air, which prolongs the time available for evaporative cooling. An optional drift eliminator 54 mounted above the nozzle array 53 catches sprays and mists of water and retains them in the cooling system. Finally a water collector 51 that allows the flow of cooling air from below catches and channels the cooled water along its slight slope downward toward and into the water basin 40 from whence the water had come, completing one of the two loops of the system's operation.
The purpose for cooling the water in the basin 40 is to use that cooled water in one or more heat exchangers that are components of HVAC systems or cooling systems for industrial processes. In the second loop of the system's operation, cooled water is pumped from the basin 40 to the target HVAC or cooling system or systems where it undergoes a heat exchange, and is pumped back into the basin 40 for another iteration of the two loops.
The proper functioning of a cooling tower is critical to the functioning of HVAC systems and other cooling systems. If a cooling tower fails, it must be repaired or replaced. If a cooling tower is under-performing, or is under-specified in light of possibly unforeseen increased needs, it must be either replaced with or supplemented with another cooling tower. And such replacement or supplementation is likely to be needed immediately, where the efficient functioning of an enterprise is being hampered by a broken or under-performing cooling tower. The several months' long construction times of present cooling towers are costly to the enterprises needing new cooling towers.
The cooling-tower structure of the present invention is able to be constructed very quickly, in a matter of only a few days, for several reasons:
The materials, known quantities of six different sizes and styles of standard CMU blocks are universally available at small cost, are available on pallets of manageable size and weight that can be moved with a standard forklift, and can be quickly secured and transported to any job site. The only other materials, rebar and sacks of cement, mortar, or grout, are equally as easily available. There is no waiting period for anything to be pre-fabricated or to be secured and transported from a remote location.
The construction materials can be delivered to the job site—which might be the roof of a tall building—without the delays of arranging special shipments from far away, without arranging and waiting for special equipment such as cranes, and then waiting for permission to block streets with such equipment, and without arranging for the delivery and transfer of mixed concrete for on-site pouring to job sites that are not directly accessible to cement-mixer trucks.
The construction work can be performed by any block mason of average competence and experience, using standard methods. Therefore there is a greater chance that such a block mason will be available no matter the locale or the timing of the construction. Also, the construction work can proceed more quickly by adding more block masons, up to a point, and by adding additional shifts of block masons.
The construction work can proceed continuously to completion without waiting for any curing, drying, or setting up, or waiting for any special personnel or any special tool or material to arrive on site.
The cooling-tower structure that results from the very quick construction time of only a few days, even in difficult locations, is very sturdy, long-lasting, and inherently two-hour fire-rated.
The cooling-tower structure of this invention should be constructed on a suitable foundation, where the suitability will be determined by the specific construction site and conditions, which might range from a reinforced-concrete rooftop to a swampy spot of unused ground. FIG. 10 illustrates a foundation for the preferred embodiment of FIG. 9, and FIG. 11 illustrates a foundation for the smaller alternate embodiment of FIG. 11. In addition to whatever reinforcement and other requirements might be necessary for a particular foundation on a particular site, the foundation 12 should be of a size matching the footprint of the intended cooling-tower structure, which is 30 feet by 26 feet for the preferred embodiment here. Vertical reinforcement bars 90 or rebar should be embedded in the foundation 12 and attached to any horizontal reinforcement within the foundation. The placement of these vertical reinforcement rods is at the corners of the square tower structure under the corner columns 32, 34, plus the outer corners of the water basin 40, plus the eventual location of the fan pedestal 20, which is at the center of the square formed by the upper portion 16 of the cooling tower, disregarding the water basin 40.
The length of the vertical reinforcement bars 90 embedded in the foundation 12 does not have to extend the full height of the cooling tower, and the length is not critical because additional reinforcement bars can be placed in upper courses, as is standard and known in the art.
The secure attachment of the fan pedestal to the foundation is important because of the weight and the torque generated by the fan 22 in operation.
Additionally, electrical conduit 95 for electric power to the fan may be incorporated in the foundation and terminated under the location of the fan pedestal 20, although such electric power can also be run through surface-mounted conduit or by other conforming means.
Turning now to the invention in more detail, numeral 10 designates the water cooling tower according to the present invention. It should be noted that the water cooling tower is only one example of the structure that can be constructed using the apparatus and method of the present invention. The cooling tower 10 comprises a hollow structure having a foundation 12, a lower portion 14 supported by the foundation 12, and an upper portion 16 supported by the lower portion 14. The exemplary embodiment described herein is of a water cooling tower of counterflow design, where the air flow is directly opposite to the water flow. Air flow first enters an open area beneath the fill media, and is then drawn up vertically. The water is sprayed through pressurized nozzles near the top of the tower, and then flows downward through the fill, opposite to the air flow.
The lower portion 14 defines an open chamber 18, where a fan pedestal 20 is mounted. A motorized fan 22 is mounted on top of the fan pedestal 20, with the fan and motor being protected by a fan shroud 24. The fan shroud is supported by freestanding rear corner columns 32 and mid corner columns 34 incorporated into the above-ground water basin 40. A lateral bonding beam 30 separates the lower portion 14 from the upper portion 16, the lateral bonding beam 30 resting on the four columns of the lower portion 14.
A water collector assembly 51 is positioned in the upper portion 16 above the lateral beam 30. The water collector assembly can be a series of troughs or one large trough configured to direct collected water away from the upper portion 16. The water collector unit 51 is mounted at an angle to direct water by gravity into a basin 40 located above ground on the foundation 12. An angle of approximately 2 degrees, or a 4-inch drop over a 24-foot span is sufficient. In an embodiment, the proper mounting angle is created by a spacer 93 shown in FIG. 9 that provides a 4-inch rise and that may be made of various material, including concrete or steel, and may be incorporated into the construction of the cooling-tower structure, or into the installation of the cooling system into the tower structure, or may built into the water collector 51 itself.
Pumps, known in the art, are used to circulate water through the cooling tower and from the cooling tower to the HVAC or cooling system or systems served by the cooling tower. Waterproofed piping and connections, also known in the art, can be placed through holes made in the cooling-tower structure and the water basin at the appropriate locations.
The upper portion 16 defines an open space where the fill media 52 is deposited.
Water is pumped from the basin 40 and sprayed through the nozzle assembly 53 and passes through the fill media before flowing into the water collector unit 51.
The corner columns 32, 34 are constructed from CMU blocks of 16-inch and 8-inch lengths, in alternating courses, as shown, using construction methods of reinforcement and filling with concrete, mortar, or grout known to block masons of normal skill and competence. Each column provides 40 square inches, in cross section, of support, and each is secured in 5 places to the foundation 12 through the vertical reinforcement bars 90.
Because the CMU blocks themselves define the structural frame for the concrete, there is no need to wait for the concrete to set in a lower course or layer before placing additional courses on top, and construction can proceed without delay.
After the corner columns 32, 34 are constructed from standard 16-inch and 8- inch CMUs 71, 72 the lateral bond beams 30 can be constructed from deep lintel CMUs 74. A temporary support structure 79 can be used to hold the lateral bond beams 30 in place until the concrete 78, mortar, or grout securing the reinforcement bars 90 sets up. In the alternative, the deep lintel CMUs 74 comprising the bond beams 30 can be assembled on an adjacent flat surface and later hoisted into place. Because the exact materials and dimensions of the bond beams 30 are known in advance, they can be assembled in advance of the time they are needed to be put in place.
The bond beam 30 is constructed from deep lintel CMUs 74 securely bonded together by reinforcement bar 90 and concrete 78, mortar, or grout, and effectively forming a lintel. Where a deep lintel CMU 74 sits over another CMU, such as at a corner, it can be vertically secured by placing a reinforcement bar 90 through a notch 77 in the face of CMU that is mounted downward. A vertical reinforcement bar is positioned transversely to the horizontal reinforcement bar or bars. The vertical reinforcement member 90 extends through the notch 77.
The preferred materials of construction are CMU concrete blocks with a waterproof coating applied to the inside walls of the cell and basin to prevent water seeping through the blocks.
The structure of the present invention requires only an above-ground foundation with only a single conduit in the slab for power and controls for the fan. Once the foundation is completed, the blocks will arrive by truck and the block masons can immediately begin installing blocks. A single cell tower can be erected in 3 working days. Multiple cells can be staged with additional block masons and can go up just as quickly. No special equipment (i.e. cranes, forklifts, etc.) are required to erect the tower. A crane will be required to set the water collectors inside the erected tower. The lifts required to install the collectors are less than 1,000 lbs per lift so the size of the crane required is minimal. Everything else will be installed by hand. The total time required to install a working cell is less than two weeks.
Many changes and modifications can be made in the present invention without departing from the spirit thereof. We, therefore pray that our rights to the present invention be limited only by the scope of the appended claims.

Claims

We claim:

1. A cooling tower structure to support a cooling system of a target square size, comprising:

a foundation of the target square size plus six feet on a longer, water-basin dimension of said cooling tower structure, plus two feet on a shorter dimension;

where said foundation has embedded within it vertical reinforcement bars for the secure attachment of said cooling tower structure;

two freestanding corner columns constructed from CMU blocks, attached to said foundation;

two corner columns incorporated into said structure, constructed from CMU blocks and attached to said foundation;

at least three bonding beams constructed from CMU blocks, supported by and attached to said corner columns;

where said bonding beams supported by said corner columns create an open chamber within a lower portion of said cooling tower structure for unobstructed intake of air;

an above-ground water basin incorporated into said cooling tower structure at said incorporated corner columns, constructed from CMU blocks and attached to said foundation;

an upper portion of said cooling tower structure, of said target square size plus two feet, constructed from CMU blocks, supported by said bonding beams, in turn supported by said corner columns;

where said upper portion is adapted to enclose a cooling system of said target square size; and

a fan pedestal constructed from CMU blocks, attached to said foundation at a point in the center of said upper portion;

where said fan pedestal is adapted to support a fan motor and fan of said cooling system of said target square size;

where said cooling tower structure is constructed from standard CMU blocks using standard materials and construction techniques known to block masons of average competence and experience; and

where said construction from standard CMU blocks is accomplished quickly and inexpensively.

2. The cooling tower structure of claim 1, where said upper portion further encloses a forced-air counterflow type of cooling system.

3. The cooling tower structure of claim 1, where said target square size is 24 feet, said cooling tower structure is 30 feet in the longer horizontal dimension, which includes said water basin, 26 feet in the shorter horizontal dimension, and 18 feet tall, supporting said fan at about 9 feet off the ground surface.

4. The cooling tower structure of claim 1, where said standard CMU blocks further comprise 1576 8-by-16-by-8-inch CMUs, 26 8-by-8-by-8 CMUs, 234 deep-lintel 16-by-8-by-8 CMUs, 6 corner 16-by-8-by-8 CMUs, 37 perforated 8-by-8-by-8 CMUs, and 209 capping 1-by-8-by-8 CMUs.

5. A method for constructing a cooling tower structure of a target square size, comprising:

providing a foundation of the target square size plus six feet on a longer, water-basin dimension of said cooling tower structure, plus two feet on a shorter dimension;

embedding within said foundation vertical reinforcement bars for the secure attachment of said cooling tower structure;

providing two freestanding corner columns constructed from CMU blocks, attached to said foundation;

providing two corner columns incorporated into said structure, constructed from CMU blocks and attached to said foundation;

providing at least three bonding beams constructed from CMU blocks, supported by and attached to said corner columns;

providing an above-ground water basin incorporated into said cooling tower structure at said incorporated corner columns, constructed from CMU blocks and attached to said foundation;

providing an upper portion of said cooling tower structure, of said target square size, constructed from CMU blocks, supported by said bonding beams, in turn supported by said corner columns;

providing a fan pedestal constructed from CMU blocks, attached to said foundation at a point in the center of said upper portion;

6. The method for constructing a cooling tower structure of claim 5, where said upper portion further encloses a forced-air counterflow type of cooling system.

7. The method for constructing a cooling tower structure of claim 5, where said target square size is 24 feet, said cooling tower structure is 30 feet in the longer horizontal dimension, which includes said water basin, 26 feet in the shorter horizontal dimension, and 18 feet tall, supporting said fan at about 9 feet off the ground surface.

8. The method for constructing a cooling tower structure of claim 5, where said standard CMU blocks further comprise 1576 8-by-16-by-8-inch CMUs, 26 8-by-8-by-8 CMUs, 234 deep-lintel 16-by-8-by-8 CMUs, 6 corner 16-by-8-by-8 CMUs, 37 perforated 8-by-8-by-8 CMUs, and 209 capping 1-by-8-by-8 CMUs.