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Cubic Centimeters per second (cm³/s) to Cubic kilometers per second (km³/s) conversion

Cubic Centimeters per second to Cubic kilometers per second conversion table

Cubic Centimeters per second (cm³/s)	Cubic kilometers per second (km³/s)
0	0
1	1e-15
2	2e-15
3	3e-15
4	4e-15
5	5e-15
6	6e-15
7	7e-15
8	8e-15
9	9e-15
10	1e-14
20	2e-14
30	3e-14
40	4e-14
50	5e-14
60	6e-14
70	7e-14
80	8e-14
90	9e-14
100	1e-13
1000	1e-12

How to convert cubic centimeters per second to cubic kilometers per second?

Converting between cubic centimeters per second ( $cm^3/s$ ) and cubic kilometers per second ( $km^3/s$ ) involves understanding the relationship between centimeters and kilometers. This conversion doesn't depend on base 10 or base 2, as it's a unit conversion based on the metric system.

Conversion Formula

The key is to remember that 1 kilometer (km) is equal to 100,000 centimeters (cm), or $10^5$ cm. Therefore, 1 cubic kilometer ( $km^3$ ) is equal to $(10^5 cm)^3 = 10^{15} cm^3$ .

Converting Cubic Centimeters per Second to Cubic Kilometers per Second

To convert from $cm^3/s$ to $km^3/s$ , you need to divide by $10^{15}$ :

1 \, \frac{cm^3}{s} = \frac{1}{10^{15}} \, \frac{km^3}{s} = 1 \times 10^{-15} \, \frac{km^3}{s}

So, 1 cubic centimeter per second is equal to $1 \times 10^{-15}$ cubic kilometers per second.

Step-by-step Conversion:

Start with the value in $cm^3/s$ : 1 $cm^3/s$
Divide by $10^{15}$ : $1 \, cm^3/s \div 10^{15} = 1 \times 10^{-15} \, km^3/s$

Converting Cubic Kilometers per Second to Cubic Centimeters per Second

To convert from $km^3/s$ to $cm^3/s$ , you need to multiply by $10^{15}$ :

1 \, \frac{km^3}{s} = 1 \times 10^{15} \, \frac{cm^3}{s}

So, 1 cubic kilometer per second is equal to $1 \times 10^{15}$ cubic centimeters per second.

Step-by-step Conversion:

Start with the value in $km^3/s$ : 1 $km^3/s$
Multiply by $10^{15}$ : $1 \, km^3/s \times 10^{15} = 1 \times 10^{15} \, cm^3/s$

Real-World Examples and Context

While converting between $cm^3/s$ and $km^3/s$ might seem abstract, understanding volume flow rate is crucial in many scientific and engineering fields.

Hydrology: Volume flow rate is used to measure river discharge, which is the volume of water flowing past a point per unit of time. Typical river discharge is measured in $m^3/s$ , but smaller streams can be in $cm^3/s$ . To put into perspective, if you are converting $cm^3/s$ of a stream to $km^3/s$ , you are typically dealing with very small values in $km^3/s$ .
Industrial Processes: Chemical engineers use volume flow rate to control the rate at which fluids are pumped through pipes in a chemical plant.
Medical Applications: Doctors use volume flow rate to measure blood flow through arteries and veins.

Interesting Facts:

Archimedes' Principle: While not directly related to the conversion itself, Archimedes' principle is fundamental to understanding fluid displacement and volume, which underlies the concept of volume flow rate. Archimedes famously used his principle to determine whether a crown was made of pure gold.

Summary

$1 \, cm^3/s = 1 \times 10^{-15} \, km^3/s$
$1 \, km^3/s = 1 \times 10^{15} \, cm^3/s$

See below section for step by step unit conversion with formulas and explanations. Please refer to the table below for a list of all the Cubic kilometers per second to other unit conversions.

What is Cubic Centimeters per second?

Cubic centimeters per second (cc/s or $\text{cm}^3/\text{s}$ ) is a unit of volumetric flow rate. It describes the volume of a substance that passes through a given area per unit of time. In this case, it represents the volume in cubic centimeters that flows every second. This unit is often used when dealing with small flow rates, as cubic meters per second would be too large to be practical.

Understanding Cubic Centimeters

A cubic centimeter ( $cm^3$ ) is a unit of volume equivalent to a milliliter (mL). Imagine a cube with each side measuring one centimeter. The space contained within that cube is one cubic centimeter.

Defining "Per Second"

The "per second" part of the unit indicates the rate at which the cubic centimeters are flowing. So, 1 cc/s means one cubic centimeter of a substance is passing a specific point every second.

Formula for Volumetric Flow Rate

The volumetric flow rate (Q) can be calculated using the following formula:

Q = \frac{V}{t}

Where:

$Q$ = Volumetric flow rate (in $\text{cm}^3/\text{s}$ )
$V$ = Volume (in $\text{cm}^3$ )
$t$ = Time (in seconds)

Relationship to Other Units

Cubic centimeters per second can be converted to other units of flow rate. Here are a few common conversions:

1 $\text{cm}^3/\text{s}$ = 0.000001 $\text{m}^3/\text{s}$ (cubic meters per second)
1 $\text{cm}^3/\text{s}$ ≈ 0.061 $\text{in}^3/\text{s}$ (cubic inches per second)
1 $\text{cm}^3/\text{s}$ = 1 $\text{mL/s}$ (milliliters per second)

Applications in the Real World

While there isn't a specific "law" directly associated with cubic centimeters per second, it's a fundamental unit in fluid mechanics and is used extensively in various fields:

Medicine: Measuring the flow rate of intravenous (IV) fluids, where precise and relatively small volumes are crucial. For example, administering medication at a rate of 0.5 cc/s.
Chemistry: Controlling the flow rate of reactants in microfluidic devices and lab experiments. For example, dispensing a reagent at a flow rate of 2 cc/s into a reaction chamber.
Engineering: Testing the flow rate of fuel injectors in engines. Fuel injector flow rates are critical and are measured in terms of volume per time, such as 15 cc/s.
3D Printing: Regulating the extrusion rate of material in some 3D printing processes. The rate at which filament extrudes could be controlled at levels of 1-5 cc/s.
HVAC Systems: Measuring air flow rates in small ducts or vents.

Relevant Physical Laws and Concepts

The concept of cubic centimeters per second ties into several important physical laws:

Continuity Equation: This equation states that for incompressible fluids, the mass flow rate is constant throughout a closed system. The continuity equation is expressed as:

$A_1v_1 = A_2v_2$

where $A$ is the cross-sectional area and $v$ is the flow velocity.

Khan Academy's explanation of the Continuity Equation further details the relationship between area, velocity, and flow rate.
Bernoulli's Principle: This principle relates the pressure, velocity, and height of a fluid in a flowing system. It states that an increase in the speed of a fluid occurs simultaneously with a decrease in pressure or a decrease in the fluid's potential energy.

More information on Bernoulli's Principle can be found here.

What is Cubic Kilometers per Second?

Cubic kilometers per second ( $km^3/s$ ) is a unit of flow rate, representing the volume of a substance that passes through a given area each second. It's an extremely large unit, suitable for measuring immense flows like those found in astrophysics or large-scale geological events.

How is it Formed?

The unit is derived from the standard units of volume and time:

Cubic kilometer ( $km^3$ ): A unit of volume equal to a cube with sides of 1 kilometer (1000 meters) each.
Second (s): The base unit of time in the International System of Units (SI).

Combining these, $1 \, km^3/s$ means that one cubic kilometer of substance flows past a point every second. This is a massive flow rate.

Understanding Flow Rate

The general formula for flow rate (Q) is:

$Q = \frac{V}{t}$