| Management number | 233297135 | Release Date | 2026/06/27 | List Price | US$48.00 | Model Number | 233297135 | ||
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Master Every Propulsion Architecture That Powers Spaceflight — From Engine Cycle Selection to Real-World Design DecisionsRocket propulsion is no longer the exclusive domain of national space agencies. With reusable launch vehicles, commercial smallsats, hypersonic programs, and hybrid startups reshaping the industry, engineers at every level need a working command of propulsion fundamentals — not just the equations, but the engineering logic behind every design decision. This book delivers exactly that: a rigorous, practical, and thoroughly modern guide to how rocket engines work, why they are designed the way they are, and how to evaluate propulsion architectures for real missions.From solid motor grain geometry through liquid engine turbopump cycles, combustion instability mitigation, hybrid throttling, and advanced rotating detonation engines — every chapter builds from first principles to engineering judgment. The treatment covers what textbooks often omit: failure modes, trade-offs, selection logic, and the operational realities that separate successful engine programs from costly development setbacks.Whether you are an aerospace student, a propulsion engineer expanding across architectures, or a systems engineer who needs to evaluate engine options without being misled — this book builds the technical vocabulary and decision-making framework that real propulsion work demands.What You Will Master Inside This Book:Analyze solid rocket motor grain geometry and predict thrust profiles — understanding how cylindrical, star, wagon wheel, and finocyl perforations produce progressive, neutral, regressive, and dual-thrust profiles, applying Vieille's law with pressure exponent, temperature sensitivity, and web thickness calculations to real motor sizingSelect and evaluate liquid rocket engine cycles with engineering precision — gas-generator, staged combustion, and expander cycles mapped to performance and risk trade-offs, anchored by real engines including the F-1, RS-25, RD-180, Merlin 1D, and RaptorDesign hybrid rocket motor grain and oxidizer systems — comparing HTPB, paraffin, and polyethylene fuels against regression rate and mechanical trade-offs, evaluating LOX, nitrous oxide, and hydrogen peroxide against mission storability and performance requirementsIdentify, diagnose, and mitigate combustion instability — recognizing low-frequency feed coupling, mid-frequency acoustic coupling, and high-frequency screech using case histories from operational programs, and applying injector design, baffles, and damping cavities as countermeasuresEvaluate pulsed and rotating detonation engine architectures — quantifying the 5–15 percent Isp improvement potential over deflagration combustion and assessing RDE readiness levels for near-term operational applicationApply systematic engine selection methodology — balancing thrust, specific impulse, restart capability, storability, reusability, manufacturing infrastructure, and program risk in a structured framework matched to mission profileInterpret turbopump design fundamentals and failure modes — understanding how gas-generator cycles produce 5–40 megawatts of shaft power and why turbopump failure has historically driven more vehicle losses than combustion chamber failureBuy Now and build the propulsion engineering fluency that modern spaceflight demands. Read more
| ASIN | B0GZ81CPN4 |
|---|---|
| ISBN13 | 979-8195083922 |
| Language | English |
| Publisher | Independently published |
| Dimensions | 8.5 x 1.22 x 11 inches |
| Item Weight | 3.36 pounds |
| Print length | 541 pages |
| Publication date | May 1, 2026 |
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