What is the primary purpose of the discharge coefficient Co in orifice discharge calculations?

Unlock all questions

This demo includes only 20 questions. Upgrade to access hundreds of questions, flashcards, exam simulations, and disable ads.

Full question bankExam simulationsFlashcards
From $9.99Unlock all

Prepare for the SAChE Source Models Exam with flashcards and comprehensive quizzes. Each question includes detailed explanations to ensure you get the most out of your study sessions. Aim high for your exam!

Multiple Choice

What is the primary purpose of the discharge coefficient Co in orifice discharge calculations?

Explanation:
Discharge coefficient describes how real flow through an orifice differs from the idealized case. In actual flow, the jet contracts downstream of the orifice (vena contracta), and energy is lost to friction, turbulence, viscosity, and sometimes compressibility effects. These non-ideal losses make the true discharge lower than what a simple pressure-difference calculation would predict, so Co is introduced to correct for those differences. For a given orifice geometry and flow regime, Co is determined experimentally and is typically less than 1, allowing the practical discharge equation to be written as Q = Co × A × sqrt(2 × ΔP / ρ). The other ideas—calculating hydrostatic pressure, measuring fluid density, or computing discharge temperature—aren’t what Co is used for; Co specifically accounts for non-ideal flow behavior through the orifice.

Discharge coefficient describes how real flow through an orifice differs from the idealized case. In actual flow, the jet contracts downstream of the orifice (vena contracta), and energy is lost to friction, turbulence, viscosity, and sometimes compressibility effects. These non-ideal losses make the true discharge lower than what a simple pressure-difference calculation would predict, so Co is introduced to correct for those differences. For a given orifice geometry and flow regime, Co is determined experimentally and is typically less than 1, allowing the practical discharge equation to be written as Q = Co × A × sqrt(2 × ΔP / ρ). The other ideas—calculating hydrostatic pressure, measuring fluid density, or computing discharge temperature—aren’t what Co is used for; Co specifically accounts for non-ideal flow behavior through the orifice.

More Multiple Choice Questions
Subscribe

Get the latest from Examzify

You can unsubscribe at any time. Read our privacy policy