Consider a pumping system used in a cooling water loop. Water is drawn from a tank, which maintains a height of 2 m of water. It then enters the pump and then passes through the process heat exchanger, where it is heated. The water is then cooled back to cooling water temperature using a chiller (another heat exchanger). Finally, water exits the chiller and is circulated back to the original tank, forming a closed loop. All equipment is at ground level. All pipe in the system is 2-inch schedule 40, commercial steel pipe. a. If the flowrate is 15 kg/s, determine the Fanning friction factor in the pipe using the Colebrook Equation. b. At a flowrate of 15 kg/s, the heat exchanger and chiller each have a pressure drop of 15 kPa. Estimate the equivalent length of each heat exchanger. c. In addition to the heat exchangers and 35 m of straight pipe, there are the following valves and fittings: 90° elbows Tee Open gate valve Swing check valve If the flowrate is 15 kg/s, determine the work required (in kW) for a 75% efficient pump. You may ignore entrance and exit effects. x6 x 2 x 6 x 1 d. Determine the pressure increase across the pump. e. If an orifice plate with = 0.5 is used to measure the flowrate, what would the pressure drop across the plate be? f. If the pump is 25 kW, what diameter of pipe should be used?

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1. Consider a pumping system used in a cooling water loop. Water is drawn from a tank, which maintains a height of 2 m of water. It then enters the pump and then passes through the process heat exchanger, where it is heated. The water is then cooled back to cooling water temperature using a chiller (another heat exchanger). Finally, water exits the chiller and is circulated back to the original tank, forming a closed loop. All equipment is at ground level. All pipe in the system is 2-inch schedule 40, commercial steel pipe. a. If the flowrate is 15 kg/s, determine the Fanning friction factor in the pipe using the Colebrook Equation. b. At a flowrate of 15 kg/s, the heat exchanger and chiller each have a pressure drop of 15 kPa. Estimate the equivalent length of each heat exchanger. c. In addition to the heat exchangers and 35 m of straight pipe, there are the following valves and fittings: 90° elbows Tee x 6 x 2 Open gate valve x 6 Swing check valve x 1 If the flowrate is 15 kg/s, determine the work required (in kW) for a 75% efficient pump. You may ignore entrance and exit effects. d. Determine the pressure increase across the pump. e. If an orifice plate with = 0.5 is used to measure the flowrate, what would the pressure drop across the plate be? f. If the pump is 25 kW, what diameter of pipe should be used?