Block 1 (7 kg) is resting on the surface of a
table. A hand pushes vertically down on block 1
with a force of 280. N.
On a sheet of paper, draw the free body diagram
for block 1 using the two-subscript notation from class. After
completing the free body diagram, enter below each force and its x
& y-components. Remember that the x-component
is the "i" component and the y-component is the "j"
component.
FORCES on BLOCK 1
Weight force on block 1 by
Earth: (two-subscript notation)
Value = i
+ j N
| Tries 0/2 |
Normal force on block 1 by
Hand: (two-subscript notation)
Value = i
+ j N
| Tries 0/2 |
Normal force on block 1 by
Surface: (two-subscript notation)
Value = i
+ j N

Block 1 (7 kg) is resting on the surface of a table. A hand pushes vertically...
Block 1 (m1 = 8 kg) is resting on top of block 2 (m2 = 9 kg) on the surface of a table. On a sheet of paper, draw the free body diagrams for block 1 and block 2 using the two-subscript notation from class. After completing the free body diagrams, enter below each force and its x & y-components. Remember that the x-component is the "i" component and the y-component is the "j" component. (Use g = 10 m/s2)...
Block 1 (m1 = 7 kg) and block 2 (m2 = 9 kg) are adjacent to each other on the surface of a table. Block 2 is to the LEFT of block 1. A hand pushes horizontally on block 2 and causes both blocks to move to the right with an acceleration of magnitude 2 m/s2. The coefficient of kinetic friction between the block and the surface equals 0.4. On a sheet of paper, draw the free body diagrams for...
Block 1 (15 kg) is located on the surface of a table. A rope pulls on block 1 with a horizontal tension of 87 N to the right and a vertical tension of 110 N upward. The coefficient of kinetic friction between the block and the surface equals 0.3. On a sheet of paper, draw the free body diagram for block 1 using the two-subscript notation from class. After completing the free body diagram, enter below each force and its...
Block 1 (m1 = 6 kg) and block 2 (m2 = 7 kg) are adjacent to each other on the surface of a table. Block 2 is to the LEFT of block 1. A rope pulls on block 2 up and to the right with a vertical tension of 40 N upward, and both blocks move right with an acceleration of magnitude 6 m/s2. The coefficient of kinetic friction between the blocks and the surface equals 0.4. On a sheet...
Block 1 (m1 = 5 kg) and block 2 (m2 = 7 kg) are adjacent to each other on the surface of a table. Block 2 is to the LEFT of block 1. A hand pushes horizontally on block 2 and causes both blocks to move to the right with an acceleration of magnitude 8 m/s2. The coefficient of kinetic friction between the block and the surface equals 0.2. On a sheet of paper, draw the free body diagrams for...
Block 1 (15 kg) is pulled by a rope from left to right up a ramp which is inclined 45 degrees from the horizontal. The rope pulls on block 1 with a force of 255 N parallel to the surface of the inclined plane. The coefficient of kinetic friction between the block and the surface equals 0.3. On a sheet of paper, draw the free body diagram for block 1 using the two-subscript notation from class. Assume that the x-axis...
Block 1 (20 kg) is pulled by a rope from left to right up a ramp which is inclined 30 degrees from the horizontal. The rope pulls on block 1 with a force of 220 N parallel to the surface of the inclined plane. The coefficient of kinetic friction between the block and the surface equals 0.1. On a sheet of paper, draw the free body diagram for block 1 using the two-subscript notation from class. Assume that the x-axis...
Please help. Block 1 (m1 = 5kg) and block 2 (m2 = 6 kg) are
adjacent.
Block 1 (m1 5 kg) and block 2 (m2 6 kg) are adjacent to each other on the surface of a table. Block 2 is to the LEFT of block 1. A rope pulls on block 2 up and to the right with a vertical tension of 30 N upward, and both blocks move right with an acceleration of magnitude 3 m/s2. The coefficient...
webbplnotation from class. After completing the free body diagram, enter below each force and its x y components. (use 9 - 10 m) Remember that the x-component is the component and they component is the component NET force on Block 1 (round to nearest Integer) FD I + 2043 IN The DIRECTION of the net force on Block 1 is in the same direction as its acceleration of the elevator is moving downward with a decreasing speed, then the direction...
A block with mass of 10 kg is on a frictionless surface. One
hand on the left side of the block is pushing it to the right. A
second hand on the right side of the block is pushing it to the
left.
The block starts from rest. Then Hand 1 pushes with a force of 8
N and the block moves to the right a distance of 4 m, where it has
a final velocity of 2 m/s. Between...