Answer:
I think it is attacking technique?
Answer:
C₁₀ = 6.3 KN
Explanation:
The catalog rating of a bearing can be found by using the following formula:
C₁₀ = F [Ln/L₀n₀]^1/3
where,
C₁₀ = Catalog Rating = ?
F = Design Load = 2.75 KN
L = Design Life = 1800 rev/min
n = No. of Hours Desired = 10000 h
L₀ = Rating Life = 500 rev/min
n₀ = No. of Hours Rated = 3000 h
Therefore,
C₁₀ = [2.75 KN][(1800 rev/min)(10000 h)/(500 rev/min)(3000 h)]^1/3
C₁₀ = (2.75 KN)(2.289)
<u>C₁₀ = 6.3 KN</u>
Answer
The answer and procedures of the exercise are attached in the following archives.
Step-by-step explanation:
You will find the procedures, formulas or necessary explanations in the archive attached below. If you have any question ask and I will aclare your doubts kindly.
Answer:
Other formulas equivalent of I=E/R are:
- R = E/I
- E = IR
Where,
R = Resistance
E = Voltage
I = Current
Explanation:
For some conductors of power, the electric flow which will course through them is straightforwardly relative to the voltage concerned them. At the point when a microscopic perspective on Ohm's law is taken, it is found to rely on the way that the float speed of charges through the material is relative to the electric field in the conduit. The proportion of voltage to current is known as the resistance, and if the proportion is constant over a wide scope of voltages, the material is said to be an "ohmic" material. On the off chance that the material can be described by such a resistance, at that point the current can be anticipated from the relationship:
I = E/R
Electric Current = Voltage/Resistance
The voltage changes around any shut circle must total to zero. Regardless of what way you take through an electric circuit, in the event that you come back to your beginning stage you should gauge a similar voltage, compelling the net change around the circle to be zero. Since voltage is electric potential vitality per unit charge, the voltage law can be believed to be an outcome of preservation of vitality. The voltage law has extraordinary handy utility in the investigation of electric circuits. It is utilized related to the present law in many circuit investigation errands.
The electric current in amperes that streams into any intersection in an electric circuit is equivalent to the current which streams out. This can be believed to be only an announcement of preservation of charge. Since you don't lose any charge during the stream procedure around the circuit, the absolute current in any cross-segment of the circuit is the equivalent. Alongside the voltage law, the current law is a useful asset for the investigation of electric circuits.
Answer:
Explanation:
The concept of amperes law is applied;
Given the current density vector in the medium is J,
the electric flux density vector is D,
and the magnetic flux density vector is B. The line integral of the magnetic field intensity H
considering the orientation of the contour is adopted according to ampere law;
deta x B = Jc + JD
delta x B = Jc + partial differential D/partial differential t
where Jc = conduction current density
JD = displacement current density