Fourbar 3 Precision Points Synthesis Solution ( 1 of 2 ) - Video

Tutorial Description
The resulting fourbar mechanism from a dyadic synthesis. Using the arbitrary free choices we used in the synthesis process, the resulting fourbar mechanism is a crank-rocker (Non-Grashof). This example demonstrate that with this dyadic synthesis method, there is no guarantee on the type of mechanism (Grashof or Non-Grashof) you will get. There is also no guarantee that the mechanism will pass through all 3 points in one configuration (crossed/ uncrossed). This is the simulation where the crank (R2) rotate 360 degree with uncrossed configuration. In this configuration, the mechanism is able to pass through the only one points. The crossed configuration pass through the remaining two points - please see part 2 of this video: "Fourbar 3 Precision Points Synthesis Solution ( 2 of 2 )" http://www.youtube.com/watch?v=9Beymhbu-mM Note: The first version of this video have a wrong title in the simulation - instead of "Fourbar Synthesis: 3 Precision Points", it was "Limiting Position: Fourbar (Crank-Rocker)". This version updated this error. The first version of this simulation can be found here: http://www.youtube.com/watch?v=DqFcG_h15x8 This is an example used in the Dyadic Synthesis in MAE412/512 Machines and Mechanism II class at the State University of New York at Buffalo, Mechanical & Aerospace Engineering Department. For more information, visit: http://www.eng.buffalo.edu/~llee3/ http://mechatronics.eng.buffalo.edu/
Fourbar 3 Precision Points Synthesis Solution ( 1 of 2 ) - Video

Fourbar 3 Precision Points Synthesis Solution ( 2 of 2 ) - Video

Tutorial Description
The resulting fourbar mechanism from a dyadic synthesis. The task is to synthesize a fourbar mechanism that will pass through three precision points using dyadic synthesis method. The three points are P1(30,5), P2(15,15), P3(5,30). Using the arbitrary free choices we used in the synthesis process, the resulting fourbar mechanism is a crank-rocker (Non-Grashof). This example demonstrate that with this dyadic synthesis method, there is no guarantee on the type of mechanism (Grashof or Non-Grashof) you will get. There is also no guarantee that the mechanism will pass through all 3 points in one configuration (crossed/ uncrossed). The resulting fourbar mechanism is a crank-rocker. This is the simulation where the crank (R2) rotate 360 degree with crossed configuration. In this configuration, the mechanism is able to pass through the remaining two points. The uncrossed configuration pass through the remaining one point - please see part 1 of this video here: "Fourbar 3 Precision Points Synthesis Solution ( 1 of 2 )" http://www.youtube.com/watch?v=SJiYLvzhaow Note: The first version of this video have a wrong title in the simulation - instead of "Fourbar Synthesis: 3 Precision Points", it was "Limiting Position: Fourbar (Crank-Rocker)". This version updated this error. The first version of this simulation can be found here: http://www.youtube.com/watch?v=JXi4UqNTboo This is an example used in the Dyadic Synthesis in MAE412/512 Machines and Mechanism II class at the State University of New York at Buffalo, Mechanical & Aerospace Engineering Department. For more information, visit: http://www.eng.buffalo.edu/~llee3/ http://mechatronics.eng.buffalo.edu/
Fourbar 3 Precision Points Synthesis Solution ( 2 of 2 ) - Video

Fourbar Mechanism (Crank-Rocker) Simulation - Video

Tutorial Description
Author: Leng-Feng Lee (llee3@eng.buffalo.edu) Description: A simulation created for Machines and Mechanism II course where I am the Teaching Assistant. Summary: Simulation of a four-bar crank-rocker mechanism. As the crank go through a 360 degree rotation, the limiting positions of the rocker is shown. A singular position also shown as the crank, coupler, and rocker all in a straight line. Shown in solid line is the un-crossed configuration and dotted line shows the crossed configuration. Movie created using MATLAB.
Fourbar Mechanism (Crank-Rocker) Simulation - Video

Limiting Position: Fourbar Mechanism (Double-Rocker) 1 of 4. - Video

Tutorial Description
MATLAB Simulation of a double-rocker four-bar mechanism to show the limiting position (angle) of both the rocker (input & output link). This simulation show the mechanism of the crossed configuration for the motion limit of input link (link 2). A animation to help understanding the concept of limiting position. Created for course MAE412/512 Machines and Mechanisms II at SUNY-Buffalo. Note: Please rate my video and send me an email if you have any questions. Thanks! =)
Limiting Position: Fourbar Mechanism (Double-Rocker) 1 of 4. - Video

Limiting Position: Fourbar Mechanism (Double-Rocker) 1 of 4. - Video

Tutorial Description
MATLAB Simulation of a double-rocker four-bar mechanism to show the limiting position (angle) of both the rocker (input & output link). This simulation show the mechanism of the crossed configuration for the motion limit of input link (link 2). A animation to help understanding the concept of limiting position. Created for course MAE412/512 Machines and Mechanisms II at SUNY-Buffalo. Note: Please rate my video and send me an email if you have any questions. Thanks! =)
Limiting Position: Fourbar Mechanism (Double-Rocker) 1 of 4. - Video

Limiting Position: Fourbar Mechanism (Double-Rocker) 2 of 2. - Video

Tutorial Description
MATLAB Simulation of a double-rocker four-bar mechanism to show the limiting position (angle) of both the rocker (input & output link). This simulation show the mechanism of both the Crossed and Uncrossed configuration for the motion limit of input link (link 2). A animation to help understanding the concept of limiting position. Created for course MAE412/512 Machines and Mechanisms II at SUNY-Buffalo. Note: Please rate my video and send me an email if you have any questions. Thanks! =)
Limiting Position: Fourbar Mechanism (Double-Rocker) 2 of 2. - Video

Limiting Position: Fourbar Mechanism (Double-Rocker) 4 of 4. - Video

Tutorial Description
MATLAB Simulation of a double-rocker four-bar mechanism to show the limiting position (angle) of both the rocker (input & output link). This simulation show the mechanism of the Crossed configuration for the motion limit of output link (link 4). A animation to help understanding the concept of limiting position. Created for course MAE412/512 Machines and Mechanisms II at SUNY-Buffalo. Note: Please rate my video and send me an email if you have any questions. Thanks! =)
Limiting Position: Fourbar Mechanism (Double-Rocker) 4 of 4. - Video

Limiting Position: Fourbar Mechanism (Rocker-Crank) 1 of 2 - Video

Tutorial Description
MATLAB Simulation of a rocker-crank four-bar mechanism to show the limiting position (angle) of the rocker (output linkis r2). This is the mechanism at the Uncrossed Configuration. A animation to help understanding the concept of limiting position. Created for course MAE412/512 Machines and Mechanisms II at SUNY-Buffalo. Note: Please rate my video and send me an email if you have any questions. Thanks! =)
Limiting Position: Fourbar Mechanism (Rocker-Crank) 1 of 2 - Video

Limiting Position: Fourbar Mechanism (Rocker-Crank) 1 of 2 - Video

Tutorial Description
MATLAB Simulation of a rocker-crank four-bar mechanism to show the limiting position (angle) of the rocker (output linkis r2). This is the mechanism at the Uncrossed Configuration. A animation to help understanding the concept of limiting position. Created for course MAE412/512 Machines and Mechanisms II at SUNY-Buffalo. Note: Please rate my video and send me an email if you have any questions. Thanks! =)
Limiting Position: Fourbar Mechanism (Rocker-Crank) 1 of 2 - Video

Limiting Position: Fourbar Mechanism (Rocker-Crank) 1 of 2 - Video

Tutorial Description
MATLAB Simulation of a rocker-crank four-bar mechanism to show the limiting position (angle) of the rocker (output linkis r2). This is the mechanism at the Uncrossed Configuration. A animation to help understanding the concept of limiting position. Created for course MAE412/512 Machines and Mechanisms II at SUNY-Buffalo. Note: Please rate my video and send me an email if you have any questions. Thanks! =)
Limiting Position: Fourbar Mechanism (Rocker-Crank) 1 of 2 - Video

Limiting Position: Fourbar Mechanism (Double-Rocker) 3 of 4. - Video

Tutorial Description
MATLAB Simulation of a double-rocker four-bar mechanism to show the limiting position (angle) of both the rocker (input & output link). This simulation show the mechanism of the Uncrossed configuration for the motion limit of output link (link 4). A animation to help understanding the concept of limiting position. Created for course MAE412/512 Machines and Mechanisms II at SUNY-Buffalo. Note: Please rate my video and send me an email if you have any questions. Thanks! =)
Limiting Position: Fourbar Mechanism (Double-Rocker) 3 of 4. - Video

Limiting Position: Fourbar Mechanism (Rocker-Crank) 2 of 2 - Video

Tutorial Description
MATLAB Simulation of a rocker-crank four-bar mechanism to show the limiting position (angle) of the rocker (output linkis r2). This is the mechanism at the Crossed Configuration. A animation to help understanding the concept of limiting position. Created for course MAE412/512 Machines and Mechanisms II at SUNY-Buffalo. Note: Please rate my video and send me an email if you have any questions. Thanks! =)
Limiting Position: Fourbar Mechanism (Rocker-Crank) 2 of 2 - Video

Limiting Position: Fourbar Mechanism (Double-Rocker) 1 of 2. - Video

Tutorial Description
MATLAB Simulation of a double-rocker four-bar mechanism to show the limiting position (angle) of both the rocker (input & output link). This simulation show the mechanism of both the Crossed and Uncrossed configuration for the motion limit of output link (link 4). A animation to help understanding the concept of limiting position. Created for course MAE412/512 Machines and Mechanisms II at SUNY-Buffalo. Note: Please rate my video and send me an email if you have any questions. Thanks! =)
Limiting Position: Fourbar Mechanism (Double-Rocker) 1 of 2. - Video

Limiting Position: Fourbar Mechanism (Double-Rocker) 1 of 2. - Video

Tutorial Description
MATLAB Simulation of a double-rocker four-bar mechanism to show the limiting position (angle) of both the rocker (input & output link). This simulation show the mechanism of both the Crossed and Uncrossed configuration for the motion limit of output link (link 4). A animation to help understanding the concept of limiting position. Created for course MAE412/512 Machines and Mechanisms II at SUNY-Buffalo. Note: Please rate my video and send me an email if you have any questions. Thanks! =)
Limiting Position: Fourbar Mechanism (Double-Rocker) 1 of 2. - Video