Consequently, work is equal to the energy converted from one type to another. Test Work. Power. Conservation laws Determine the minimum power which must have

Option 1

1.A body weighing 1kg rises to a height of 5m. What is the work of gravity when lifting the body.

A. 50J B.150J C. 250J.

2. Determine the minimum power that the hoist motor must have to lift a 0.05t load to a height of 10m in 5s.

A.2kW B.1kW B.3kW.

3. When cycling on a horizontal road at a speed of 9 km / h, a power of 30W is developed. Find the driving force.

A.12N B. 24N V. 40N.

4. A body weighing 2kg has a potential energy of 10J. To what height above the ground is the body lifted if the zero of the potential energy is located on the surface of the earth?

A.1m B. 0.5m C. 2m.

5. What is the potential energy of the striking part of a 300kg pile hammer raised to a height of 1.5m?

A. 4500J B. 5000J C. 6000J.

6. What is the maximum potential energy of a bullet ejected from a gun, if its velocity at exit is 600 m / s, and its mass is 9g?

A. 460J B.1620J V. 2500J.

7. With what speed was the stone thrown vertically upward, if it rose to a height of 5m?

A.10m / s B.5m / s V. 2m / s.

8. An airplane with a mass of 2 tons is moving in a horizontal direction at a speed of 50 m / s. Being at an altitude of 420m, it descends with the engine off and reaches the airfield track with a speed of 30m / s. What is the work of the air resistance force during gliding flight?

A. -10MJ B.10MJ V. -20MJ.

9. Two carts move towards each other at a speed of 4 m / s each. After the collision, the second bogie got a speed in the direction of movement of the first bogie, equal to 6 m / s, and the first stopped. Calculate the mass of the first cart if the mass of the second is 2kg.

10. A stone weighing 20g, released vertically upward from a slingshot, the rubber band of which was stretched by 20cm, rose to a height of 40cm. Find the stiffness of the harness.

Option 2

1.A body weighing 2kg is lifted to a height of 2m. What is the work force of gravity when lifting the body

A. 40J B. 80J C. 60J.

2. Calculate the power of the pump that delivers 1200kg of water every minute to a height of 20m.

A.4kW B.10kW V. 20kW.

3. The thrust force of a supersonic aircraft at a flight speed of 2340 km / h is 220 kN. What is the power of the aircraft engines in this flight mode?

A. 143 MW B. 150 MW C. 43 MW.

4. A body raised above the ground to a height of 2m has a potential energy of 40J. What is the mass of this body if the zero of the potential energy is located on the surface of the earth?

A. 2kg B. 4kg B. 5kg

5. What is the change in the potential energy of a 200kg load that fell to the ground from a height of 2m?

A. -4500J B. -4000J C. 4000J.

6. What is the kinetic energy of a body with a mass of 3 kg, moving at a speed of 4 m / s?

A. 20J B. 30J C. 24J.

7. The ball is thrown vertically upward at a speed of 10m / s. Determine the maximum height the ball will climb.

A.10m B. 5m C. 20m

8. A stone thrown vertically upward at a speed of 20 m / s fell to the ground at a speed of 10 m / s. Stone weight200g. What is the work of the air resistance force?

A. -30J B. 30J W. -40J.

9. Two balls are moving towards each other at the same speed. The mass of the first ball is 1kg. What mass should the second ball have so that after the collision the first ball stops and the second rolls back at the same speed?

10. When preparing a toy pistol for a shot, the spring with a stiffness of 800n / m was compressed by 5cm. What velocity does a 20g bullet acquire when fired horizontally?

Option 3

1. A ball of mass m moves with a speed v and collides with the same motionless ball. Assuming the impact is absolutely elastic, determine the velocity of the balls after the collision.

A. v 1 = 0; v 2 = v B. v 1 = 0; v 2 = 0 V. v 1 = v; v 2 = v.

2. What is the modulus of change in the impulse of a body of mass m, moving with a speed v, if after a collision with a wall the body began to move in the opposite direction with the same modulus of speed?

A. 0 B. mv B. 2mv.

3. A material point weighing 1 kg moves uniformly around a circle at a speed of 10m ∕ s. Determine the change in impulse over a half period.

A. 0 kg m ∕ s B. 14 kg ∙ m ∕ s B. 20 kg m ∕ s.

4. How many times is the potential energy accumulated by the spring when compressed from the equilibrium position by 2 cm less than when the same spring is compressed by 4 cm?

A. 2 times B. 8 times C. 4 times.

5. How will the kinetic energy of a body change when its speed doubles?

A. Increase 4 times B. Decrease 4 times C. Increase 2 times.

6. A bullet is fired from a spring pistol located at a height of 2m above the ground. The first time vertically upward, the second time horizontally. In which case will the bullet velocity be greatest when approaching the earth's surface? Neglect air resistance. The bullet velocity from the pistol is considered the same in all cases.

A. In the first B. In the second C. In all cases, the final velocity of the bullet will be the same in absolute value.

7. The figure shows the trajectory of a body thrown at an angle to the horizon (neglect air resistance). The kinetic energy is equal to the potential at the point

A. 2 B. 3 C. 4

D. At all points is equal.

8. A proton moving at a speed of 2 · 10 4 m / s collided with a fixed nucleus of a helium atom. Calculate the speed of the nucleus of a helium atom after the impact if the speed of the proton has decreased to 0.8 · 10 4 m / s. The mass of a helium nucleus is 4 times greater than the mass of a proton.

9. When preparing a toy pistol for a shot, the spring with a stiffness of 800 N / m was compressed by 5 cm. What speed does a bullet weighing 20 g acquire when fired in a horizontal direction.

10. Calculate the average force of soil resistance if a body with a mass of 2 kg, thrown from a height of 250 m vertically downward with an initial speed of 20 m / s, plunged into the ground to a depth of 1.5 m.

WORK, POWER, ENERGY

Contents of a book

1.c B E D E N I E.

2. T E O R E T I Ch E S K I J O B Z O R.

3.RESH E N I E Z A D A CH A S T and 1 Unified State Exam - 80 Z A D A CH.

4. R E S E N I E Z A D A HCH A S T I 2 Unified State Exam - 50 Z A D A Ch.

3-1. Job. power.

3-2. MECHANICAL ENERGY.

3-3. the theorem about the change and the kinetic energy.

5. PROBLEMS OF INDEPENDENT SOLUTION - 21 tasks.

6.t A B L I C Y S F O R M U L A M I.

AS AN EXAMPLE BELOW ARE 4 TASKS OUT OF 130 TASKS ON THE TOPIC " WORK AND ENERGY"WITH DETAILED SOLUTIONS

R E W E N I E Z A D A CH A S T i 1 Unified State Exam

Problem number 1-8

How much power should the lift motor have to lift a load m= 100 kg per height h= 20 m for t= 9.8 s from the ground, uniformly accelerated?

Given: m= 100 kg, h= 20 m, t= 9.8 s. Define N - ?

The instantaneous power of the engine, which will ensure the lifting of the load for a given time, is determined by the formula N = F · V (1), whereF - lifting force , V - load speed at heighth ... The following forces act on the load when lifting: mg - the force of gravity, directed vertically downward and F - the lifting force is directed vertically upward. The load moves vertically upward with acceleration a in accordance with Newton's second law:

F - mg = ma, where F = mg + ma.

We find the acceleration from the path equation accelerated movement h = at² / 2, where a = 2h / t². Then the lifting force will be F = mg + m2h / t².

Determine the speed of the load at height h : V = a t = 2h / t.

Substitute the expression for force and speed in (1):

Problem number 1- 22

The boy pushed the sled off the top of the hill. Immediately after the push, the sledges had a speed V 1 = 5 m / s. Slide height h= 10 m. The friction of the sled on the snow is negligible. What is the speed V 2 sledges at the foot of the slide?

Given: V 1 = 5 m / s, h= 10 m. Determine V 2 - ?

After the san push ok from the top of the slide sledges acquired kinetic energy

Since the friction of the sled on the snow can be disregarded, then when the sled is moving from the mountain, only the force of gravity mg doing work A = mgh.

This work of gravity goes to increase the kinetic energy of the sled, which at the foot of the slide will be equal to

where V 2 - the speed of the sled at the foot of the slide.

We solve the resulting equation and find the speed of the sled at the foot of the hill

R E W E N I E Z A D A CH A S T I 2 Unified State Exam

Problem number 2-9

Operating at constant power, the locomotive can drive the train up a slope at a lean angle α 1= 5 · 10 -3 rad with a speed V 1= 50 km / h. For tilt angle α 2= 2.5. · 10 -3 rad under the same conditions, he develops speed V 2= 60 km / h. Determine the coefficient of friction, considering it the same in both cases.

Given: α 1= 5 · 10 -3 rad, V 1= 50 km / h = 13.9 m / s, α 2= 2.5. · 10 -3 rad, V 2= 60 km / h = 16.7 m / s. Define μ - ?

Rice. 3.

The power that the engines of the locomotive develop during uniform movement up the slope will be determined by the formula N = F 1 V 1 (1) for the first case and N = F 2 V 2 (2)– for the second, where F 1 and F 2 - the thrust force of the engines.

To express the pulling force, we use rice. 2-9 and write down Newton's first law:

F + mg + N + F tr = 0.

Let's project this equation on the axis OX and OY.

OX: F - mgsin α - F tr= 0 (3), OY: - mgcosα + N= 0,

Where do we get N =mgcosα andF tr = μmgcosα.

Substitute the expression for the friction force in (3) :

F - mgsin α - μmgcosα = 0,

whence we obtain the expression for the thrust force of the enginesF = mg (sin α + μcosα).

Then F 1 = mg (sin α 1 + μcosα 1) and F 2 = mg (sin α 2 + μcos α 2).

Taking into account the smallness of the tilt angles, we will somewhat simplify the formulas: sin α 1 ≈ α 1, sin α 2 ≈ α 2, cosα 1 ≈ 1, cosα 2 ≈ 1, then F 1 = mg (α 1 + μ) and F 2 = mg (α 2 + μ).

Substitute expressions for F 1 and F 2 into equations (1) and (2):

N = V 1 mg (α 1 + μ) (4) and N = V 2 mg (α 2 + μ) (5).

We solve the resulting system of equations:

V 1 mg (α 1 + μ) = V 2mg (α 2 + μ),

Let's transform the equation: μ (V 2 -V 1) = V 1 α 1 - V 2 α 2, where

Problem number 2-16

Body mass m= 1 kg moves on the table, having the speed at the starting point V about= 2 m / s. Reaching the edge of the table, the height of which h= 1 m, the body falls. Coefficient of friction of the body on the table μ = 0.1. Determine the amount of heat Q, released upon inelastic impact on the ground. The path traversed by the body on the table S= 2m.

Given: m= 1 kg, V about= 2 m / s, h= 1 m, μ = 0,1,S= 2m. Define Q -?

When the body falls from the table to the ground, then with an inelastic impact, all the kinetic energy of the body K 2 will turn into heat: K 2 = Q . Therefore, we need to determine the kinetic energy of the body at the moment it hits the ground. To do this, we use the theorem on the change in the kinetic energy of the body:

K 2 - K 1 = ∑A i, where К 2 = К 1 + ∑А i (1) .

Kinetic energy of the body at the starting point of the path K 1 = mV o ² / 2. The sum of the work of external forces acting on the body ∑A i = A tr + A t , where A tr = -F tr S = - μmgS - friction work on the way S , And m = mgh - the work of gravity when the body falls from a height h.

Let's substitute everything into equation (1):

phone: +79175649529, mail: [email protected]

Conversion of mechanical energy... Mechanical energy is not conserved during any interactions of bodies. The law of conservation of mechanical energy is not fulfilled if friction forces act between the bodies.

Experience shows that mechanical movement never disappears without a trace and never arises by itself. During the braking of the vehicle, heating of the brake pads, vehicle tires and asphalt occurred. Consequently, as a result of the action of friction forces, the kinetic energy of the car did not disappear, but turned into the internal energy of the thermal motion of molecules.

For any physical interactions energy does not arise and does not disappear, but only transforms from one form to another.

This experimentally established fact is called the law of conservation and transformation of energy.

The main problem of mechanics - determining the position of a body at any moment in time - can be solved using Newton's laws if the initial conditions and forces acting on the body are given as functions of coordinates and velocities (and time). In practice, these dependencies are not always known. However, many problems in mechanics can be solved without knowing the values ​​of the forces acting on the body. This is possible because there are quantities that characterize the mechanical movement of bodies, which are preserved under certain conditions. If the position of the body and its speed at a certain moment of time are known, then using the conserved quantities it is possible to determine the position and speed of this body after any interaction, without resorting to the laws of dynamics.

The quantities conserved in mechanical processes are momentum, angular momentum and energy.

Body impulse. We multiply the expression for Newton's second law in the form F = ma (under the action of a constant force F) by Δ t: F * Δt = ma * Δt = m Δ v = m (v 2 - v 1) = mv 2 - mv 1 = Δ (mv). The value p = mv is called the momentum of the body(otherwise - by the amount of movement), F Δ t - by the impulse of force. Using these concepts, Newton's second law can be formulated as follows: the momentum of the forces applied to the body is equal to the change in the momentum of the body; F Δ t = Δ p (18)

Momentum conservation law... When considering a system of bodies, one should take into account that each of them can interact both with bodies belonging to the system, and with bodies that are not included in this system. Let there be a system of two material points interacting with each other. Let us write Newton's second law for each of the material points of the system under consideration for the time interval Δ t:

(F 1 + F 21) Δ t = Δ p 1

(F 2 + F 12) Δ t = Δ p 2

Adding both equalities, we get: Δ p 1 + Δ p 2 = (F 1 + F 21) Δ t + (F 2 + F 12) Δ t

According to Newton's third law, F 12 + F 21 = 0, therefore, the change in the momentum of the entire system, equal to the vector sum of the changes in the momenta of its constituent particles, looks like this:

In inertial reference frames, the change in the total momentum of a system of material points is equal to the momentum of all external forces acting on this system.

A system of bodies that are not acted upon by external forces or the sum of all external forces is zero is called closed. Impulse conservation law: in a closed system of bodies, the momentum of the system is conserved. This conclusion is a consequence of Newton's second and third laws. The law of conservation of momentum is not applicable to open systems of bodies; however, the projections of the momentum on the coordinate axes remain constant, in the direction of which the sum of the projections of the applied external forces is equal to zero.

Jet propulsion... Consider, as an example, the operation of a jet engine. When fuel is burned, gases heated to a high temperature are ejected from the rocket nozzle. These gases are ejected from the nozzle at a speed. This speed is called the flow rate. Neglecting the interaction of the rocket with external bodies, we will consider the system of bodies "rocket - gases" closed. Let at the moment of time t 0 = 0 a rocket of mass m was moving at a speed of v 0. For a small time interval Δ t, a mass of gas Δ m is ejected from the rocket with the speed and relative to the rocket, that is, with the speed V 1 = u + v relative to the inertial reference frames (here v is the rocket speed). According to the law of conservation of momentum, we have: MV 0 = (m - Δ m) v + Δ mV 1 Substituting the values ​​V 1 = u + v, v = V 0 + Δ v we get: M Δ v = - Δ μ

Let us divide both sides of the equality by the time interval Δ t, during which the rocket engines worked: m (Δv / Δ t) = - (Δ m / Δ t) u. The product of the rocket mass m and the acceleration of its motion a is called the reactive thrust force: F p = ma = - μu (19). The reactive thrust force acts from the side of the outflowing gases on the rocket and is directed in the direction opposite to the direction of the outflow of gases.

Test questions and tasks:

1. Formulate the definition of force work. In what units is work measured? What is the physical meaning of the work?

2. Under what conditions is the work of force positive? negative? is zero?

3. What is the definition of potential energy? Where is the minimum potential energy?

4. Formulate the definition of the kinetic energy of the body and the kinetic energy theorem.

5. Give the definition of power. What are the scalar or vector quantities of power?

6. On what quantities does the work of the elastic force depend?

7. What is called the total mechanical energy of the system? Formulate the law of conservation of mechanical energy, and under what conditions is it fulfilled?

8. Give the definition of body impulse. Formulate the law of conservation of momentum.

9. What is the jet motion of the body?

10. The tower crane lifts in a horizontal position a steel beam 5 m long and 100 cm 2 section to a height of 12 m. What useful work does the crane do?

11. What kind of work does a person do when lifting a load weighing 2 kg to a height of 1 m with an acceleration of 3 m / s 2?

12. The speed of a freely falling body weighing 4 kg on a certain path increased from 2 to 8 m / s. find a job of gravity along the way.

13. A wooden container weighing 200 kg was evenly moved on the wooden floor at a distance of 5 m. Find the work that was perfect during this movement. Sliding friction coefficient 0.5.

14. When the spring is stretched by 2 cm, a work of 1 J is done. What work should be done to stretch the spring by another 2 cm?

15. What is the minimum power of the hoist motor to lift a 100 kg load to a height of 20 m in 9.8 s.

16. Find the maximum height to which a stone thrown vertically upward at a speed of 20 m / s will rise.

17. The movement of a material point is described by the equation x = 5 - 8t + 4t 2. Taking its mass equal to 2 kg, find the impulse in 2 s and 4 s after the start of time counting, as well as the force that caused this change in impulse.

18. A train weighing 2000 tons, moving in a straight line, increased its speed from 36 to 72 km / h. Find the change in momentum.

19. A car with a mass of 2 tons braked and stopped, having covered a distance of 50 m. Find the work of the friction force and the change in the kinetic energy of the car if the road is horizontal and the coefficient of friction is 0.4.

20. At what speed did a train with a mass of 1500 tons move if, under the action of a braking force of 150 kN, it traveled a distance of 500 m from the moment of braking to a stop?

This test contains 23 options for assignments of different levels on the topic "Work, power, simple mechanisms" for the 9th grade (according to the physics textbook for the 9th grade by the authors Shakhmaev N.M., Bunchuk A.V.). Each option contains a different number of quality and design problems of different levels. Knowing the individual characteristics of the student, it is possible in this work to select tasks that are feasible for each child. I would be glad if this publication is useful to someone. Download, recycle. Good luck!

Download:

Preview:

Aprelskaya

9kl. (according to Shakhmaev).

Examination work No. 3.

Work, power, simple mechanisms.

Option number 1

1. A body weighing 1 kg with a force of 20 N rises to a height of 5 m. What is the work of this force?
2. Give a detailed answer: is it possible to move a sailboat by directing a stream of air from a powerful fan on the boat to the sails?
3. Determine the minimum power that the lift motor must have to lift a 50kg load to a height of 10m in 5s. Find efficiency
4. What work is done by the force of gravity acting on a raindrop weighing 20 g when it falls from a height of 1 km?

Option number 2

1. A body weighing 1kg rises to a height of 5m. What is the work of gravity?
2. Give a detailed answer: a stone and a tennis ball are hit with a stick. Why does the ball fly farther than a stone, other things being equal?
3. Calculate the power of the pump, which delivers 1200kg of water every minute to a height of 20m.
4. A stone weighing 400 g was thrown vertically upward at a speed of 20 m / s. What are the kinetic and potential energies of a stone at a height of 15m?
5. A piano weighing 300 kg was fed into the sixth floor window, located 16 m above the sidewalk, using a lifting device in 50 seconds. Determine the work, power, efficiency.

Option number 3

1. The weightlifter, lifting the barbell, performs a work of 5 kJ in 2 s. Determine the power and efficiency.
2. What weight can the lifting machine lift to a height of 30 m in 4 minutes, if the engine power is 5 kW?

Option number 4

1. Kot Matroskin and Sharik towed Uncle Fyodor's car to Prostokvashino for 1 hour, acting with a force of 120 N. Distance to Prostokvashino is 1 km. Determine the work, efficiency and power
2. What is the power developed by a tractor at a speed of 9.65 km / h and a pulling force of 15 kN?
3. What work is done with a uniform rise of an iron beam with a volume of 0.1 m 3 to a height of 15 m?

Option number 5

1. 1. A boy weighing 40 kg climbed in 30 seconds to the second floor of the house, located at a height of 8 m. Determine the work and power
2. What kind of work does an excavator do when lifting 14 m of soil with a bucket? 3 to a height of 5 m? Soil density 1400 kg / m 3 .
3. The climber climbed the mountains to a height of 2 km. Determine the mechanical work performed by the climber during the ascent if his weight with equipment is 85 kg.
4. What weight can the lifting machine lift to a height of 30 m in 4 minutes, if the engine power is 5 kW? Find efficiency
5. A force of 4 N and 20 N acts at the ends of the lever, the length of the lever is 1.5 m. Where is the fulcrum if the lever is in equilibrium?

Option number 6.

1. A person, walking for 2 hours, makes 10,000 steps (40 J work is done in one step). Determine the work, power and efficiency.
2. What work is done by the force of gravity acting on a raindrop weighing 20 g when it falls from a height of 2 km?
3. The thrust force of a supersonic aircraft at a flight speed of 2340 km / h is 220 kN. Find the power of the aircraft engines in this flight mode.
4. Weights of 4 and 24 kg are suspended from the lever. The distance from the fulcrum to the larger load is 4 cm. Determine the length of the arm if the arm is in equilibrium.

Option number 7

1. The Baba Yaga stupa (weight 70 kg) flies 120 km in 1 hour. Determine the work, power
2. The crane lifted a load weighing 5 tons to a height of 10 m in 45 seconds. Determine the crane motor power and efficiency
3. The diesel locomotive develops a traction force of 400 kN at a speed of 54 km / h. What work is done to move the train within 1 minute?
4. A force of 4 N and 20 N acts at the ends of the lever, the length of the lever is 1.5 m. Where is the fulcrum if the lever is in equilibrium?

Option number 8

1. Carlson lifts the Kid weighing 30 kg onto the roof of a house 20 m high in 10 seconds. Determine the work and power of Carlson
2. The spring of a toy pistol, compressed by 3 cm, pushes the ball out in 1 s, acting on it with a force of 10N. Determine the work, power and efficiency.
3. A Zhiguli car travels 100 m in 6.25 s, developing a thrust of 3 kN. Determine work and power
4. 4. The atomic icebreaker, developing a power of 32400 kW, covered 20 km in ice in 5 hours. Determine the average force of resistance to the icebreaker's movement.
5. Weights of 4 and 24 kg are suspended from the lever. The distance from the fulcrum to the larger load is 4 cm. Determine the length of the arm if the arm is in equilibrium.

Option number 9.

1. The crane lifts a concrete slab weighing 5 tons to a height of 9 m for 1 minute. Determine the work, power and efficiency.
2. The boy evenly lifted the bucket of water from the well once in 20 seconds, and the other in 30 seconds. Was the same work done in these cases? What can you say about the power when performing these works?
3. A cyclist performed 800 J in 10 seconds. What is the power of a cyclist?
4. What weight can the lifting machine lift to a height of 30 m in 4 minutes, if the engine power is 5 kW?
5. A force of 4 N and 20 N acts at the ends of the lever, the length of the lever is 1.5 m. Where is the fulcrum if the lever is in equilibrium?

Option number 10

1. How long will it take to pump out water weighing 2 tons, if the pump power is 1.5 kW? The height of the water rise is 20 m. Find the efficiency.
2. Academician B.S. Jacobi invented the electric motor in 1834. In the first version, the electric motor lifted a 5 kg load to a height of 60 cm in 2 s. Determine the engine power.
3. What is the power developed by a tractor at a speed of 9 km / h and a pulling force of 10 kN?
4. The atomic icebreaker, developing a power of 32400 kW, covered 20 km in 5 hours. Determine the average force of resistance to the movement of the icebreaker.
5. Weights of 4 and 24 kg are suspended from the lever. The distance from the fulcrum to the larger load is 4 cm. Determine the length of the arm if the arm is in equilibrium.

Option number 11

1. .How to what height do you need to lift a weight of 100 N in order to do the work?

200 J?

1. Determine the work done when lifting a 4 N load to a height of 4 m
2. Determine the work done by a 400 W motor in 30 s. What is the efficiency?
3. What weight can the lifting machine lift to a height of 30 m in 4 minutes, if the engine power is 5 kW?
4. A force of 4 N and 20 N acts at the ends of the lever, the length of the lever is 1.5 m. Where is the fulcrum if the lever is in equilibrium?

Option number 12

1. How long does a 200 W electric motor have to run in order to do 2500 J?
2. When cycling on a horizontal road at a speed of 9 km / h, a power of 30 watts is generated. Find the driving force.
3. Calculate the power of the pump that delivers 1200 kg of water every minute to a height of 20m

1. The nuclear icebreaker, developing a power of 32,400 kW, covered 20 km of ice in 5 hours.
2. Determine the average force of resistance to the movement of the icebreaker and efficiency. icebreaker
3. Weights of 4 and 24 kg are suspended from the lever. The distance from the fulcrum to the larger load is 4 cm. Determine the length of the lever if the lever is in

balance.

Option number 13

1. The crane lifts the load at a constant speed of 5.0 m / s. Crane power 1.5 kW. Which

can the load be lifted by this crane?

1. When preparing a toy pistol for a shot, a spring with a stiffness of 800 N / m

squeezed by 5 cm. What velocity will a 20 g bullet acquire when fired horizontally?

1. A force of 4 N and 20 N acts at the ends of the lever, the length of the lever is 1.5 m. Where is the fulcrum if the lever is in equilibrium?

Option number 14

1. A ball weighing 100 g freely fell onto a horizontal platform, having a velocity of 10 m / s at the moment of impact. Find the height of the fall, neglect friction.
2. 1.8 ∙ 10 falls from a dam with a height of 20 m 4 tons of water. What kind of work is being done?
3. Determine the potential energy of a spring with a stiffness of 1.0 kN / m if it is known that the compression of the spring is 30 mm.
4. Carlson lifts the Kid weighing 20 kg onto the roof of a house 20 m high in 10 seconds. Determine the work and power of Carlson

Option number 15

1. Determine the net engine power of a motorcycle if its pulling force is 350 N at 108 km / h.
2. What work is done when lifting from the ground the materials necessary to build a column with a height of 20 m with a cross-sectional area of ​​1.2 m 2 ? The density of the material is 2.6 ∙ 10 3 kg / m 3.
3. Determine how fast you need to throw the ball down from a height of 3 m so that it bounces to a height of 8 m.
4. A force of 4 N and 20 N acts at the ends of the lever, the length of the lever is 2 m. Where is the fulcrum if the lever is in equilibrium?

Option number 16

1. With an aircraft speed of 900 km / h, its four engines develop a net power of 30 MW. Find the thrust of each engine in this flight mode.
2. Determine the work to be done when digging a well with a diameter of 1.0 m and a depth of 10 m, if the density of the soil is 1.8 ∙ 10 3 kg / m 3 ... Consider that the soil is scattered in a thin layer over the surface of the earth.

3. A stone weighing 20 g, released vertically upward from a slingshot, a rubber band that was stretched by 10 cm, rose to a height of 40 cm. Find the stiffness of the spring.

4. Determine the minimum power that the hoist motor must have to lift a 50kg load to a height of 10m in 5s. Find efficiency

Option number 17

1. The crane evenly lifts a load weighing 500kg to a height of 10m in 50s. Determine the efficiency of the crane if its motor power is 1.5 kW.
2. The spring, compressed to 30cm, is fully extended. What work did the elastic force do if the spring rate is 100N / m?
3. Determine the work of the friction force if a body with a mass of 2 kg changes its speed from 4 to 3 m / s?
4. A 250g ball is thrown vertically upward at a speed of 20m / s. What is its kinetic energy at a height of 10m.

Option number 18

1. The box is pulled evenly along a horizontal surface by a rope forming an angle of 60 ° with the horizon. The force applied to the rope is 25N. What kind of work is done when the box is moved at a distance of 4m?
2. At an altitude of 15m above the Earth's surface, the building block has a potential energy of 1500 kJ. What is its mass equal to?
3. The spring has a stiffness of 2500 N / m. What energy does the spring have when compressed 10cm?
4. An arrow weighing 20 g is fired from the bow vertically upwards at a speed of 20 m / s. Determine its kinetic energy at a height of 15m.
5. The atomic icebreaker, developing a power of 32400 kW, covered 20 km in ice in 5 hours. Determine the average force of resistance to the movement of the icebreaker and efficiency. icebreaker

Option number 19

1. A body weighing 1kg with a force of 20N rises to a height of 5m. What is the work of this force?
2. The ball, lowered under water to a depth of 30 cm, is pushed out with a force of 5N. Define the job.
3. The spring is compressed by 4 cm. The spring rate is 100 kN / m. What kind of work will she do?
4. Useful work 20kn, all consumed energy is equal to 40,000 N. Find efficiency
5. Name the transitions of energy when falling

Option number 20

1. Weights of 4 and 24 kg are suspended from the lever. The distance from the fulcrum to the larger weight is 4 cm. Determine the distance to the second weight if the arm is in balance.
2. The spring is compressed by 50 cm. The spring rate is 10 kN / m. What is the energy of the spring?
3. Determine the work of gravity when a body weighing 4 kg falls from a height of 200 cm.
4. What is meant by the energy of the body? List the types of energy.

Option number 21

1. The climber climbed in the mountains to a height of 1.5 km. Determine the mechanical work performed by the climber during the ascent if his weight with equipment is 100 kg.
2. What is the payoff for the movable block?
3. Write down the formulas of different types of energies
4. Where and for what purpose is the gate used?

Option number 22

2. What is the inclined plane used for?

3. The spring, compressed by 10cm, is fully extended. What work did the elastic force do if the spring rate is 1kN / m?

4. At a height of 10m above the Earth's surface, the building block has a potential energy of 150 kJ. What is its mass equal to?

Option number 23

1. What is the payoff for the movable block?

2. A nuclear icebreaker, developing a power of 32400 kW, covered 20 km in ice in 5 hours. Determine the average force of resistance to the movement of the icebreaker.

3. Weights of 4 and 24 kg are suspended from the lever. The distance from the fulcrum to the larger load is 4 cm. Determine the length of the arm if the arm is in equilibrium.

4. Carlson lifts the Kid weighing 30 kg to the roof of a house 20 m high in 10 seconds. Determine the work and power of Carlson

Option number 24

1. The crane lifts the load at a constant speed of 5.0 m / s. Crane power 1.5 kW. What kind of load can this crane lift?
2. Determine at what height the kinetic energy of a ball thrown vertically upward at a speed of 23 m / s is equal to its potential?
3. When preparing a toy pistol for a shot, the spring with a stiffness of 800 N / m was compressed by 5 cm. What velocity will a 20 g bullet acquire when fired horizontally?
4. Forces 5 and 6 N act on the lever from below at angles of 45 and 30 degrees at a distance of 20 and 40 cm, respectively, from the support located in the middle of the lever. Find the force that can be used to balance the system by applying it vertically at a distance of 10 cm from the axis of rotation.