초록 ▼

An evaporative cooler, including one or more media modules, distributes water from a source of water to each module through a constant flow valve. A distribution unit at each media module includes a spray bar for spraying water through a plurality of uniformly spaced holes having an aggregate area e

An evaporative cooler, including one or more media modules, distributes water from a source of water to each module through a constant flow valve. A distribution unit at each media module includes a spray bar for spraying water through a plurality of uniformly spaced holes having an aggregate area equivalent to or less than twenty five percent (25%) of the internal cross sectional area of the spray bar. A distribution cap distributes the streams of water to the underlying media module(s) and the water dripping from the media module(s) is drained. A fan or other air moving device draws air through the media module(s) to obtain cooled air resulting from evaporation of water flowing downwardly along the media module(s). A microprocessor controller, responsive to any of one or more sensors for sensing the temperature of the air flowing into and out of the media module(s), the relative humidity of the air flowing into and out of the media module(s), the pressure differential between the upstream and downstream sides of the media module(s), the temperature of the water flowing to the spray bar(s), the fan speed, and the pressure differential between the downstream side of the media module(s) and the downstream side of the fan, controls the flow of water and the fan speed.

대표청구항 ▼

We claim: 1. In an evaporative cooler system having a source of water, a media module, a water distribution system for distributing water along the top of the media, a device for causing air flow through the media module to evaporate the water flowing therethrough and cool the air, a sump and a dra

We claim: 1. In an evaporative cooler system having a source of water, a media module, a water distribution system for distributing water along the top of the media, a device for causing air flow through the media module to evaporate the water flowing therethrough and cool the air, a sump and a drain for draining water from the sump, the improvement comprising in combination: a) a spray bar in fluid communication with the source of water, said spray bar having an internal cross sectional area; b) a constant flow valve for controlling the flow of water to said spray bar; and c) a plurality of holes disposed in said spray bar for discharging water onto the media module, said plurality of holes defining, in the aggregate, an area equivalent to or less than twenty five percent (25%) of the internal cross sectional area of said spray bar. 2. An evaporative cooler system as set forth in claim 1 wherein said plurality of holes are equally spaced along said spray bar. 3. An evaporative cooler system as set forth in claim 1 including a distribution cap for distributing water from said spray bar onto the media module. 4. An evaporative cooler system as set forth in claim 3 wherein said distribution cap includes an inverted trough disposed above said spray bar and wherein said plurality of holes are oriented to spray water at selected angles to impinge upon said distribution cap to achieve a desired water distribution. 5. An evaporative cooler system as set forth in claim 1 including: a) a further spray bar in general alignment with said spray bar; b) a further constant flow valve for controlling the flow of water to said further spray bar; and c) a further plurality of holes disposed in said further spray bar for discharging water onto the media module, said further plurality of holes defining in the aggregate an area equivalent to or less than twenty five percent (25%) of the internal cross sectional area of said further spray bar. 6. An evaporative cooler system as set forth in claim 5 wherein said plurality of holes and said further plurality of holes are equally spaced along said spray bar and said further spray bar, respectively. 7. An evaporative cooler system as set forth in claim 5 including a distribution cap and a further distribution cap for distributing water from said spray bar and said further spray bar, respectively, onto the media module. 8. An evaporative cooler system as set forth in claim 7 wherein each of said distribution cap and said further distribution cap includes an inverted trough disposed above said spray bar and said further spray bar, respectively, and wherein said plurality of holes and said further plurality of holes are oriented to spray water at selected angles to impinge upon said distribution cap and said further distribution cap, respectively, to achieve a desired water distribution. 9. An evaporative cooler system as set forth in claim 1 including first and second sensors for sensing the temperature and humidity, respectively, of the air drawn into the media module, third and fourth sensors for sensing the temperature and humidity, respectively, of the air drawn from the media module, a microprocessor responsive to said first, second, third and fourth sensors for controlling the constant flow valve and the air flow through the media. 10. An evaporative cooler system as set forth in claim 9 including a fifth sensor for sensing the speed of the air flow and a sixth sensor for sensing the media differential pressure, said controller being responsive to said fifth and sixth sensors. 11. An evaporative cooler system as set forth in claim 10 including a seventh sensor for sensing the pressure differential of the air flow upstream and downstream of the media, said controller being responsive to said seventh sensor. 12. An evaporative cooler system, said system comprising in combination: a) a source of water; b) a media module; c) a device for drawing air through said media module; d) a water distribution unit in fluid communication with said source of water for distributing water onto said media module; e) a sump for collecting water from said media module and including a drain for draining the collected water; f) said water distribution unit including a spray bar having a plurality of holes for discharging streams of water, said plurality of holes defining in the aggregate an area equivalent to or less than twenty five percent (25%) of the internal cross sectional area of said spray bar; and g) a distribution cap for diverting the streams of water onto said media module. 13. An evaporative cooler system as set forth in claim 12 including a constant flow valve for controlling the flow of water from said source of water to said spray bar. 14. An evaporative cooler system as set forth in claim 13 wherein said water distribution unit includes a further spray bar, having a further plurality of holes for discharging further streams of water, said further plurality of holes defining in the aggregate a further area equivalent to or less than twenty five percent (25%) of the internal cross sectional area of said further spray bar, and a further distribution cap for diverting the further streams of water onto said media module. 15. An evaporative cooler system as set forth in claim 13 including first and second sensors for sensing the temperature of the air flowing onto said media module and for sensing the temperature of the air drawn from said media module, respectively, and a controller for controlling the flow of water from said constant flow valve and the speed of the air flow in response to said first and second sensors. 16. An evaporative cooler system as set forth in claim 15 including third and fourth sensors for sensing the relative humidity of the air flowing into said media module and for sensing the relative humidity of the air drawn from said media module, respectively, said controller being responsive to said third and fourth sensors. 17. An evaporative cooler system as set forth in claim 16 including a fifth sensor for sensing the speed of the air flow, said controller being responsive to said fifth sensor. 18. An evaporative cooler system as set forth in claim 16 including a pressure differential sensor for sensing the pressure differential across said media module, said controller being responsive to said pressure differential sensor. 19. An evaporative cooler system as set forth in claim 15 including a water temperature sensor for sensing the temperature of the water flowing to said spray bar, said controller being responsive to said water temperature sensor. 20. An evaporative cooler system as set forth in claim 15 including a differential pressure sensor for sensing the difference in pressure between the air downstream of said media module and the air downstream of said device, said controller being responsive to said differential pressure sensor. 21. An evaporative cooler system as set forth in claim 12 including at least one further media module to form an array of at least two media modules, each of said further media modules including: a) a further water distribution unit in fluid communication with said source of water for distributing water onto said further media module; b) a further sump for collecting water from said further media module and including a further drain for draining the collected water; c) each of said further water distribution units including a further spray bar having a plurality of further holes for discharging further streams of water, said further plurality of holes defining in the aggregate an area equivalent to or less than twenty five percent (25%) of the cross sectional area of said further spray bar; and d) a further distribution cap for diverting the further streams of water onto said further media module. 22. A method for operating an evaporative cooler system, said method comprising the steps of: a) providing a source of water; b) drawing air through a media module with a device; c) distributing water from the source of water to the media module; d) collecting water draining from the media and draining the collected water; e) said step of distributing including the step of discharging a plurality of streams of water from a spray bar having a plurality of holes of an aggregate area equivalent to or less than twenty five percent (25%) of the cross sectional area of the spray bar; and f) diverting the streams of water with a distribution cap onto the media module. 23. The method as set forth in claim 22 including the step of: a) sensing the temperature of the air flowing into and out of the media module; and b) controlling the flow of water distributed to the media module with a controller responsive to said step of sensing. 24. The method as set forth in claim 23 including the steps of: a) further sensing the relative humidity of the air flowing into and out of the media module; b) further controlling the flow of water distributed to the media module with the controller in response to said step of further sensing. 25. The method as set forth in claim 24 including the steps of: a) yet further sensing the differential pressure across the media module; and b) yet further controlling the flow of water distributed to the media module with the controller in response to said step of yet further sensing. 26. The method as set forth in claim 23 including the steps of: a) determining the temperature of the water flowing to the media module; and b) regulating the flow of water distributed to the media module with the controller in response to said step of determining. 27. The method as set forth in claim 23 including the steps of: a) determining the speed of the air flow urged by the device; and b) controlling the speed of the device with the controller in response to said step of determining. 28. The method as set forth in claim 23 including the steps of: a) determining the differential pressure of the air downstream of the media module and the air downstream of the device; and b) controlling the flow of water distributed to the media with the controller in response to said step of determining. 29. The method as set forth in claim 22 including an array of a plurality of media modules and repeating each of steps a), b), c), d), e), and f) for each media module. 30. The method as set forth in claim 29 including the steps of: a) sensing the temperature of the air flowing into and out of the array of media modules; and b) controlling the flow of water to the media modules with a controller responsive to said step of sensing.