Outline

Outline • Kinetics • Linear • Forces in human motion • Mechanical work, power, & energy • Impulse-momentum • Angular • Torques in human motion • Mechanical work, power, & energy • Impulse-momentum

Outline • Torques in human motion • Definitions • External force ----> muscle force (static analysis) • Review of approach • Mechanical advantage • Musculoskeletal complexity • External force ----> muscle force (dynamic analysis)

Torque (= moment) angular equivalent of force Capability of a force to produce rotation Units: N*m Importance? Muscles cause movement by creating torques about joints.

Torque (T): Capability of a force to produce rotation T = MR * F F= force MR= moment arm (perpendicular distance from the point of rotation to the line of force application) rF = distance to F MR and rFare NOT the same!! F MR rF

Torque (T): Capability of a force to produce rotation T = MR * F F= force MR= moment arm (perpendicular distance from the point of rotation to the line of force application) rF= distance to F F MR rF

What is the Torque (T) due to force F?F=100N; distance to F: rF = 1m, q=30o T = MR * F F 86.6 N 100 Nm 86.6 Nm 50 Nm 50 N MR q rF

Torque is a Vector!Right-Hand Thumb RuleFigure 2.4 r: MR (moment arm) Right-Hand Thumb Rule: 1. align your hand with MR 2. curl your fingers towards F 3. direction of thumb is direction of torque vector

Torque and the Coordinate System Direction of Positive Torque? If using default coordinate system: Use right hand thumb rule Counter-clockwise (CCW) If using flexion/extension terms: Extension is +ve! Be CONSISTENT! y x

What is the Torque (T) due to force F?F=100N; distance to F: rF = 1m, q=30o y F x MR q rF Positive Negative It Depends

Outline • Torques in human motion • Definitions • External force ----> muscle force (static analysis) • Review of approach • Mechanical advantage • Musculoskeletal complexity • External force ----> muscle force (dynamic analysis)

Example A person holds their elbow at 90° with their forearm parallel to the ground. Elbow torque? Step 1: Draw a free body diagram “system” = the forearm + hand Upper arm Forearm Elbow

Factors affecting Elbow Torque: Weight of forearm (Fw) and position of its COM From Table in Enoka(BW = 600 N) Fw (forearm+hand) = 11 N Distance from proximal end to COM is 0.16 m (MR) Fw MR

Elbow torque due to weight of forearm T=MR * F T = 0.16m * 11N T = 1.8 Nm Direction? T = -1.8Nm 11 N 0.16 m

A person holds their forearm so that it is 30° below the horizontal. Elbow torque due to forearm weight? Fw=11N; rF = 0.16m • 1.76 Nm • 1.5 Nm • 0.88 Nm • -1.5 Nm • -0.88 Nm Fw q rF

A person holds their forearm so that it is 30° below the horizontal. Elbow torque due to forearm weight?Fw=11N; rF = 0.16m 11 N MR 30° 0.16 m

Now let’s look at 2 weights

100 N 11 N A person is holding a 100N weight at a distance of 0.4 m from the elbow. What is the total elbow torque due to external forces? We must consider the effects of 2 forces: forearm (11N) weight being held (100N)

A person is statically holding a 100N weight at a distance of 0.4 m from the elbow. What is the elbow torque due to external forces? • T= (-Tarm) + (-Tbriefcase) • T = Tarm+Tbriefcase • T = (-Tarm) + Tbriefcase • T = Tarm + (- Tbriefcase) • It depends 100 N 11 N 0.16 0.4 m

A person is statically holding a 100N weight at a distance of 0.4 m from the elbow. What is the elbow torque due to external forces? 100 N 11 N 0.16 0.4 m

Torque about shoulder due to external forces when 5 kg briefcase is held with straight arm. Forearm force Upper arm force Briefcase force

Upper arm force Forearm force Briefcase force 20N 0.16 m 15N 15N 0.48 m 49N 0.48 m 0.65 m 31 Nm 20.6 Nm - 41Nm 41 Nm None of the above

20N 0.16 m 15N 15N 0.48 m 49N 0.48 m 0.65 m

Muscles create torques about joints Upper arm Elbow flexor muscle Biceps force Elbow Forearm T

Static and Dynamic Analyses Statics (acceleration = 0)  F = 0  M = 0 (M is moment or torque) Dynamics (non-zero acceleration)

Static equilibrium F1 F2 R2 Static equilibrium All accelerations are zero Three equations for analysis Fx = 0 Fy = 0  M = 0 R1 Teeter- totter

Static equilibrium F1 F2 R2 R1 Fx = 0: No forces in this direction Fy = 0 F3 - F1 - F2 = 0 Ma = 0 T1 – T2= 0 F1R1 - F2R2 = 0 Convention: Counter Clockwise is positive a F3

Upper arm Question: What muscle force (Fm) is required to support the forearm weight (Fw)? Free-body diagram - static equilibrium Elbow flexor muscle Fm Fw Elbow Forearm

Step 1: Free body diagram. Joint reaction force (Fj): net force generated between adjacent body segments External forces Muscle forces Upper arm Fj Fm Fw Fm Fw Forearm Forearm Elbow Elbow

Segmental Free body diagrams System = forearm+hand Weight Other external forces Muscle force Joint reaction force (Fj): net force generated between adjacent body segments Direction? If you are unsure of the direction a force is acting, draw a POSITIVE vector!! Fw Fj Fm Fw Forearm+hand Elbow

Question: What muscle force (Fm) is required to support the forearm weight (Fw)?Step 1: Free body diagram.Givens: Fw = 11 N, Rw = 0.16 m, Rm = 0.03 mStep 2: Apply appropriate equation Upper arm Fj Fm Fw Fm Fw Forearm Forearm Elbow Elbow

Fj,y Fm Fw Solve for Muscle force, Fm Rm Static equilibrium Melbow = 0 Fj creates no moment at elbow -(Tw) + (Tm) = 0 -(Fw * Rw) + (Fm * Rm) = 0 Fm = (Fw * Rw) / Rm Substitute: Fw= 11 N, Rw = 0.16 m, Rm = 0.03 m Fm = 59 N Rw

If a person holds a 100 N weight in their hand 0.4 m from the elbow, what is the elbow flexor muscle force? Ignore weight of forearm Information Rm = 0.03 m Rext = 0.4 m Step 1: Free body diagram Upper arm Muscle Fext Elbow Forearm

Fext Fm Rm Rext Solve forElbow flexor force Rm = 0.03 m Fext= 100 N Rext= 0.4 m Fj,y Fj,x

When Rm < Rext,muscle force > external force Fm = Fext(Rext / Rm) Last example Fext = 100N Rext > Rm Fm = 1333 N Upper arm Biceps brachialis Fext Rm Elbow Rext

If a person holds a 100 N weight in their hand 0.4 m from the elbow, what is the joint reaction force? (ignore weight of forearm). Free body diagram Apply equations Fj,y Fext Fm Rm Fj,x Rext

If a person holds a 100 N weight in their hand 0.4 m from the elbow, what is the joint reaction force? (ignore weight of forearm). Free body diagram Apply equations: Fy = 0 Fj,y + Fm - Fext = 0 Fm = 1333 N, Fext = 100 N Fj,y = -1233 N Fx = 0 Fj,x = 0 N Fj,y Fext Fm Rm Fj,x Rext

What is the muscle force when a 5 kg briefcase is held with straight arm? Fm Fj Upper arm force Forearm force Briefcase force

20N 0.16 m 15N T = (49N * 0.65m) + (15N * 0.48m) + (20N * 0.16m) T = (31 Nm) + (7.2 Nm) + (3.2 Nm) T = 41 Nm 15N 0.48 m 49N 0.48 m 0.65 m

Fm Fj 20N 0.16 m Rm = 0.025 m, Fm = ??? 15N 0.48 m 49N 0.65 m -1640 Nm 1640 Nm 1640 N None of the above

Fm Fj 20N 0.16 m Does Fjx = 0? 15N 0.48 m 49N 0.65 m Yes No It depends

At the end of stance phase while running, Fg,x under the right foot is 200N and Fg,y is 350N. Fg is applied to the foot 0.2 m from the ankle. What is the ankle torque due to Fg? Step 1: Find moment arm of Fg,x(MRx) & Fg,y(MRy) about ankle. 0.2 m 30° 200N 350N

0.2 m MRx 30° 200N 350N At the end of stance phase while running, Fg,x under the right foot is 200N and Fg,y is 350N. Fg is applied to the foot 0.2 m from the ankle. What is the ankle torque due to Fg? Step1 MRx= 0.2 sin 30° = 0.10 m

MRy 0.2 m MRx 30° 200N 350N At the end of stance phase while running, Fg,x under the right foot is 200N and Fg,y is 350N. Fg is applied to the foot 0.2 m from the ankle. What is the ankle torque due to Fg? Step 1 MRx= 0.2 sin 30° = 0.10 m MRy= 0.2 cos 30° = 0.17 m Step 2 T = (Tx) + (Ty) T= (Fg,x*MRx) + (Fg,y * MRy) T = (200 * 0.10) + (350 * 0.17) T = 79.5 Nm

MRy 0.2 m MRx 30° 200N 350N At the end of stance phase while running, Fg,x under the right foot is 200N and Fg,y is 350N. Fg is applied to the foot 0.2 m from the ankle. What is the ankle extensor muscle force?MRmusc = 0.05m

Outline: Torque • External force ----> muscle force (statics) • Review of approach • Mechanical advantage • Musculoskeletal complexity • External force ----> muscle force (dynamics)

Mechanical advantage (MA) • Fext = Fm * MA MA = Rm / Rext • MA = 1 Fm = Fext • MA < 1 Fm > Fext • MA > 1 Fm < Fext Upper arm Muscle Fext Rm Rext

MA < 1 • Rmuscle < Rext Fmuscle > Fext Shank Fm Rm Foot Rext Ankle Fext = Fg

MA < 1 Fm Briefcase force

MA > 1 • Rmuscle > Rext • Fmuscle < Fext Fmuscle (splenius capitis) Fext (Fw)

Factive MA > 1 • MA = Ractive / Rext • Ractive > Rext • Factive < Fext Ractive Fext Rext

Outline

Outline

Presentation Transcript

Outline

Outline

Outline

Outline

Outline

Outline

Outline

outline

outline

OUTLINE

Outline

Outline

Outline

Outline

Outline

Outline

Outline

Outline

Outline:

Outline

Outline

OUTLINE: