Patent ID: 7510174
Filing Date: 2009-03-31
Classification: F28C,F28F,Y02B,Y10S

Abstract:
1. A method of designing a cooling tower to cool water to a temperature less than the ambient wet bulb temperature, the cooling tower including a housing, said method comprising the steps of: a) establishing a process flow diagram by connecting and establishing air side and liquid side process relationships of components in the cooling tower including the process to be cooled by the cooling tower, wherein the components include the cooling tower, a cooling, tower inlet air to water heat exchanger, and the associated pumps, valves, instrumentation, and controls; b) further establishing the design ambient conditions (dry bulb, wet bulb, and dew point temperatures); c) identifying the process heat load (BTU/hr) to be rejected by the cooling tower and the upper limit for the coolant return temperature; d) conducting a preliminary sizing for the cooling tower using the subject process heat load with a 2 degree approach temperature and a 0.5 l/g ratio; e) using the ambient air temperature and the upper limit for the coolant return temperature to determine whether the air to water heat exchanger coolant is to be cooled in the cooling tower or in a separate tower or cell as a function of the cooling tower size and air flow, and inlet air heat exchanger coolant return temperatures and wherein the maximum return temperature being limited to less than 30 degrees of the design ambient dry bulb temperature may suggest the use of a separate cell to cool the inlet air heat exchanger; f) establishing a rough cut for the air to water heat exchanger air flow and heat load using the ambient conditions and preliminary cooling tower sizing information; g) developing a preliminary heat transfer surface area sizing for the cooling tower air inlet heat exchanger; h) determining the post sensible cooling air outlet dry bulb and wet bulb conditions for the cooling tower inlet air heat exchanger; i) further determining the approach temperature for the cooling tower and the approach temperature for the inlet air heat exchanger such that the sum of these approach temperatures is equal to the difference between the dry bulb and wet bulb temperatures of the air entering the cooling tower; j) sizing the heat exchanger to produce sensibly cooled air having the desired dry bulb temperature; k) using the sizing data and associated performance information produced; and l) optimizing the cooling tower size and parameters along with the cooling tower inlet air heat exchanger in an iterative manner to arrive at performance parameters that will produce sufficient coolant to cool the cooling tower inlet air heat exchanger and produce the designed cooling tower performance.