Answers
Answer:
The current flows in the second wire is
Explanation:
Given that,
Upward current = 24 A
Force per unit length
Distance = 7.0 cm
We need to calculate the current in second wire
Using formula of magnetic force
Where,
=force per unit length
I₁= current in first wire
I₂=current in second wire
r = distance between the wires
Put the value into the formula
Hence, The current flows in the second wire is
Related Questions
A 30 kg child on a 2 m long swing is released from rest when the swing supports make an angle of 34 ◦ with the vertical. The acceleration of gravity is 9.8 m/s 2 . If the speed of the child at the lowest position is 2.31547 m/s, what is the mechanical energy dissipated by the various resistive
What kind of exercise should you do when you're cooling down after anintense workout?
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Suppose that a barometer was made using oil with rho=900 kg/m3. What is the height of the barometer at atmospheric pressure?
1 cm = 100 m
1 mm = 100 cm
100 mm = 1 cm
1 m = 100 cm
Answers
Answer:
The last one
1m = 100 cm
Explanation:
If you do not trust me look it up
Answers
Answer:
A) No
B)-9,81 m/s^2
C)0 m/s^2
Explanation:
A free fallin object has only velocity on the vertical axis so any object that is moving in the Y and X axis has projetile motion not free falling, and when dealing with projectile motion the object is experiencing acceleration towards the ground of -9,81m/s^2 and in the Y axis, in the X axis there´s is only acceleration if the air is providing resistance, since it states that it isnot, then the accleration is 0.
1. Which terms (if any) are positive?
2. Which terms (if any) are negative?
3. Which terms (if any) are zero?
b) Determine the energy output by the athlete in SI unit.
c) Determine his metabolic power in SI unit.
d) Another day he performs the same task in 1.2 s.
1. Is the metabolic energy that he expends more, less, or the same?
2. Is his metabolic power more, less, or the same?
Answers
Answer:
Explanation:
(ΔK + ΔUg + ΔUs + ΔEch + ΔEth = W)
ΔK is increase in kinetic energy . As the athelete is lifting the barbell at constant speed change in kinetic energy is zero .
ΔK = 0
ΔUg is change in potential energy . It will be positive as weight is being lifted so its potential energy is increasing .
ΔUg = positive
ΔUs is change in the potential energy of sportsperson . It is zero since there is no change in the height of athlete .
ΔUs = 0
ΔEth is change in the energy of earth . Here earth is doing negative work . It is so because it is exerting force downwards and displacement is upwards . Hence it is doing negative work . Hence
ΔEth = negative .
b )
work done by athlete
= 400 x 2 = 800 J
energy output = 800 J
c )
It is 25% of metabolic energy output of his body
so metalic energy output of body
= 4x 800 J .
3200 J
power = energy output / time
= 3200 / 1.6
= 2000 W .
d )
1 ) Since he is doing same amount of work , his metabolic energy output is same as that in earlier case .
2 ) Since he is doing the same exercise in less time so his power is increased . Hence in the second day his power is more .
Final answer:
Positive, negative, and zero terms in the energy equation. Calculation of energy output and metabolic power. Comparison of metabolic energy and power for different time durations.
Explanation:
To apply the energy equation to the system, we need to determine whether each term is positive, negative, or zero:
- Positive terms:
- ΔUg - the change in gravitational potential energy is positive as the barbell is lifted vertically from the ground.
- ΔUs - the change in elastic potential energy is positive if there is any stretch or compression in the system.
- ΔK - the change in kinetic energy is negative as the barbell is lifted at a constant speed, so there is no change in velocity.
- ΔEch - the change in chemical potential energy is negative if the athlete is not ingesting any food or drinks during the exercise.
- ΔEth - the change in thermal energy is zero if there is no heat transfer in the system.
To determine the energy output by the athlete, we can calculate the work done on the barbell using the formula W = ΔUg. In this case, the work done is equal to the change in gravitational potential energy, which is equal to mgh. Thus, W = 400 N × 2.0 m = 800 J. So the energy output by the athlete is 800 J.
The metabolic power can be calculated using the equation P = W / t, where P is the power, W is the work done, and t is the time taken. Substituting the given values, P = 800 J / 1.6 s = 500 W. Therefore, the metabolic power of the athlete is 500 W. If the task is performed in a faster time, the metabolic energy expended will be the same. However, the metabolic power will be greater as the work is done in less time.
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Answers
Final answer:
The problem discusses the change in acceleration when a passenger is added to a car. It requires understanding of Newton's second law of motion, force equals mass times acceleration, and then recalculating the acceleration with the passenger added to the total mass.
Explanation:
This problem pertains to Newton's second law of motion, stating that the force applied on an object equals its mass times its acceleration (F = ma). Given that the initial acceleration of the Lamborghini Huracan with a driver is 0.80g or 0.80*9.80 m/s², we can calculate the force applied by the car. By multiplying the car's mass (1510 kg) with its acceleration, we will find the force.
Οnce we have the force, we can calculate the new acceleration if the 80 kg passenger rode along. Given that the force is constant, we determine the car's new acceleration by dividing this force with the new total mass (car mass + passenger's mass). So the question ultimately requires an application of the concepts of force, mass, and acceleration.
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Final answer:
The new acceleration of the Lamborghini Huracan with an added passenger can be calculated by finding the initial force using the car's mass and acceleration, and then using this force with the increased mass (original mass + passenger's mass) to find the new acceleration. The new acceleration will be less than the initial acceleration due to the increased mass.
Explanation:
To determine the new acceleration of the Lamborghini Huracan with an added passenger, we first calculate the initial force acting on the car. This can be done by using Newton's second law which states that Force = mass * acceleration. Initially, the acceleration is 0.80g (where g is acceleration due to gravity = 9.81 m/s²), and the mass is 1510 kg (including the driver). Therefore, the initial force = 1510 kg * 0.8 * 9.81 m/s².
However, when an 80-kg passenger rides along, the total mass becomes 1510 kg + 80 kg = 1590 kg. To find the new acceleration, we keep the force constant (as it is not affected by the introduction of the passenger) and rearrange the formula F = m*a as a = F/m. Use the increased mass to find the new acceleration. Please note that the new acceleration will be less than the initial acceleration due to increased mass.
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Answers
Answer:
(a) t=3.87 s :time at which Kathy overtakes Stan
(b) d=37.36 m
(c) vf₁ = 15.097 m/s : Stan's final speed
vf₂ = 19.31 m/s : Kathy's final speed
Explanation:
kinematic analysis
Because Kathy and Stan move with uniformly accelerated movement we apply the following formulas:
vf= v₀+at Formula (1)
vf²=v₀²+2*a*d Formula (2)
d= v₀t+ (1/2)*a*t² Formula (3)
Where:
d:displacement in meters (m)
t : time in seconds (s)
v₀: initial speed in m/s
vf: final speed in m/s
a: acceleration in m/s²
Nomenclature
d₁: Stan displacement
t₁ : Stan time
v₀₁: Stan initial speed
vf₁: Stan final speed
a₁: Stan acceleration
d₂: car displacement
t₂ : Kathy time
v₀₂: Kathy initial speed
vf₂: Kathy final speed
a₂: Kathy acceleration
Data
v₀₁ = 0
v₀₂ = 0
a₁ = 3.1 m/s²
a₂= 4.99 m/s²
t₁ = (t₂ +1) s
Problem development
By the time Kathy overtakes Stan, the two will have traveled the same distance:
d₁ = d₂
t₁ = (t₂ +1)
We aplpy the Formula (3)
d₁ = v₀₁t₁ + (1/2)*a₁*t₁²
d₁ = 0 + (1/2)*(3.1)*t₁²
d₁ = 1.55*t₁² ; Stan's cinematic equation 1
d₂ = v₀₂t₂ + (1/2)*a₂*t₂²
d₂ = 0 + (1/2)*(4.99)*t₂²
d₂ = 2.495* t₂² : Kathy's cinematic equation 2
d₁ = d₂
equation 1=equation 2
1.55*t₁² = 2.495* t₂² , We replace t₁ = (t₂ +1)
1.55* (t₂ +1) ² =2.495* t₂²
1.55* (t₂² +2t₂+1) =2.495* t₂²
1.55*t₂²+1.55*2t₂+1.55 = 2.495* t₂²
1.55t₂²+3.1t₂+1.55=2.495t₂²
(2.495-1.55)t₂² - 3.1t₂ - 1.55 = 0
0.905t₂² - 3.1t₂ - 1.55 = 0 Quadratic equation
Solving the quadratic equation we have:
(a) t₂ = 3.87 s : time at which Kathy overtakes Stan
(b) Distance in which Kathy catches Stan
we replace t₂ = 3.87 s in equation 2
d₂ = 2.495*( 3.87)²
d₂ = 37.36 m
(c) Speeds of both cars at the instant Kathy overtakes Stan
We apply the Formula (1)
vf₁= v₀₁+a₁t₁ t₁ =( t₂+1 ) s=( 3.87 + 1 ) s = 4.87 s
vf₁= 0+3.1* 4.87
vf₁ = 15.097 m/s : Stan's final speed
vf₂ = v₀₂+a₂ t₂
vf₂ =0+4.99* 3.87
vf₂ = 19.31m/s : Kathy's final speed
Answers
Explanation:
For equilibrium, .
So, = 0
=
= 705.6 N
Also, for equilibrium = 0
= 0
or,
=
= 176.4 N
Thus, we can conclude that the tension in the first rope is 176.4 N.