Design and Experiments of a Bionic Hook-Shape Subsoiler

Based on study of morphology of animal claws and subsoiling characteristics of subsoiler, a bionic hook-shape subsoiler is designed to decrease its operating resistance and to improve the terrain surface morphology. Design concepts and the structure scheme of the subsoiler are presented. The influences of tillage depth and operating speed on the operating resistance of bionic hook-shape subsoiler are examined in soil bin experimental tests by compared with a standard arc-shape subsoiler regulated by national standard (JB/T 9788-1999). It is proved by experiment results that the bionic hook-shape subsoiler when the operating speed range is 4-5km / h, compared with the standard arc-shape subsoiler, showed much lower operating resistance and power requirement against soil. The resistance-decrease index of the bionic hook-shape subsoiler is 24.1%, 24.4% and 26.5% at 300, 350 and 400mm cutting depth, respectively.

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Design and Experimental Investigation of a Bionic Subsoiler with a Multiplex-Modality Shank

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.184-185.125 ◽

2012 ◽

Vol 184-185 ◽

pp. 125-129

Author(s):

Qiang Zhang ◽

Lu Lu Yu ◽

Yu Jing Sun ◽

Miao Hao ◽

Lu Zhang ◽

...

Keyword(s):

National Standard ◽

Forward Speed ◽

Cutting Depth ◽

Power Requirement ◽

Design Concepts ◽

Claw Morphology ◽

Arc Shape ◽

Structure Scheme ◽

Tillage Depth ◽

Soil Bin

Based on study of animal-claw morphology, a multiplex-modality subsoiler is designed with an intention to decrease its operating resistance. Design concepts and structure scheme of the subsoiler are presented. To analyze the performance of multiplex-modality subsoiler, a multiplex modality sub-soiling shovel and a national standard regulated arc-shape subsoiler (JB/T 9788-1999) are tested in soil bin. Effect of tillage depth and operating speed on the operating resistance of sub-soiling shovels is examined. Type of subsoilers, tillage depth and forward speed, with 2, 3 and 3 levels taken respectively, are considered in experiment. Experiment results show that the multiplex-modality subsoiler, compared with the standard arc-shape subsoiler, sees much lower operating resistance and power requirement against soil. Resistance-decreased index of the multiplex modality subsoiler are 45.3%, 34.4% and 34.2% at 300, 350 and 400mm cutting depth, respectively.

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Microprocessor controlled DC power supply for the generator control unit of a future aircraft generator with a wide operating speed range

Second IEE International Conference on Power Electronics, Machines and Drives ◽

10.1049/cp:20040331 ◽

2004 ◽

Cited By ~ 3

Author(s):

C. Cossar

Keyword(s):

Power Supply ◽

Control Unit ◽

Operating Speed ◽

Dc Power ◽

Speed Range ◽

Dc Power Supply ◽

Wide Operating

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Hybrid Active Vibration Control of Rotorbearing Systems Using Piezoelectric Actuators

Journal of Vibration and Acoustics ◽

10.1115/1.2930303 ◽

1993 ◽

Vol 115 (1) ◽

pp. 111-119 ◽

Cited By ~ 42

Author(s):

A. B. Palazzolo ◽

S. Jagannathan ◽

A. F. Kascak ◽

G. T. Montague ◽

L. J. Kiraly

Keyword(s):

Vibration Control ◽

Search Algorithm ◽

Active Vibration Control ◽

Piezoelectric Actuators ◽

Operating Speed ◽

Speed Range ◽

Active Vibration ◽

Linear Fit ◽

Hybrid Interface ◽

Grid Search Algorithm

The vibrations of a flexible rotor are controlled using piezoelectric actuators. The controller includes active analog components and a hybrid interface with a digital computer. The computer utilizes a grid search algorithm to select feedback gains that minimize a vibration norm at a specific operating speed. These gains are then downloaded as active stiffnesses and dampings with a linear fit throughout the operating speed range to obtain a very effective vibration control.

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Modal Analysis of a High-Speed Turbomachinery for Reliable Prediction of RD Properties Throughout Operating Speed Range

Rotating Machinery, Optical Methods & Scanning LDV Methods, Volume 6 - Conference Proceedings of the Society for Experimental Mechanics Series ◽

10.1007/978-3-030-12935-4_7 ◽

2019 ◽

pp. 71-74

Author(s):

Yuhei Shindo ◽

Kazuhiko Adachi ◽

Satoshi Kawasaki ◽

Mitsuru Shimagaki

Keyword(s):

Modal Analysis ◽

High Speed ◽

Operating Speed ◽

Reliable Prediction ◽

Speed Range

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Using Dynamic Analysis for Compact Gear Design

Volume 8: 1998 Power Transmission and Gearing Conference ◽

10.1115/detc98/ptg-5785 ◽

1998 ◽

Author(s):

Ping-Hsun Lin ◽

Hsiang Hsi Lin ◽

Fred B. Oswald ◽

Dennis P. Townsend

Keyword(s):

Dynamic Response ◽

Bending Strength ◽

Three Dimensional ◽

Spur Gear ◽

Dynamic Factor ◽

Operating Speed ◽

Gear Design ◽

Dynamic Factors ◽

Speed Range ◽

Response Change

Abstract This paper presents procedures for designing compact spur gear sets with the objective of minimizing the gear size. The allowable tooth stress and dynamic response are incorporated in the process to obtain a feasible design region. Various dynamic rating factors were investigated and evaluated. The constraints of contact stress limits and involute interference combined with the tooth bending strength provide the main criteria for this investigation. A three-dimensional design space involving the gear size, diametral pitch, and operating speed was developed to illustrate the optimal design of spur gear pairs. The study performed here indicates that as gears operate over a range of speeds, variations in the dynamic response change the required gear size in a trend that parallels the dynamic factor. The dynamic factors are strongly affected by the system natural frequencies. The peak values of the dynamic factor within the operating speed range significantly influence the optimal gear designs. The refined dynamic factor introduced in this study yields more compact designs than AGMA dynamic factors.

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Thermally Induced Synchronous Instability of a Radial Inflow Overhung Turbine: Part I

Volume 1B: 16th Biennial Conference on Mechanical Vibration and Noise ◽

10.1115/detc97/vib-4063 ◽

1997 ◽

Author(s):

H. B. Faulkner ◽

W. F. Strong ◽

R. G. Kirk

Keyword(s):

Thermal Expansion ◽

Operating Speed ◽

Lateral Motion ◽

Turbine Wheel ◽

Thermally Induced ◽

Lateral Dynamics ◽

Morton Effect ◽

Speed Range ◽

Differential Thermal Expansion ◽

Rotor Dynamic

Abstract This paper is in two parts, and concerns the lateral dynamics of a large turbocharger rotor with overhung wheels. Initial rotor dynamic analysis indicated no excessive motion in the operating speed range. However, testing showed excessive motion, which was initially traced to the radial-inflow turbine wheel becoming loose on the shaft, due to transient differential thermal expansion in the wheel on startup. The attachment of the wheel was modified to eliminate this problem. The discussion up to this point is in Part I of the paper, and the remainder is in Part II. The wheel attachment modification extended the range of satisfactory operation upward considerably, but excessive lateral motion was again encountered near the upper end of the operating speed range. This behavior was traced to thermal bowing of the shaft at the turbine end, known as the Morton Effect. The turbine end bearing was modified to eliminate this problem, and satisfactory operation was then achieved throughout the operating speed range.

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Improvement of Harvesters for Tires by Means of Multi-Physics Simulation

Volume 3: 19th International Conference on Advanced Vehicle Technologies; 14th International Conference on Design Education; 10th Frontiers in Biomedical Devices ◽

10.1115/detc2017-67301 ◽

2017 ◽

Cited By ~ 1

Author(s):

Alberto Doria ◽

Cristian Medè ◽

Daniele Desideri ◽

Alvise Maschio ◽

Federico Moro

Keyword(s):

Working Conditions ◽

Experimental Tests ◽

Single Mode ◽

Fe Model ◽

Natural Period ◽

Impulse Duration ◽

Speed Range ◽

Physics Simulation ◽

Numerical Finite Element ◽

Specific Working

The specific working conditions of piezoelectric harvesters for scooter tires are analyzed. Calculated and experimental results show that the excitation of the harvester can be considered a series of separated impulses. Harvester response to an ideal impulse is analyzed with a single-mode model. An optimal ratio between impulse duration and natural period of the harvester that maximizes harvester excitation is found. A numerical finite element (FE) model of a bimorph cantilever harvester is developed in COMSOL and validated by means of experimental tests. The validated FE model is used for showing that an actual harvester excited by road impulses generates a large voltage only if there is a specific relation between impulse duration and natural period of the harvester. Starting from the validated FE model, small harvesters suited to tires are developed and analyzed. Also these harvesters show the best performance for a specific range of impulse durations, which corresponds to the highest speeds of the speed range of the scooter (50–80 km/h) and to high levels of acceleration.

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Experimental Evaluation of Multiplane-Multispeed Rotor Balancing Through Multiple Critical Speeds

Journal of Engineering for Industry ◽

10.1115/1.3439062 ◽

1976 ◽

Vol 98 (3) ◽

pp. 988-998 ◽

Cited By ~ 7

Author(s):

J. M. Tessarzik ◽

R. H. Badgley ◽

D. P. Fleming

Keyword(s):

Experimental Tests ◽

Influence Coefficient ◽

Critical Speeds ◽

Vibration Data ◽

Vibration Sensors ◽

Flexible Rotors ◽

Speed Range ◽

Full Speed ◽

Influence Coefficient Method ◽

Rotor Balancing

Experimental tests have been conducted to further demonstrate the ability of the Influence Coefficient Method to achieve precise balance of flexible rotors of virtually any design for operation through virtually any speed range. Four distinct practical aspects of flexible-rotor balancing were investigated in the present work: (1) Balancing for operation through multiple bending critical speeds; (2) balancing of rotors mounted in both rigid and flexible bearing supports, the latter having significantly different stiffnesses in the horizontal and vertical directions so as to cause severe ellipticity in the vibration orbits; (3) balancing of rotors with various amounts of measured vibration response information (e.g., numbers of vibration data sets, and numbers and types of vibration sensors), and with different number of correction planes; (4) balancing of rotors with different (though arbitrary) initial unbalance configurations. Tests were made on a laboratory quality machine having a 122-cm (48-in.) long rotor weighing 50 kg (110 lb) and covering a speed range up to 18,000 rpm. The balancing method was found in every instance to be effective, practical, and economical, permitting safe rotor operation over the full speed range covering four rotor bending critical speeds.

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Lateral Rotordynamic Analysis of a Large Alternator/Flywheel/Motor Train

Volume 6: Structures and Dynamics, Parts A and B ◽

10.1115/gt2010-23585 ◽

2010 ◽

Author(s):

Jawad Chaudhry ◽

Tim Dimond ◽

Amir Younan ◽

Paul Allaire

Keyword(s):

Critical Speed ◽

Operating Speed ◽

Response Level ◽

Critical Speeds ◽

The Third ◽

Unbalance Response ◽

Speed Range ◽

Stress Levels ◽

Full Speed ◽

Working Day

A large alternator/flywheel/motor train is employed as part of the power system for the ALCATOR C-MOD experiment at the MIT Plasma Fusion Center. The alternator is used to provide peak pulse power of 100 MW to the magnets employed in the fusion experiment. The flywheel diameter is 3.3m and the alternator is 1.8 m in diameter. After being driven up to full speed over a long period of time by a 1491 kW motor, the alternator is rapidly decelerated from approximately 1800 rpm to 1500 rpm during a 2 second interval. This sequence is repeated about six times per working day on average. A full lateral rotordynamic analysis of the including the rotors, fluid film bearings and unbalanced motor magnetic force was carried to assess the effects of rotor modifications in the alternator shaft bore. This paper provides a more detailed analysis of a complicated rotor train than is often performed for most rotors. Critical speeds, stability and unbalance response were evaluated to determine if lateral critical speeds might exist in the operating speed range in the existing or modified rotor train and if unbalance levels were within acceptable ranges. Critical speeds and rotor damping values determined for the rotor system with the existing and modified rotor. The first critical speed at 1069 rpm is an alternator mode below the operating speed range. The second critical speed is also an alternator mode but, at 1528 rpm, is in the rundown operating speed range. The third critical speed is a flywheel mode at 1538 rpm, also in the rundown operating speed range but well damped. The predicted highest rotor amplitude unbalance response level is at 1633 rpm, again in the operating speed range. Direct comparisons were made with measured bearing temperature values, with good agreement between calculations and measurements. Stress levels in the rotor were evaluated and found to be well below yield stress levels for the material for both original and modified rotors. Comparisons we carried out between standard vibration specifications and measured vibration levels which indicated that the third critical speed amplification factors were much higher than API standards indicate they should have been. Corrective actions to reduce unbalance were taken for the modified rotor.

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