No, Young's modulus of rubber is not greater than that of steel. Young's modulus is a measure of a material's stiffness, and rubber is much more flexible compared to steel. Typically, Young's modulus for rubber ranges from about 0.01 to 0.1 GPa, while for steel, it is around 200 GPa. This significant difference indicates that steel is much stiffer than rubber.
Measure it in a graduated cylinder by seeing how much water it displaces.
When a steel rod is heated, it expands due to thermal expansion. The change in length can be calculated using the formula: ΔL = α * L0 * ΔT, where ΔL is the change in length, α is the coefficient of linear expansion for steel (approximately 11 x 10^-6 /°C), L0 is the original length (10 meters), and ΔT is the change in temperature (10°C). Applying this, the rod would expand by about 0.0011 meters or 1.1 millimeters, resulting in a new length of approximately 10.0011 meters.
The weight of a mild steel (MS) pipe can be calculated using the formula: [ \text{Weight} = \pi \times \left( \frac{D^2 - d^2}{4} \right) \times L \times \rho ] where ( D ) is the outer diameter, ( d ) is the inner diameter, ( L ) is the length of the pipe, and ( \rho ) is the density of mild steel (approximately 7850 kg/m³). This formula accounts for the volume of the pipe's material and multiplies it by the material's density to find the weight.
An adjective derivative (derivative adjective) is a verb or noun that becomes an adjective by means of adding affixes, usually suffixes. Examples: react- reactive care- careless hope- hopeless steel- steely accept- acceptable
Forwards Contract:A forward contract is the simplest of the Derivative products. It is a mutual agreement between two parties, in which the buyer agrees to buy a quantity of an asset at a specific price from the seller at a future date. The Price of the contract does not change before delivery. These type of contracts are binding, which means both the buyer and seller must stay committed to the contract. This means they are bound to deliver or take delivery of the product on which the forward contract was agreed upon. Forwards contracts are very useful in hedging.Important Characteristics of Forwards Contracts:1. They are Over the counter (OTC) contracts2. Both the buyer and seller are bound by the contractual terms3. The Price remains fixedLimitations of Forwards contracts:1. Lack of centralized trading. Any two individuals can enter into a forwards contract2. Lack of Liquidity3. Counterparty risk - The case wherein either the buyer or seller does not honour his end of the contract.Futures Contract:A futures contract is an agreement to buy or sell an asset at a certain time in the future at a specific price. The Contractual terms of the futures contracts are very clear. The Futures market was designed to solve the shortcomings in the forwards contracts. Unlike forwards, futures are traded in organized exchanges. They also use a clearing house that provides the necessary protection to both the buyer and the seller. The price of the futures contract can change prior to delivery. Hence, both participants must settle daily price changes as per the contract values.An Example of a futures contract would be an agreement to 100 tonnes of Steel at Rs. 10000/- per tonne at some date say in December 2008. If no interim payments are made and if the price of Steel moves violently, a considerable credit risk could build up. To avoid this a margin system is used by the exchanges. As per the margin system, both parties must deposit a small sum with the exchange. This amount will be a small percentage of the total contract. This amount is called the initial margin. As the steel value changes, the contract value also changes. If the contract value changes, the margin must be topped up by an amount corresponding to the change in price of steel. The margin money is the property of the person who deposits it and would be returned to them if the contract gets cancelled/completed.Characteristics of Futures contract:1. They are traded in organized exchanges2. Credit risk is eliminated with the margin system. Both parties deposit a portion of the contract with the clearing house.3. Both the buyer and seller are bound by the contract terms and are expected to honour their end of the contract.
young modulus remain unaffected ...as it depends on change in length ..
en 24 is an alloy steel in the .40 carbon range. Young's modulus between 28 and 30 million PSI Tim Engleman
yes
yes
Unless you need more precision, they are all about the same - 29,000,000 to 30,000,000 psi
what is the flexural modulus value od mild steel
shear = 77GPa
Contrary to popular expectation, rubber is not really elastic, atleast not the way scientists define elasticity. Rubber is actually much less elastic than steel. Thus for best results we use steel or similar materials, say brass, in this experiment.
30000000psi
The tangent modulus of steel varies depending on if the steel has yielded.If the steel has not yielded, and is still elastic (stresses less than approx. 275 MPa (39885 Psi) the tangent modulus will be equal to the Young's Modulus, 205 GPa (39885367)If the steel has yielded, the tangent modulus will be related by the Ramsberg-Osgood Equation, but a reasonable value to use would be approx. 1.5 GPa (2175565 Psi)
N0. The common belief is that if an object elongates easily the object is more elastic . But in Physics the object which gives more resistance to elongate is said to be more elastic . Such objects will have high Young's modulus . Steel is more elastic than copper . The Young's modulus for steel is 210 G Pa For copper it is 117 G Pa Elongation for steel is 35% and for copper it is 45% For rubber Young's modulus is 0.02 G Pa and elongation is 500 % During collision two clay balls will stick together. We call it inelastic collision . Two steel balls will rebound easily and the collision is elastic collision.
The modulus of elasticity of spring steel is typically around 30 million psi. This property determines how much a material can deform under stress and return to its original shape. A higher modulus of elasticity in spring steel means that the material can withstand greater stress without permanent deformation, resulting in more durable and efficient springs.