This work describes how the methods of control system analysis and design can be applied to meet performance requirements of an instrument. The basic methods and steps are: mathematical modelling of the instrument, analysis of performance and stability, design modifications to provide satisfactory performance, simulation by computer to verify the design, implementing the modification into the instrument, and verification of the proposed design by tests. Nomenclature (see Fig 2) cm distance (Fig 2) (in) 4 ~ b effective area at nozzle side of booster enclosure (in2) Ac effective area of feedback bellow (in2) And effective area of sensing diaphragm (in2) A~ effective area at output side of booster enclosure (in~) h distance (Fig 2) (in) C,, capacitance of compensation ((Ibm -in2)/Ibf); see Fig 6 Cb capacitance of nozzle side of booster ((Ibm -in2)/ lbf) C~ capacitance of feedback bellow «(lbm-in2)/lbf) '~, capacitance of output enclosure of booster «(lbm-in2)/lbf) d distance (Fig 2) (in) e clearance at nozzle (in) Fd sensing diaphragm force (Ibf) F~d feedback bellow force (Ibf) Ff7 fulcrum force (1bf) F,~ spring force (lbfg distance (Fig 2) (in) k~ spring constant of feedback bellow (Ibf/in) kd sensing diaphragm spring constant (Ibf/in) ko spring constant at the output of booster (Ibf/in) ks spring constant of range spring (Ibf/in) k, valve constant for supply air (lbm/(s-in)) L distance (Fig 2) (in) I distance (Fig 2) (in) Pa a pressure of compensation (lbf/in'); see Fig 6 Pb pressure at nozzle side of booster enclosure (lbf/in2) Pc pressure of feedback bellow (Ibf/in~ 2) p, pressure of nozzle tip (Ibf/in-) po pressure at output side of booster enclosure (Ibf/ur) p, supply pressure (lbf/in') £p p i -pz pressure difference at measuring diaphragms (Ibf/in'2) R resistance of compensation (s/in'); see Fig 6 Ri resistance of compensation (s/in2); see Fig 6 R~ tubing resistance between output and feedback s/in~~R a resistance of compensation (s/in2); see Fig 6 R~, b tubing resistance between nozzle and booster (s/in2) T'1 booster relay time-constant (s); see Eqn (12) T2 feedback bellow time constant (s); see Eqn (12) 7g time constant of compensation (s); see Eqn (13) T4 time constant of compensation (s); see Eqn (13) T,, time constant of compensation (s); see Eqn (13) T~ nozzle feedback time-constant (s); see Eqn (12) x booster diaphragm displacement (in) xd motion of sensing diaphragm (in) xfd motion of feedback bellow (in) x~~, motion of fulcrum (in) xp motion of adjustment screw (in) xs displacement at range spring (in) y distance (Fig 2) (in) z distance (Fig 2) (in) Note: 51 units for corresponding imperial units Ibm, lbf, in, are kg, N, m, respectively.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.