Wiki User
∙ 9y agoYou can find out the weight of an unknown object by using standard masses and a scale.
Wiki User
∙ 9y agoTo find the weight of an unknown object using standard masses and a scale, you can use a balance scale. Place the unknown object on one side and add standard masses to the other side until the balance is achieved. The sum of the standard masses used will be equal to the weight of the unknown object.
To find the weight of an unknown object using a ruler, you can use the concept of density. Measure the dimensions of the object to calculate its volume, then weigh the object to find its mass. Using the formula density = mass/volume, you can determine the weight of the object by multiplying its volume by the density of the material it's made of.
That would be a balance or a balance scale. It compares the weight of an unknown object to the weight of known masses to determine the object's weight.
The equipment used to measure the mass of objects is a "beam balance," which is a type of mechanical balance that compares the weight of an unknown mass against the weight of standard masses. It is designed to achieve a state of equilibrium by balancing the forces acting on the two sides of the beam.
Devices such as scales and balances are commonly used to measure weight and mass. Scales work by measuring the force of gravity acting on an object, which is directly proportional to its mass. Balances work by comparing the weight of an unknown object to the weight of a known standard mass. Both devices provide a numerical value that represents the weight or mass of the object being measured.
The mutual force with which every two masses attract each other because of gravity is referred to as the "weight" of the objects.
If the weight of an object is 50 pounds, its mass at standard conditions (assuming standard gravity of 9.81 m/s^2) would be approximately 22.68 kg.
That would be a balance or a balance scale. It compares the weight of an unknown object to the weight of known masses to determine the object's weight.
Use a balance with standard masses to find the mass. You need only find the mass at one of the two locations. Find the weight using a spring balance.
The mass of an object doesn't change, no matter where the object goes. The object's weight changes, depending on what other masses are nearby.
weight
The equipment used to measure the mass of objects is a "beam balance," which is a type of mechanical balance that compares the weight of an unknown mass against the weight of standard masses. It is designed to achieve a state of equilibrium by balancing the forces acting on the two sides of the beam.
Devices such as scales and balances are commonly used to measure weight and mass. Scales work by measuring the force of gravity acting on an object, which is directly proportional to its mass. Balances work by comparing the weight of an unknown object to the weight of a known standard mass. Both devices provide a numerical value that represents the weight or mass of the object being measured.
Of course objects have mass because Mass is any object that has weight.
The mutual force with which every two masses attract each other because of gravity is referred to as the "weight" of the objects.
Yes, an object can have mass without having weight in a microgravity environment, such as in space. Weight is a measure of the gravitational force acting on an object, so in the absence of gravity, an object with mass would not experience weight.
If the weight of an object is 50 pounds, its mass at standard conditions (assuming standard gravity of 9.81 m/s^2) would be approximately 22.68 kg.
Yes. The mass of the object doesn't change, no matter where it is. What does change is the object's weight, because that depends on what other masses are nearby.
An object with zero mass is more likely than an object with zero weight, since mass is an intrinsic property of matter, whereas weight is a force caused by gravity acting on an object's mass. A zero-weight object would require a lack of gravitational force, which is unlikely in most scenarios.