Abstract:
A dual evaporative pre-cooling system is installed packaged air conditioning units. The dual evaporative pre-cooling system includes an evaporative media disposed in a housing through which incoming condenser air flows. A water distribution device is disposed above the evaporative media. A sump and a pump are located below the evaporative media to recirculate water through the water distribution device and a ventilation air pre-cooling coil. A plurality of pipes connect, and allow circulation of, a water source discharged from the pump through the ventilation air pre-cooling coil, and to the water distribution device.

Description:
CROSS-REFERENCE TO RELATED APPLICATION 
     This application claims the benefit of U.S. Provisional Application No. 60/256,474, filed on Dec. 20, 2000. 
    
    
     BACKGROUND OF THE INVENTION 
     1. Field of Invention 
     This invention relates to improvements in evaporative pre-cooling devices, and particularly to a device that uses a dual evaporative cooling system to improve the efficiency and reduce electrical demand of packaged rooftop cooling systems frequently used on non-residential buildings. 
     2. Description of Related Art 
     A majority of new low-rise non-residential buildings in the United States are cooled with packaged rooftop units (RTU&#39;s). A RTU can include a number of components, e.g., one or more compressors, a condenser section that includes one or more air-cooled condensing coils, condenser fans, an evaporator coil, a supply blower, an intake location for outdoor ventilation air (with or without an “economizer” to fully cool from outdoor air when possible), optional exhaust air components, and controls. These components are packaged alike by manufacturers to be air cooled. Conventional modes for packaging fail to take advantage of the opportunity to improve efficiency and reduce electrical demand through evaporative condenser cooling. This opportunity is particularly significant in dry climate locations such as in California, where more than 1,000,000 air-cooled RTU&#39;s were operating as of the year 2000. 
     In climates where summer afternoon temperatures routinely reach 95° F. and higher, but with dry air such that wet bulb temperatures rarely exceed 70° F., RTU cooling efficiencies can be increased by 20% to 25% using an evaporative condenser air pre-cooler (ECAP). ECAP&#39;s have been available for many years but have not achieved widespread success. Their low sales volume results in part from their added maintenance requirements and in part from the failure of RTU manufacturers to market them. RTU manufacturers have been reluctant to market accessories that appeal to regional markets, especially if those accessories require added maintenance. Strategies that reduce ECAP maintenance requirements and clearly demonstrate favorable economics could substantially enlarge the ECAP market. 
     High maintenance requirements that have typically plagued ECAP&#39;s result from: hard water deposits, entry of insects and debris, difficult access to key operating components, and biological growth that fouls water feed components. Hard water deposits result from calcium and magnesium in the supply water that concentrate as pure water evaporates. These minerals firmly adhere to piping and evaporative media surfaces, reducing flow rates, clogging water distribution headers, and causing deterioration of the economical rigid evaporative media materials. The entry of bugs and debris also contribute to the disadvantages associated with RTU&#39;s without ECAP&#39;s. Periodic cleaning of condenser coils is required to maintain efficient operation. Evaporative media panel cleaning is complicated by conventional designs. For example, removal of an evaporative media panel is required from the top, where the water distribution header interferes and therefore must also be removed. An ECAP reduces condenser coil cleaning frequency, but its own maintenance requirements are seldom credited for the coil cleaning savings. Biological (algae) growth typically occurs in locations that remain continuously wet, as is true of ECAP sumps. These maintenance issues for traditional ECAP&#39;s offer a clear opportunity to enlarge the market using features that significantly reduce maintenance requirements. 
     The ECAP market has also been limited by a disconnect between purchasers and maintainers. ECAP&#39;s are usually purchased by management based on a payback analysis prepared by the seller. After installation, the ECAP becomes the responsibility of a maintenance staff or a contractor who seldom pays the energy bill and therefore has little idea of the ECAP value. Monitoring of savings is typically expensive and therefore avoided. As a result, many ECAP&#39;s are removed and considered a failure after a few years in use. This recurring scenario suggests an opportunity for improved designs with economical on-board monitoring and diagnosis electronics. 
     A major untapped opportunity afforded by RTU design is evaporative pre-cooling of ventilation air. At least 10% of the supply air delivered by RTU&#39;s is typically outdoor air needed for building ventilation. In some cases, particularly for laboratory facilities, RTU&#39;s deliver 100% outdoor air. In warm weather, cooling of ventilation air represents a significant fraction of the total cooling load. In the driest climates, ventilation air can be pre-cooled by the same direct evaporative process used in ECAP&#39;s. However, in most applications an indirect process that adds no moisture to the ventilation air is preferred. 
     Another opportunity afforded by RTU evaporative pre-cooling is reduction of fan energy consumption. On the condenser side, RTU&#39;s use high airflow rates to compensate for their air-cooled design. And, on the evaporator side, RTU&#39;s typically send indoor air through a contorted path as it is drawn up through return ducts into the RTU, around several tight turns inside the unit, and back down through supply ductwork. The added pressure drop associated with this complex path results in high fan energy consumption that penalizes the system all year, particularly in widely-used constant-speed systems. These high fan speeds are required during peak cooling load conditions. Applying evaporative air pre-cooling to both condenser and evaporator sides allows reduced fan speeds that generate full-year fan energy savings. 
     In recent years several new RTU pre-cooler products use a non-recirculating water feed system without a pump or a sump. In these lower-cost systems, water from a pressurized source is fed over the evaporative media as needed in response to a moisture sensor at the bottom of the evaporative media. Excess water that reaches the bottom is drained away. These systems have three disadvantages. First, they cannot circulate evaporatively-cooled sump water to a ventilation air pre-cooling coil. Second, they typically use more water than recirculating systems because of their constant drainage. Third, they are more susceptible to fouling with hard water deposits because all hardness minerals are left on the pads of the rigid evaporative media. 
     These disadvantages suggest a need and opportunity for dual evaporative pre-cooling systems that are capable of fitting both new and existing packaged rooftop cooling units, reducing maintenance requirements, and pre-cooling both condenser and ventilation air, thus facilitating reduced fan operating speeds. In addition, there is a need for a dual evaporative pre-cooling system that can diagnose operation and report energy savings to building owners, operators, electric utilities and any other party responsible for the operation thereof. 
     SUMMARY OF THE INVENTION 
     The present invention addresses the problems set forth above. The present invention is directed to dual evaporative pre-cooling systems for use as accessories on packaged rooftop cooling units that satisfy the above needs. An exemplary dual evaporative pre-cooling system according to the invention includes one or more evaporative condenser air pre-cooling panels, one or more water sumps, one or more water pumps, an indirect ventilation air pre-cooling coil, a supply pipe from at least one pump to the indirect ventilation air pre-cooling coil, a return pipe from the indirect ventilation air pre-cooling coil to the evaporative condenser air pre-cooling panels, a refill system to replace evaporated water, a motorized valve or second pump to purge and discharge sump water for maintenance purposes, an electrical power supply, and a control system to control and monitor system operations. 
     Another aspect of the invention is to provide a dual evaporative pre-cooling system for packaged air conditioning units. The dual evaporative pre-cooling system includes an evaporative media disposed in a housing with an air entry side through which incoming air flows. A water distribution device is disposed above the evaporative media. A sump and a pump are located in the housing below the evaporative media. The pump recirculates water through the water distribution device. A ventilation air pre-cooling coil and a plurality of pipes are connected together to allow circulation of a water source discharged from the pump through the ventilation air pre-cooling coil, and to the water distribution device. 
     According to the invention, each evaporative condenser air pre-cooling panel includes a structural frame, a rigid evaporative media contained within the frame, a water distribution header above the evaporative media, and an inlet screen that prevents insects and debris from entering the system. At least one (primary) evaporative condenser air pre-cooling panel includes a sump disposed below the evaporative media that contains enough water to ensure continuous pump operation without running dry. Other panels may be secondary panels, without sumps, that drain to the sump of the primary evaporative condenser air pre-cooling panel. In an exemplary embodiment, all of the water pumped from at least one of the sumps is delivered through the indirect ventilation air pre-cooling coil before circulating to at least one of the water distribution headers. In alternate exemplary embodiments, a pumped flow of water can be apportioned between the indirect ventilation air pre-cooling coil and at least one of the distribution headers, such that some of the water can bypass the coil and flow directly to the distribution headers, or some of the water can return directly to the sump from the indirect ventilation air pre-cooling coil, bypassing the distribution headers. 
     In an exemplary embodiment, each distribution header includes of a horizontal pipe perforated with a linear hole pattern. To ensure uniform water distribution on the top of the evaporative media, water is discharged upward from the horizontal perforated pipe against an underside of a semi-cyclindrical distributor surface. The sprayed water ricochets randomly into a widely-dispersed pattern that fully wets the evaporative media. 
     To prevent freeze-damage, the indirect coil and connecting pipes are designed to drain water back to the sump when the pump is not operating. Drainage is facilitated by a submersible pump with a vertical-axis impeller that delivers water through an upward-sloping pipe to a bottom inlet of a vertical supply manifold in the ventilation air pre-cooling coil. The indirect ventilation air pre-cooling coil can be provided with all horizontal serpentine circuits in parallel. The horizontal serpentine circuits of the ventilation air pre-cooling coil discharge into a vertical return manifold with top outlet. From the indirect ventilation air pre-cooling coil discharge, no “traps” are permitted before the water emerges from the perforated pipe. When pumped flow stops, air entering the perforated pipe allows water in the indirect ventilation air pre-cooling coil and in the pipes to drain back to the sump. The sump is discharged either by opening a drain valve or activating a pump-out cycle. 
     In an exemplary embodiment, the water refill system includes: a pressurized water supply line, a solenoid valve, a float switch, and a controller to operate the water refill system. This exemplary embodiment is used in conjunction with controls that limit biological growth by regularly discharging the sump. According to the invention, a control/monitoring system includes the controller (e.g., a microprocessor controller) with a time clock and temperature sensors that detect: an outdoor air, an evaporatively pre-cooled air, a building return air, the sump water, and a return water from the ventilation air precooling coil. Based on at least these five temperature inputs, pre-programmed building operating schedule data, and a cooling demand on the RTU, the controller can decide when to operate the evaporative pre-cooler system to maximize energy savings. The controller also uses this data in conjunction with power monitoring input data to compute and report energy savings, and to diagnose potential operating problems. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The invention will be described in detail with reference to the following drawings in which like reference numerals refer to like elements and wherein: 
     FIG. 1 shows a cross sectional view of a rooftop cooling unit with a dual evaporative pre-cooling system according to an exemplary embodiment of the present invention; 
     FIG. 2 shows an enlarged cross-sectional view of the condenser air pre-cooling panel of the exemplary embodiment shown in FIG. 1; and 
     FIG. 3 shows an enlarged cross-sectional view of another aspect of an open-bottomed slot as shown in FIG.  2 . 
    
    
     DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS 
     An exemplary embodiment of the present invention is described hereafter, with reference to FIGS. 1 and 2. 
     FIG. 1 shows an exemplary embodiment of a schematic cross-sectional view of a rooftop cooling unit (RTU)  10  including a dual evaporative pre-cooling system according to the present invention. 
     The RTU  10  includes a refrigeration-based cooling system including: an evaporator coil  11 , a condensing coil  12 , a compressor  13 , an expansion device  16 , and connecting refrigerant lines  14 ,  15 , and  17 . Included in the RTU is a condenser fan  12   a  and a supply blower  18 . In operation, a hot refrigerant gas compressed by a compressor  13  flows through refrigerant line  14  into the condenser coil  12 . The condenser fan  12   a  pulls outdoor air  100  across the condenser coil  12 . Since the outdoor air  100  is cooler than the hot gas refrigerant entering the condenser coil  12 , the gas is condensed to a pressurized liquid refrigerant and leaves the condenser coil  12  through the refrigerant line  15 . In refrigerant line  15 , the pressurized liquid refrigerant passes through expansion device  16 , where the pressure of the pressurized liquid refrigerant is reduced. The liquid refrigerant then enters the evaporator coil  11 , where the liquid refrigerant cools as it flashes to a vapor state (refrigerant vapor). A variable mixture of outdoor air  100  and return air  101  is drawn across the evaporator coil  11  by the supply blower  18 . The supply blower  18  is driven by the blower motor  19 . The cooled refrigerant cools the air drawn across the evaporator coil  11 . The refrigerant vapor leaves the evaporator coil  11  through the refrigerant line  17  and returns to the compressor  13 , where the refrigerant begins another cycle. 
     Return air  101  from the building enters a mixing zone  20  from a return duct  21  through a return damper  24 . A return air temperature sensor  45  disposed in the return duct can be used to create a more accurate estimate for cooling energy savings. Outdoor air  100  enters the mixing zone  20  through an inlet  22  and an outdoor damper  23 . The percentage of outdoor air  100  to return air  101  is controlled by movement of the outdoor damper  23  and the return damper  24 . Most RTU&#39;s are equipped for adjustable outdoor air percentages from 0% to 100%. The variable mixture of outdoor air  100  and return air  101  pulled by the supply blower  18  across (and cooled by) the coil  11  is delivered as supply air  102  to the building through a supply duct  25 . 
     According to this invention, an exemplary dual evaporative pre-cooling system is included with the RTU. The dual evaporative pre-cooling system includes a condenser air pre-cooling panel  30  with a sump  50  and a water refill system  31 , an indirect ventilation air pre-cooling coil  33 , a supply pipe  34 , a return pipe  35  (connecting distribution pipes), a media distribution header  36 , and a controller  40 . As further described with reference to FIG. 2, the major component of the pre-cooling panel  30  is an evaporative media  37 . The evaporative media  37  is wetted at the top with water from the distribution header  36 . The water cools evaporatively while it drains downward through the evaporative media  37  and is collected at the bottom in the sump  50 . A submersible pump  32  is located in the sump  50 , and delivers cooled sump water through the supply pipe  34  into the bottom of the ventilation air pre-cooling coil  33 . After passing through the ventilation air pre-cooling coil  33 , where it cools incoming outdoor air  100 , the water returns to the distribution header  36  through supply pipe  35 . 
     In climates where outdoor air temperature may fall below freezing, the ventilation air pre-cooling coil  33 , the supply pipe  34 , the return pipe  35 , and the distribution header  36  can be configured to drain the water when the submersible pump  32  stops operation. Thus, the supply pipe  34  is configured to slope continuously upward from the submersible pump  32  to the ventilation air pre-cooling coil  33 , and both the ventilation air pre-cooling coil  33  and the return pipe  35  are configured to be free of traps that would prevent drainage. The distribution header  36  is perforated for drainage. When the submersible pump  32  stops operating, air enters the distribution header  36  to replace water draining by gravity back to the sump  50 . The design of the ventilation air pre-cooling coil  33  is configured to promote drainage. Water enters adjacent the lowest point on a vertical supply header  33   a , and then proceeds either horizontally or upward through serpentine coil tubes (not shown) before flowing into a vertical return header  33   b . To facilitate drainage, the return pipe  35  is connected adjacent the top of the vertical return header  33   b.    
     According to the exemplary embodiment, the controller  40  monitors and controls operation of the dual evaporative pre-cooling system based on cooling requests from a building thermostat (not shown), and temperature conditions sensed by at least one sensor, which will be described later. Various exemplary embodiments for the dual evaporative pre-cooling system are possible. In one embodiment, a pre-cooling operation occurs only when the building thermostat calls for a compressor  13  operation, after which the controller  40  causes the sump  50  to fill as will be further discussed with reference to FIG.  2 . When the sump  50  is full, the controller  40  activates the submersible pump  32  to deliver water in the sump  50  through the ventilation air pre-cooling coil  33  and the distribution header  36  before wetting the evaporative media  37 . The evaporative process has a dual effect, cooling both the air flowing across the condenser coil  11  and the water from the sump  50 . The submersible pump  32  continues to operate until operation of compressor  13  has stopped. When the submersible pump  32  has not operated for a predetermined period (e.g., four hours), the controller  40  causes the sump  50  to be emptied as will be further discussed with reference to FIG.  2 . 
     According to this invention, the controller  40  performs many control and diagnostic functions in response to sensing a variety of different conditions. Using input signals received from an outdoor air sensor  41 , the controller operates the submersible pump  32 , and optionally the condenser fan  12   a , even when compressor  13  is not operating. If the outdoor air  100  is warmer than a preset threshold temperature (e.g., 60 F.), the dual evaporative pre-cooling system can delay the need for operation of the compressor  13  by pre-cooling the supply air  102  even though the building thermostat has not yet sensed a cooling load. Additional sensors can be provided to detect many conditions for input to the controller  40  including, but not limited to, measuring energy savings and diagnose operating problems. 
     For example, a pre-cooled air sensor  42  can be used to measure both energy savings and to assist in diagnosing operating problems. When the submersible pump  32  has been operating for a sufficient time long enough to fully wet the evaporative media  37 , the controller  40  can report an operating error, and request a service call if the pre-cooled air sensed by the pre-cooled air sensor  42  is not cooler than the outdoor air  100  sensed by the outdoor air sensor  41 . And, inputs signals received by the controller  40  from the outdoor air sensor  41  and the pre-cooled air sensor  42  can be used in conjunction with other known cooling performance parameters to compute energy savings produced by the condenser air pre-cooler. For example, the microprocessor can use an algorithm that computes “base case” and “pre-cooled” compressor energy use as a function of condenser inlet air temperature, and based on an assumed indoor air temperature. A base case is defined as an evaporative pre-cooling device without dual evaporative pre-cooling. The program can then subtract and integrate pre-cooled energy use from base case energy use to compute total energy savings that derive from the pre-cooled condenser air. 
     Approximate energy savings produced by the ventilation air pre-cooling operation can be estimated based on a water flow rate determined in laboratory tests and a water temperature rise computed by subtracting the reading of temperature sensor  43  in the water sump  50  from a reading of a coil return water temperature sensor  44 . This temperature rise multiplied by the flow rate times a predetermined constant equals heat removed from the ventilation air by the ventilation air pre-cooling coil  33 . Total cooling energy savings can then be approximated by adding the condenser air and ventilation air savings in thermal units (such as British thermal units or “Btu&#39;s”), converting to electrical energy units saved based on known efficiency for the RTU, and subtracting parasitic energy consumption of the submersible pump  32  based on run time as tracked by the controller  40 . Approximate efficiency of the pre-cooling system can be computed by dividing total energy savings by parasitic energy consumption of the submersible pump  32 . For example, the total cooling energy savings in Btu&#39;s over a one month period can be divided by the pump energy consumption over the same period in kWh to generate an energy efficiency ratio (EER) in Btu&#39;s/kWh for the dual evaporative pre-cooling system. This EER may be directly compared to EER&#39;s for the RTU and other cooling systems. While these values are approximate, they are suitably accurate for reporting system savings. According to these approximations, air and water flow rates are assumed not to vary with time. 
     The dual evaporative pre-cooling system is provided with a communication link  200  connected to the controller  40  for transmitting conditions monitored and computed by the controller  40  for reporting operation data information about the dual evaporative pre-cooling system to any known or later developed device that can transmit information, including but not limited to, a radio communication system, a telephone system, and an Internet connection system, in order to report operation data information about the dual evaporative pre-cooling system. The communication link  190  can be any known or later developed communication link. 
     FIG. 2 shows an enlarged cross-sectional view of the condenser air pre-cooling panel  30  according to the present invention. As mentioned with reference to FIG. 1, outdoor air  100  proceeds from right to left through the condenser air pre-cooling panel  30 . The distribution header  36  distributes water along a top edge panel  37   a  of the evaporative media  37  and the water drains downward into the sump  50 . The water is delivered though the supply pipe  34  to the ventilation air pre-cooling coil  33  by the submersible pump  32 . Supply pipe  34  is located above the water level to minimize the danger of leakage. A solenoid valve  27  fills the sump  50  and re-supplies water as it is evaporated. 
     The structure of condenser air pre-cooling panel  30  includes of a bottom container  51  connected by side panels (not labeled) to a top cover  56 . The bottom container  51  includes at its upper left side, sloping surface  52   a  to drain any water droplets falling from the evaporative media  37  back into the sump  50 . A horizontal ledge  52   b  extends inward from the sloping surface  52   a  to support a rear edge  37   b  of the evaporative media  37 . The sloping surface  52   a  is steep enough (e.g., 45 degrees) to prevent fan suction created by the condenser fan  12   a  from drawing the evaporative media  37  inward. The bottom container  51  includes at its right edge a trough  58  with an inward horizontal extension  52   c  to support a front edge  37   c  of the evaporative media  37 . 
     The top cover  56  includes, disposed at a left side, a vertical evaporative media stop  57   a . The right side of the top cover  56  includes an open-bottomed slot  57   c . The open-bottomed slot  57   c  is deeper than the trough  58  by at least the depth of the trough  58 . The open-bottomed slot  57   c  is formed by a first vertical surface  57   b , a second vertical surface  59  and on top by the top cover  56 . The open-bottomed slot  57   c  can be made integral with the top cover  56  or from separate elements. For example, FIG. 3 shows the open-bottomed slot  57   c  being configured from separate elements. As a combination of separate elements, the open-bottomed slot  57   c  includes a vertical surface  57   b  that combines with an angle  59   a  secured to the top cover  56  by a fastener  59   b  (e.g., a rivet). According to this aspect of the invention, the open-bottomed slot  57   c  is easy to fabricate. 
     A screen  53 , lined by a screen frame  54 , is inserted into the trough  58  at a lowermost end and the open-bottomed slot  57   c  at an uppermost end. The height of the screen frame  54  is configured to be easily inserted into the open-bottomed slot  57   c  of the cover top  56  and to be held without fasteners. To insert the screen  53 , the top of the screen frame  54  is inserted and slid fully upward into the open-bottomed slot  57   c  to permit the bottom of the screen frame  54  to clear its bottom edge and drop downward into the trough  58 . The top of the screen frame  54  is then retained by the front edge  57   b  of the top cover  56 . 
     The evaporative media  37  includes a relatively rigid assembly of treated corrugated paper layers in an alternating configuration that maximizes evaporative contact between air and water, with relatively low pressure drop for air passing through the evaporative media  37 . Various alternatives are possible according to the invention. For example, a more expensive alternate rigid evaporative media of similar configuration but produced from corrugated fiberglass layers with enhanced fire-resistance can be used. The alternating corrugated layers typically slope (e.g., 45 degrees) downward toward an air entry side, and at a lesser (e.g., 15 degree) downward slope toward an air exit side. This sloping bias causes water flowing downward to counteract the tendency of the inward air flow to carry water droplets off the back side of evaporative media  37 . 
     As shown in FIG. 2, the distribution header  36  has small holes  36   a  (e.g., ⅛″ diameter) uniformly spaced (e.g., 2 inches apart) along its top side. Water returning from the ventilation air pre-cooling coil  33  and through the distribution header  36  sprays upwards through holes  36   a  disposed against the underside of a reflector  60 . The reflector  60  is a half-cylinder of diameter, e.g., approximately three times the diameter of the distribution header  36 . The distribution header  36  is secured by fasteners  61  to the underside of the top cover  56 . The reflector  60  distributes water relatively uniformly downward onto the top of the evaporative media  37 . The diameter of the reflector  60  can be, e.g., approximately half the thickness of the evaporative media  37 . The distribution header  36  and the reflector  60  can be located closer to the outdoor air entry side (e.g., the right) of the evaporative media  37  than to the outdoor air exit side (e.g., the left). 
     A water refill subsystem  31  is located in the bottom container  51  of the condenser air pre-cooling panel  30 . The water refill subsystem  31  includes a supply pipe  26 , a solenoid valve  27 , a spout  28 , a float switch  29 , and control wires  29   a  connected to the controller  40 . A sump purge assembly  150  is connected to the bottom container  51  and includes a flush exit port  55   a , a drain valve  156 , and a discharge line  55   b . The solenoid valve  27  is automatically opened when the system is operating and the float switch  29  indicates that the water level in the sump  50  is low. 
     To begin a cooling cycle, the controller  40  closes the drain valve  156  and activates the solenoid valve  27  until the float switch  29  indicates that the sump  50  is full. When the submersible pump  32  has not operated for a predetermined length of time (e.g., 4 hours), the controller  40  opens the drain valve  156  to drain all of the water from the sump  50  through the discharge line  55   b . The exit port  55   a  is located flush with the bottom of the sump  50  to assure that all water is drained from the sump  50 . The exit from the spout  28  can be located at a position that prevents backflow, e.g., at least 2 inches above the water level in the sump  50 . Signals between the controller  40 , the float switch  29 , and the solenoid valve  27  travel through the control wires  29   a.    
     In the illustrated embodiment, the controller  40  is implemented as a programmed general purpose computer. It will be appreciated by those skilled in the art that the controller can be implemented using a single special purpose integrated circuit (e.g., ASIC) having a main or central processor section for overall, system-level control, and separate sections dedicated to performing various different specific computations, functions and other processes under control of the central processor section. The controller can be a plurality of separate dedicated or programmable integrated or other electronic circuits or devices (e.g., hardwired electronic or logic circuits such as discrete element circuits, or programmable logic devices such as PLDs, PLAs, PALs or the like). The controller can be implemented using a suitably programmed general purpose computer, e.g., a microprocessor, microcontroller or other processor device (CPU or MPU), either alone or in conjunction with one or more peripheral (e.g., integrated circuit) data and signal processing devices. In general, any device or assembly of devices on which a finite state machine capable of implementing the procedures described herein can be used as the controller. A distributed processing architecture can be used for maximum data/signal processing capability and speed. 
     The controller  40  is also connected to receive signals and to control a variety of devices in the dual evaporative pre-cooling system, including but not limited to, the compressor  13 , the blower motor  19 , the condenser fan  12   a , the coil return water temperature sensor  44 , the pre-cooled air sensor  42 , the solenoid valve  27 , the float switch  29 , the submersible pump  32 , the temperature sensor  43  located in the sump water, the return air sensor  45 , the drain valve  156  and any other device requiring control and receipt of a control signal. A utility input signal can also be received from the return air sensor  45  to signal the controller  40  to pre-cool the building in the morning to limit afternoon cooling loads. 
     The communication link  200  in FIG. 1 can be any known or later developed device or system for reporting operation data information about the dual evaporative pre-cooling system to any known or later developed device for transmitting information. The controller  40  may be connected via the communication link  200  to one or more of a direct cable connection, a radio transmission connection, a telephone line connection, a connection over a wide area network or a local area network, a connection over an intranet, a connection over the Internet, or a connection over any other distributed processing network or system. In general, the communication link  190  can be any known or later developed connection system. Further, it should be appreciated that the communication link  190  can be a wired or wireless link to a network. The network can be a local area network, a wide area network, an intranet, the Internet, or any other distributed processing and storage network. 
     While the invention has been described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the exemplary embodiments or constructions. To the contrary, the invention is intended to cover various modifications and equivalent arrangements. In addition, while the various elements of the exemplary embodiments are shown in various combinations and configurations, other combinations and configurations, including more, less or only a single element, are also within the spirit and scope of the invention.