Question

How does Boyle's law relate to a bicycle pump?

Answer 1

Hint: The pressure factor of a fixed amount of gas is conversely relative to the volume it involves inasmuch as the temperature stays consistent.
Boyle's Law expresses that the pressure factor and volume of a gas are contrarily corresponding. A bike siphon is an extraordinary model that shows Boyle's Law. At the point when you push down on the siphon, the volume inside the bicycle siphon diminishes, and the pressure factor of the air increments so that it's driven into the tire.

Complete step by step answer:
 Boyle's Law essentially portrays the connection between the pressure factor and volume of an encased gas when Temperature stays steady. That relationship, typically communicated as \[{P_1}{V_1} = {\text{ }}{P_2}{V_2}\], simply implies that the result of pressure factor \[x\] volume stays unaltered as either or both are changed.
Since pressure X volume stays consistent, for instance, multiplying the tension on an encased gas will diminish its volume to \[1/2\] its past size. Significantly increasing the pressure factor will diminish its volume to \[1/3\], etc. Then again, on the off chance that you twofold the volume accessible to an encased gas, pressure is divided.
Boyle's Law is a hand bike siphon. By pushing down on the cylinder, the volume of the gas diminishes, the particles are currently having more odds of crashing with the inside dividers of the siphon and this expands the pressure factor of the air inside so it is constrained into the tire.

Note:
The outright pressure factor applied by a given mass of an ideal gas is conversely corresponding to the volume it involves if the temperature and measure of gas stay unaltered inside a shut framework.
In the event that you have ever attempted to drive in the unclogger of a needle or a bike pump while fixing the opening with your finger, you will have seen Boyle's Law in real life!