Hydraulic leveling control system of harvester chassis. Hao4,d

Similar documents
Dynamic Characteristics Analysis of H-Type Leg Hydraulic System of. Truck mounted Concrete Pump

Open Access Co-Simulation and Experimental Research of Wedge Broken-Belt Catching Device

Modal Analysis of Automobile Brake Drum Based on ANSYS Workbench Dan Yang1, 2,Zhen Yu1, 2, Leilei Zhang1, a * and Wentao Cheng2

The Assist Curve Design for Electric Power Steering System Qinghe Liu1, a, Weiguang Kong2, b and Tao Li3, c

Parametric Design and Motion Analysis of Geneva Wheel Mechanism Based on the UG NX8.5

A Device for Sorting and Recycling Dry Batteries Automatically Jiahang Xia

Shimmy Identification Caused by Self-Excitation Components at Vehicle High Speed

Simulation Analysis of Certain Hydraulic Lifting Appliance under Different Working Conditions

Dynamic and Decoupling Analysis of the Bogie with Single EMS Modules for Low-speed Maglev Train

Development of Hybrid Type Flexible Pneumatic Cylinder for Considering Less Air Consumption

Design and experiment of hydraulic impact loading system for mine cable bolt

Technology, Xi an , China

Design of Damping Base and Dynamic Analysis of Whole Vehicle Transportation based on Filtered White-Noise GongXue Zhang1,a and Ning Chen2,b,*

Intelligent CAD system for the Hydraulic Manifold Blocks

Chapter 2 Dynamic Analysis of a Heavy Vehicle Using Lumped Parameter Model

International Conference on Advances in Energy and Environmental Science (ICAEES 2015)

Design of Control System for Vertical Injection Moulding Machine Based on PLC

Electromagnetic Field Analysis for Permanent Magnet Retarder by Finite Element Method

Study on Braking Energy Recovery of Four Wheel Drive Electric Vehicle Based on Driving Intention Recognition

2nd Annual International Conference on Advanced Material Engineering (AME 2016)

College of Mechanical & Power Engineering Of China Three Gorges University, Yichang, Hubei Province, China

Tooth Shape Optimization of the NGW31 Planetary Gear Based on Romax Designer

Design and Manufacture of Heavy Truck Braking Spray Device Based on PLCS7-200

Bond Graph Modeling and Simulation Analysis of the Electro-Hydraulic Actuator in Non-Load Condition

Study on the Performance of Lithium-Ion Batteries at Different Temperatures Shanshan Guo1,a*,Yun Liu1,b and Lin Li2,c 1

Study on Tractor Semi-Trailer Roll Stability Control

Applications of Frequency Conversion Technology in Aircompressor

Hardware Design of Brushless DC Motor System Based on DSP28335

Comparison of Braking Performance by Electro-Hydraulic ABS and Motor Torque Control for In-wheel Electric Vehicle

Perodua Myvi engine fuel consumption map and fuel economy vehicle simulation on the drive cycles based on Malaysian roads

Available online at ScienceDirect. Procedia CIRP 33 (2015 )

Integrated Monitoring System Design of Hybrid Aircompressors

Study on State of Charge Estimation of Batteries for Electric Vehicle

Optimization of PID Parameters of Hydraulic System of Elevating Wheelchair Based on AMESim Hui Cao a*, Hui Guo b

CHAPTER 4: EXPERIMENTAL WORK 4-1

Technical elements for minimising of vibration effects in special vehicles

International Industrial Informatics and Computer Engineering Conference (IIICEC 2015)

The Brake System and Method of the Small Vertical Axis. Wind Turbine

KINEMATICAL SUSPENSION OPTIMIZATION USING DESIGN OF EXPERIMENT METHOD

Available online at ScienceDirect. Procedia Technology 21 (2015 ) SMART GRID Technologies, August 6-8, 2015

Semi-Active Air Suspension (SAS)

ELECTROPNEUMATIC POSITIONING SYSTEM CONTROL WITH THE LEGENDARY LOGO! PLC

Optimum Matching of Electric Vehicle Powertrain

INTELLIGENT ENERGY MANAGEMENT IN A TWO POWER-BUS VEHICLE SYSTEM

Advances in Engineering Research, volume 93 International Symposium on Mechanical Engineering and Material Science (ISMEMS 2016)

Investigation of Semi-Active Hydro-Pneumatic Suspension for a Heavy Vehicle Based on Electro-Hydraulic Proportional Valve

Adjustment Performance of a Novel Continuous Variable Valve Timing and Lift System

Modeling and Simulation of Linear Two - DOF Vehicle Handling Stability

Integrated Control Strategy for Torque Vectoring and Electronic Stability Control for in wheel motor EV

Dynamic Modelling of Hybrid System for Efficient Power Transfer under Different Condition

Open Access The New Structure Design and Simulation of Preventing Electric Shock Multi-Jacks Socket

Selected Problems of Electric Vehicle Dynamics

The operating principle and experimental verification of the hydraulic electromagnetic energy-regenerative shock absorber

Experimental Investigation of Effects of Shock Absorber Mounting Angle on Damping Characterstics

China. Keywords: Electronically controled Braking System, Proportional Relay Valve, Simulation, HIL Test

Design of Active and Reactive Power Control of Grid Tied Photovoltaics

Research on Electric Hydraulic Regenerative Braking System of Electric Bus

Available online at ScienceDirect. Procedia Engineering 137 (2016 ) GITSS2015

The Testing and Data Analyzing of Automobile Braking Performance. Peijiang Chen

Analysis and Design of the Super Capacitor Monitoring System of Hybrid Electric Vehicles

PRIMAAX. - MAAXimize durability - MAAXimize driver comfort - MAAXimize performance. Severe-Duty Vocational Air Suspension

The Institute of Mechanical and Electrical Engineer, xi'an Technological University, Xi'an

Introduction. Pre-Lab

Research on Damping Characteristics of Magneto-rheological Damper Used in Vehicle Seat Suspension

Design and Analysis of Hydraulic Chassis with Obstacle Avoidance Function

POSIBILITIES TO IMPROVED HOMOGENEOUS CHARGE IN INTERNAL COMBUSTION ENGINES, USING C.F.D. PROGRAM

Collaborative vehicle steering and braking control system research Jiuchao Li, Yu Cui, Guohua Zang

COURSE LEARNING OUTCOMES

CHAPTER 2 MODELLING OF SWITCHED RELUCTANCE MOTORS

STABILIZATION OF ISLANDING PEA MICRO GRID BY PEVS CHARGING CONTROL

AUTOMATIC VEHICLE STABILIZATION SYSTEM Gaurav Pednekar 1, Raunak Borwankar 2 and Purva Sawant 3 1, 2, 3

AMT Fault Diagnosis Technology Based on Simulink and LabVIEW

2nd International Conference on Electronic & Mechanical Engineering and Information Technology (EMEIT-2012)

International Journal Of Global Innovations -Vol.2, Issue.I Paper Id: SP-V2-I1-007 ISSN Online:

Hydraulic Characteristic of Cooling Tower Francis Turbine with Different Spiral Casing and Stay Ring

A Simulation Model of the Automotive Power System Based on the Finite State Machine

Dual cycloid gear mechanism for automobile safety pretensioners

Passive Vibration Reduction with Silicone Springs and Dynamic Absorber

Key Parameters Investigation on Small Cycle Fuel Injection Quantity for a Diesel Engine Electronic Unit Pump System

Analysis and Design of Independent Pitch Control System

Optimal design of a double coil magnetorheological fluid damper with various piston profiles

Design and Analysis of suspension system components

Design and Application of Versatile Automatic Bin with Valve Splint Slide Way

International Conference on Information Sciences, Machinery, Materials and Energy (ICISMME 2015)

Advances in Engineering Research (AER), volume 102 Second International Conference on Mechanics, Materials and Structural Engineering (ICMMSE 2017)

Comparison Of Multibody Dynamic Analysis Of Double Wishbone Suspension Using Simmechanics And FEA Approach

The Improvement Research of the Freight Train Braking System Li-wei QIAO

EXPERIMENTAL HEAT TRANSFER STUDY ON THE SHOCK ABSORBER OPERATION

Numerical Study on the Flow Characteristics of a Solenoid Valve for Industrial Applications

Wireless Networks. Series Editor Xuemin Sherman Shen University of Waterloo Waterloo, Ontario, Canada

Research on the charging system of electric vehicle photovoltaic cells HUANG Jun ( Hunan Railway Professional Technology College, Zhuzhou, )

TEST STAND IN UNIVERSITY OF APPLIED SCIENCE GIESSEN FOR FRICTION FORCES MEASUREMENTS IN SLIDE BEARING USING THE ACOUSTIC EMISSION METHOD

Analysis of Structure and Process of a Robot with Obstacles

Computer Aided Transient Stability Analysis

The Application of Simulink for Vibration Simulation of Suspension Dual-mass System

Comparison of Braking Performance by Electro-Hydraulic ABS and Motor Torque Control for In-wheel Electric Vehicle

Preliminary Design of a LSA Aircraft Using Wind Tunnel Tests

Available online at ScienceDirect. Physics Procedia 67 (2015 )

Steering Performance Evaluation of Off Highway Vehicle Using Matlab Tools

I) Clamping the work piece II) Drilling the work piece. III) Unclamping the work piece. 10

Transcription:

International Forum on Energy, Environment Science and Materials (IFEESM 2017) Hydraulic leveling control system of harvester chassis Song Xiangwen1,a Cao Shukun2,b(Corresponding author) Li Shizhuang3,c Shen Hao4,d 1 2 3 4 a 751937831@qq.com b 87756997@qq.com c 1148660320@qq.com d354174809@qq.com Key words: harvester stable;oil and gas suspension; angle error control algorithm Abstract: Based on the research of the position error control algorithm and the angle error control algorithm, according to the specific characteristics of the harvester, the leveling control strategy of angle error control algorithm is proposed in this paper. Making leveling at both direction of X and Y, first adjust the direction of large angle. By reducing the hydraulic cylinder to reduce the center of the harvester and keep harvester stable. When lowing one side of the harvester unable to achieve leveling, then raising the other side. Finally, writing some programs of the whole leveling process. Introduction The existing oil and gas suspension system, the widespread use of independent oil and gas suspension system and connected hydraulic system, but in the anti-rollover performance, the connected type of oil and gas suspension can significantly improve the vehicle's anti-rollover performance, reduce the vehicle The roll angle generated when turning, so that the vehicle is more stable, and the hydraulic system is simple, so the large wheeled vehicle chassis hydraulic system and more use of connected type oil and gas suspension system. But because the traditional connected hydraulic system is not the flow control, and because we harvester front and rear bridge load is different, resulting in different pressure cylinder, resulting in different working position of the accumulator, resulting in the speed of lifting is not the same, the final body there is a tilt of the situation, or left and right roll, or roll back and forth, in short, the vehicle lift function can not be applied normally, which will harves the efficiency of harvesting, anti-rollover performance, vehicle passing and mobility to bring serious impact, so the problem seriously restricts the application of the automatic leveling function of the harvester. Design of hydraulic system for connected hydraulic system Study on the Principle of Traditional Connected Oil and Gas Suspension The schematic diagram of the traditional connected type oil and gas suspension is shown in Copyright 2018, the Authors. Published by Atlantis Press. This is an open access article under the CC BY-NC license (http://creativecommons.org/licenses/by-nc/4.0/). 331

Fig.1: 1, 4, 5, 6, 7, 8 - two-way two-way solenoid valve 2,3-accumulator 9,10- suspension cylinder Fig.1 Hydraulic model of connecting type oil and gas suspension Connect the type of oil and gas suspension system to X-type connected to the majority, that is, right front and left after the connection, left and right rear connection, such a corner increase, will inevitably lead diagonal reduction, faster and better finish body leveling. As shown in Figure 1 above, when the front right side is raised, the opening of the solenoid valve 6 opens, the oil enters the left rear hydraulic cylinder through the solenoid valve 6 and enters the right front through the solenoid valve 1 The hydraulic cylinder has no rod cavity, resulting in an increase in the right front hydraulic cylinder. As the right side of the increase, resulting in the right side of the rod cavity pressure, resulting in the left side of the hydraulic cylinder rod pressure will be increased, but because the left side of the hydraulic cylinder into the oil, the pressure will rise. So eventually lead to the right front side of the rise. When the front right side of the hydraulic cylinder increases, the right front side of the hydraulic cylinder has reduced the rod cavity, the pressure increases, resulting in a slight increase in the left rear hydraulic cylinder, but the overall increase in the right front. However, for the harvester, due to the huge difference between the front and rear axle load, the role of the pressure on both sides of the hydraulic cylinder on the pressure, resulting in different working position of the accumulator, resulting in the speed of lift is uncertain, resulting in the left and right side of the hydraulic lift Can not be synchronized. Constant flow, pressure tracking connected hydraulic system For the harvester front and rear axle bearing a huge difference caused by the left and right leveling, the one-sided hydraulic cylinder can not synchronize the lifting of the problem, the reasons for the analysis, first, because the suspension tank into the oil flow is not flow control, so that into the suspension cylinder The flow is different, this we can by adding fuel flow control valve to ensure that the flow at both ends of the same; second, can not eliminate the accumulator caused by load changes caused by the impact of oil filling, for this point, due to oil and gas suspension Flattening the various hydraulic cylinder load is different, then only in leveling, the accumulator cut off, that is, in the process of raising the accumulator will first cut off, through the control of the flow valve to extend the suspension, because there is no energy storage The impact of the flow valve can be controlled by the side of the suspension cylinder simultaneously lift. However, after leveling, due to the pressure in the accumulator and the pressure in the oil circuit is different, when re-access to the accumulator, due to the large difference in pressure, will make the hydraulic cylinder status 332

changes rapidly, resulting in hydraulic cylinder jitter, In this paper, the pressure control valve is installed in the hydraulic control system. When the accumulator is cut off, the pressure in the accumulator is kept at the same pressure as the oil in the leveling process. A schematic diagram of the synchronous lift system based on constant flow is shown in Fig 2 below. 1,21-filter 2,13,2-check valve 3,4 hydraulic cylinder 5,7,18-two-way two-way electromagnetic valve 6,8-accumulator 9,10-two-way four-way electromagnetic commutation ball valve 11,12-pressure tracking valve 14,16-three four-way electromagnetic valve 15,17-speed valve Fig.2 Schematic diagram of a synchro-ascending system based on constant flow-connected cascade The whole system hydraulic principle is: first turn off the solenoid valve 5,7, the accumulator and the suspension cylinder cut off, while opening the solenoid valve 9,10,14,16, high pressure oil to push the suspension cylinder, 15, 17, the flow rate of the one side suspension cylinder is the same, and the side suspension cylinder is simultaneously extended so that the harvester side is raised synchronously, and when the solenoid valves 9 and 10 are opened during the raising process, And the pressure tracking valves 11, 12 are allowed to operate so that the pressure in the accumulator can always follow the pressure in the suspension cylinder, i.e. the pressure in the accumulator is the same as the pressure in the suspension cylinder. When the solenoid valve 9, 10, 14, 16 is de-energized and the solenoid valves 5, 7 are energized, the high-pressure port is closed and the accumulator is connected to the system. At this time, Pressure equal, can achieve a smooth switch to ensure the smooth vehicle. Fig 2 in the ordinary hydraulic control valve works: when the control port has control of oil pressure, the pressure oil to promote the piston, and then push the cone valve spool open, so that the oil P1 to P2 and P2 to P1 are connected, When the hydraulic port K oil pressure is zero, with the ordinary one-way valve function, the oil P1 to P2 connected, P2 to P1 is not connected. Independent control of hydraulic systems However, the entire hydraulic system can be connected to the hydraulic system can ensure synchronous lifting, but because the entire oil control is complex, and the pressure tracking valve is not ready-made products, the whole device can not learn from the experience, consider the harvester control needs and costs, And the project needs, the hydraulic system does not use the connected hydraulic control system, using a relatively simple independent control hydraulic system. The hydraulic system is shown in Fig. 3 below. 333

1,15-filter 2,5-check valve 3,8,9,12-hydraulic cylinder 4 pressure gauge 6,7,10,11-three-position four-way electromagnetic valve 13-two-way two-way electromagnetic valve 14 - relief valve 16 - hydraulic pump Fig. 3 Independent control of the hydraulic control system Hydraulic oil through the three four-way electromagnetic valve to the hydraulic cylinder without rod into the oil, and then flatten the end of the one-way valve to seal the oil in the hydraulic cylinder rodless cavity, when the hydraulic cylinder need to restore, through the body Gravity, while the pressure to the pilot port, so that one-way valve to open again, the oil reflux. Conclusions This chapter determines the hydraulic control system of the oil and gas suspension using the connected hydraulic control system of oil and gas suspension, and controls the single cylinder relative to the traditional single valve, and the anti-rollover effect is better. In the analysis of the traditional loader before and after the bridge load and the traditional connected type of oil and gas suspension is insufficient, the proposed speed control valve and pressure tracking valve connected hydraulic system hydraulic control system. Acknowledgements This work was financially supported by the Shandong Province, the major project of science and technology (item number: 2015ZDZX10001) " the development and industrialization demonstration of intelligent corn combine harvester".and Taishan industry leading talent project special funds. References [1] Kyuhyun Sim, Hwayoung Lee. Effectiveness Evaluation of Hydro-pneumatic and Semi-active Cab Suspension for the Improvement of Ride Comfort of Agricultural Tractors[J]. Journal of Terramechanics,2016.Giacomin J.,Neural network simulation of an automotive shock absorber,engineering Application Artificial Intelligence,Vo1.4,No.1 Paragon Press,1991:59-64P. 334

[2] Bauer Wolfgang, Hydropneumatic suspension system[m]. Verlag Berlin Heidelberg: springer,2011. [3] H.G.Gibson,K.C.Elliott. Side slope stability of articulated-frame logging tractors[j].journal of Terra mechanics,1971(2): 65-79. [4] Ralf.Eger,Majjad.Rachid.Rollover simulation based on a Nonlinear Model[J].SAE special publications, 1998(11): 1-7.Novak A.J,Larson C.S. Computer simulation of semi-trailer haul truck roll-over dynamics. Society of Automotive Engineers[ J]. 1990, 99(2): 491-497. [5] Wilson, JN, Klassen, N.D. Sensor requirements for combine harvester control[j].soeiety of Auto motive Engineers Transactions,1991,100(2):239-247. 335

2024 © autodocbox.com Privacy Policy | Terms of Service | Feedback