Theoretical and Experimental Studies of a Digital Flow Booster Operating at High Pressures and Flow Rates
The switched inertance hydraulic converter (SIHC) is a new technology providing an alternative to conventional proportional or servo-valve-controlled systems in the area of fluid power. SIHCs can adjust or control flow and pressure by means of using digital control signals that do not rely on thrott...
Main Authors: | , , , |
---|---|
Format: | Article |
Language: | English |
Published: |
MDPI AG
2020-02-01
|
Series: | Processes |
Subjects: | |
Online Access: | https://www.mdpi.com/2227-9717/8/2/211 |
id |
doaj-b0143c7a05d549909425ed8dd4a1d82d |
---|---|
record_format |
Article |
spelling |
doaj-b0143c7a05d549909425ed8dd4a1d82d2020-11-25T02:16:09ZengMDPI AGProcesses2227-97172020-02-018221110.3390/pr8020211pr8020211Theoretical and Experimental Studies of a Digital Flow Booster Operating at High Pressures and Flow RatesChenggang Yuan0Vinrea Lim Mao Lung1Andrew Plummer2Min Pan3Centre for Power Transmission and Motion Control, Department of Mechanical Engineering, University of Bath, Claverton Down BA2 7AY, UKCentre for Power Transmission and Motion Control, Department of Mechanical Engineering, University of Bath, Claverton Down BA2 7AY, UKCentre for Power Transmission and Motion Control, Department of Mechanical Engineering, University of Bath, Claverton Down BA2 7AY, UKCentre for Power Transmission and Motion Control, Department of Mechanical Engineering, University of Bath, Claverton Down BA2 7AY, UKThe switched inertance hydraulic converter (SIHC) is a new technology providing an alternative to conventional proportional or servo-valve-controlled systems in the area of fluid power. SIHCs can adjust or control flow and pressure by means of using digital control signals that do not rely on throttling the flow and dissipation of power, and provide hydraulic systems with high-energy efficiency, flexible control, and insensitivity to contamination. In this article, the analytical models of an SIHC in a three-port flow-booster configuration were used and validated at high operating pressure, with the low- and high-pressure supplies of 30 and 90 bar and a high delivery flow rate of 21 L/min. The system dynamics, flow responses, and power consumption were investigated and theoretically and experimentally validated. Results were compared to previous results achieved using low operating pressures, where low- and high-pressure supplies were 20 and 30 bar, and the delivery flow rate was 7 L/min. We concluded that the analytical models could effectively predict SIHC performance, and higher operating pressures and flow rates could result in system uncertainties that need to be understood well. As high operating pressure or flow rate is a common requirement in hydraulic systems, this constitutes an important contribution to the development of newly switched inertance hydraulic converters and the improvement of fluid-power energy efficiency.https://www.mdpi.com/2227-9717/8/2/211digital hydraulicsswitched inertance hydraulic systemshigh-speed switching valvespressure boosterflow boosterefficient fluid power |
collection |
DOAJ |
language |
English |
format |
Article |
sources |
DOAJ |
author |
Chenggang Yuan Vinrea Lim Mao Lung Andrew Plummer Min Pan |
spellingShingle |
Chenggang Yuan Vinrea Lim Mao Lung Andrew Plummer Min Pan Theoretical and Experimental Studies of a Digital Flow Booster Operating at High Pressures and Flow Rates Processes digital hydraulics switched inertance hydraulic systems high-speed switching valves pressure booster flow booster efficient fluid power |
author_facet |
Chenggang Yuan Vinrea Lim Mao Lung Andrew Plummer Min Pan |
author_sort |
Chenggang Yuan |
title |
Theoretical and Experimental Studies of a Digital Flow Booster Operating at High Pressures and Flow Rates |
title_short |
Theoretical and Experimental Studies of a Digital Flow Booster Operating at High Pressures and Flow Rates |
title_full |
Theoretical and Experimental Studies of a Digital Flow Booster Operating at High Pressures and Flow Rates |
title_fullStr |
Theoretical and Experimental Studies of a Digital Flow Booster Operating at High Pressures and Flow Rates |
title_full_unstemmed |
Theoretical and Experimental Studies of a Digital Flow Booster Operating at High Pressures and Flow Rates |
title_sort |
theoretical and experimental studies of a digital flow booster operating at high pressures and flow rates |
publisher |
MDPI AG |
series |
Processes |
issn |
2227-9717 |
publishDate |
2020-02-01 |
description |
The switched inertance hydraulic converter (SIHC) is a new technology providing an alternative to conventional proportional or servo-valve-controlled systems in the area of fluid power. SIHCs can adjust or control flow and pressure by means of using digital control signals that do not rely on throttling the flow and dissipation of power, and provide hydraulic systems with high-energy efficiency, flexible control, and insensitivity to contamination. In this article, the analytical models of an SIHC in a three-port flow-booster configuration were used and validated at high operating pressure, with the low- and high-pressure supplies of 30 and 90 bar and a high delivery flow rate of 21 L/min. The system dynamics, flow responses, and power consumption were investigated and theoretically and experimentally validated. Results were compared to previous results achieved using low operating pressures, where low- and high-pressure supplies were 20 and 30 bar, and the delivery flow rate was 7 L/min. We concluded that the analytical models could effectively predict SIHC performance, and higher operating pressures and flow rates could result in system uncertainties that need to be understood well. As high operating pressure or flow rate is a common requirement in hydraulic systems, this constitutes an important contribution to the development of newly switched inertance hydraulic converters and the improvement of fluid-power energy efficiency. |
topic |
digital hydraulics switched inertance hydraulic systems high-speed switching valves pressure booster flow booster efficient fluid power |
url |
https://www.mdpi.com/2227-9717/8/2/211 |
work_keys_str_mv |
AT chenggangyuan theoreticalandexperimentalstudiesofadigitalflowboosteroperatingathighpressuresandflowrates AT vinrealimmaolung theoreticalandexperimentalstudiesofadigitalflowboosteroperatingathighpressuresandflowrates AT andrewplummer theoreticalandexperimentalstudiesofadigitalflowboosteroperatingathighpressuresandflowrates AT minpan theoreticalandexperimentalstudiesofadigitalflowboosteroperatingathighpressuresandflowrates |
_version_ |
1724892480369852416 |