Cooling Tower Design Calculation Software
BAC’s Product Selection Software contains performance and technical data for all of BAC’s evaporative cooling products: Cooling Towers, Closed Circuit Cooling Towers, and Evaporative Condensers. The software provides: Equipment Selections: • Input design conditions and obtain best model selections • Select a model and obtain its performance capability • Generate performance curves Technical Information: • Dimensions, weights, motor horsepower, connections sizes, layout restrictions, etc. • Sound level data • Equipment specifications • CAD Drawings In order to access the available Product Selection Software programs, you must either or for The Loop. The ENDURADRIVE Fan System mobile Total Cost of Ownership (TCO) Calculator is available on both iOs and Droid Platforms. This tool calculates the additional costs you may not have included when considering your cooling tower drive system. These extra costs include: energy costs, energy demand charge, life expectancy, maintenance, and labor costs over the life of the equipment.
Be sure to calculate your total savings over the life of your equipment. The ENDURADRIVE Fan System is currently available for the. Shablon prajs lista dlya salona krasoti.
Cooling Tower Calculation, free cooling tower calculation software downloads.
Krossvord na kazahskom yazike onlajn. How Do I Install This On My Mobile Device? Android: From Chrome for Android, tap the menu button and tap Add to homescreen. Enter a name for the shortcut and then add it to your home screen. IPhone, iPad, & iPod Touch: From Safari for Apple’s iOS, tap the Share button on the browser’s toolbar (rectangle with an arrow pointing upward). It’s on the bar at the top of the screen on an iPad, and on the bar at the bottom of the screen on an iPhone or iPod Touch.
Tap the Add to Home Screen icon in the Share menu. Enter a name for the shortcut and then add it to your home screen. In order to access the ENDURADRIVE Fan System TCO Calculator, you must either or for The Loop.
The cooling tower itself should be modeled as a tank with design data entered through the Tank property grid as shown in Figure 3. • Elevation should be set to the elevation of the bottom of the basin of the cooling tower. • Surface Pressure should be set to 0.0 psig if the cooling tower is open to atmosphere. If the cooling tower is pressurized or under vacuum, the pressure (or vacuum) exerted on the surface of the liquid should be entered.
• Liquid Level should be set to the level of the liquid as measured from the bottom of the tank, typically the basin depth (5 feet in the model shown above) for cooling towers. Click the Penetrations field of the Tank's property grid to open the Tank Penetrations dialog box, shown in Figure 4. This is where you must specify the Penetration Height of each pipe connected to the tank. For example, the return sprayers come in to the top of the cooling tower at 20 feet measured from the bottom of the tower. The outlet pipe to the suction of the pump penetrates the tower at the bottom of the tank, or 0 feet. The default penetration height is 0 feet (or meters if metric units are selected).
Figure 4. Tank Penetrations dialog box to define the height at which each pipe enters the tank, as measured from the Bottom Elevation of the tank. For reference to older versions of PIPE-FLO see.