if you want to remove an article from website contact us from top.

# block of mass 10 kg is moving on inclined plane with constant velocity 10m/s

Category :

### Mohammed

Guys, does anyone know the answer?

get block of mass 10 kg is moving on inclined plane with constant velocity 10m/s from screen.

## Block of mass 10 kg is moving on an inclined plane with constant velocity 10 m/s . The coefficient of kinetic friction between the incline plane and block is:

Click here👆to get an answer to your question ✍️ Block of mass 10 kg is moving on an inclined plane with constant velocity 10 m/s . The coefficient of kinetic friction between the incline plane and block is:

Question

A

B

C

D

## None of these

Medium Open in App

Updated on : 2022-09-05

Solution Verified by Toppr

Correct option is B)

∑Fy=0

⇒N−mgcosθ=0 ⇒N=mgcosθ−−−−(1)

Fx=0 (as constant velocity ⇒ No acceleration)

⇒mgsinθ−μ k ​ N=0 ⇒mgsinθ−μ k ​

mgcosθ=0               |From (1)

⇒cosθ(tanθ−μ k ​ )=0 ⇒μ k ​ =tanθ=tan37 o = 4 3 ​ = 0.75 ​

77 15

स्रोत : www.toppr.com

## Block of mass 10kg is moving on inclined plane of angle 37 degree with constant velocity 10m/s the coeficcient of kinetic friction between inclined plane and block is

Block of mass 10kg is moving on inclined plane of angle 37 degree with constant velocity 10m/s the coeficcient of kinetic friction between inclined plane and block is

Home

Block of mass 10kg is moving on inclined plane of angle 37 degree with constant velocity 10m/s the coeficcient of kinetic friction between inclined plane and block is

Question

Block of mass 10kg is moving on inclined plane of angle 37 degree with constant velocity 10m/s the coeficcient of kinetic friction between inclined plane and block is

Open in App Solution

Suggest Corrections 6

SIMILAR QUESTIONS

Q. Block of mass

10 k g

is moving on an inclined plane with constant velocity

10 m / s

. The coefficient of kinetic friction between the incline plane and block is:

Q. A block of mass

m

slides down an inclined plane of slope angle

θ

with constant velocity. Now, same block is projected up an inclined plane with an initial velocity

u

. If the coefficient of kinetic friction between the block and the plane is

μ

, the distance up to which the block will rise up the plane, before coming to rest is :-

Q. A block of mass

m

is kept on an inclined plane inside a lift moving down with acceleration of

2 m/s 2

. What should be the coefficient of friction between block and inclined plane to let the block move down with constant velocity relative to lift?

(Take g = 10 m/s 2 )

Q. A block rests on a rough inclined plane making an angle

30 0

with horizontal. The coefficient of static friction between the block and inclined plane is

0.8

. If the maximum frictional force on the block is

10 N

, the mass of the block in

k g is ( g = 10 m / s 2 ):

Q. A block rests on a rough inclined plane making an angle of

30 ∘

with horizontal. The coefficient of static friction between the block and inclined plane is 0.8. If the frictional force on the block is 10N, the mass of the block in kg is (g=10

m / s 2 ) View More

स्रोत : byjus.com

## Block of mass 10 kg is moving on inclined plane with constant velocity 10 m/s. The coedfficient of kinetic friction between incline plane and block is :

Block of mass 10 kg is moving on inclined plane with constant velocity 10 m/s. The coedfficient of kinetic friction between incline plane and block is :-

Home > English > Class 12 > Physics > Chapter > Race >

Block of mass 10 kg is moving ...

Block of mass 10 kg is moving on inclined plane with constant velocity 10 m/s. The coedfficient of kinetic friction between incline plane and block is :-

Updated On: 27-06-2022

00 : 30

Text Solution Open Answer in App A 0.57 B 0.75 C 0.5 D None of these Answer

Step by step solution by experts to help you in doubt clearance & scoring excellent marks in exams.

## Related Videos

Block of mass 10 kg is moving on inclined plane with constant velocity 10 m/s. The coedfficient of kinetic friction between incline plane and block is :-

48210127 600 7.9 K 1:57

Block of mass 10 kg is moving on inclined plane with constant velocity 10 m/s. The coedfficient of kinetic friction between incline plane and block is :-

645877470 22 5.8 K 3:30

646687152 0 7.7 K 2:49

An inclined plane is moving with Constant velocity

v=4m/s v=4m/s

on a horizoontal surface as shown in figure. If a block of mass

2kg 2kg

is kept at top of the incline and their is no friction between the block and the incline, then the distance travelled by the incline till the block reaches bottom of the inclined is

(g=10m/ s 2 ) (g=10m/s2)

14278000 0 5.1 K 4:13

An inclined plane is moving with Constant velocity

v=4m/s v=4m/s

on a horizoontal surface as shown in figure. If a block of mass

2kg 2kg

is kept at top of the incline and their is no friction between the block and the incline, then the distance travelled by the incline till the block reaches bottom of the inclined is

(g=10m/ s 2 ) (g=10m/s2)

462815756 0 1.9 K 5:05

A block of mass m moves with constant speed down the inclined plane of inclination

. Find the coefficient of kinetic friction.

θ θ

646703356 0 600 1:28

A block of mass m moves with constant speed down the inclined plane of inclination

. Find the coefficient of kinetic friction.

θ θ

Popular Chapters by Class:

Class 6 Algebra

Basic Geometrical Ideas

Data Handling Decimals Fractions Class 7

Algebraic Expressions

Comparing Quantities

Congruence of Triangles

Data Handling

Exponents and Powers

Class 8

Algebraic Expressions and Identities

Comparing Quantities

Cubes and Cube Roots

Data Handling

Direct and Inverse Proportions

Class 9

Areas of Parallelograms and Triangles

Circles Coordinate Geometry Herons Formula

Introduction to Euclids Geometry

Class 10

Areas Related to Circles

Arithmetic Progressions

Circles Coordinate Geometry

Introduction to Trigonometry

Class 11 Binomial Theorem

Conic Sections

Introduction to Three Dimensional Geometry

Limits and Derivatives

Class 12

Application of Derivatives

Application of Integrals

Continuity and Differentiability

Determinants

Differential Equations