Cubic Centimeters per second (cm3/s) to Litres per year (l/a) conversion

1 cm3/s = 31557.6 l/al/acm3/s
Formula
l/a = cm3/s × 31557.6

Converting between cubic centimeters per second and liters per year involves understanding the relationships between volume and time units. Here's how to perform the conversion and some related information.

Conversion: Cubic Centimeters per Second to Liters per Year

To convert cubic centimeters per second (cm3/scm^3/s) to liters per year (L/yearL/year), you need to account for the relationships between cubic centimeters and liters, and seconds and years.

Step-by-Step Conversion:

  1. Cubic Centimeters to Liters:

    • 1 liter (L) = 1000 cubic centimeters (cm3cm^3)
    • So, 1cm3=0.001L1 cm^3 = 0.001 L

  2. Seconds to Years:

    • 1 minute = 60 seconds
    • 1 hour = 60 minutes
    • 1 day = 24 hours
    • 1 year = 365.25 days (accounting for leap years)
    • Therefore, 1 year = 365.25×24×60×60=31,557,600365.25 \times 24 \times 60 \times 60 = 31,557,600 seconds

  3. Combining the Conversions:

    • 1cm3s=0.001Ls1 \frac{cm^3}{s} = 0.001 \frac{L}{s}
    • 1Ls=31,557,600Lyear1 \frac{L}{s} = 31,557,600 \frac{L}{year}
    • So, 1cm3s=0.001×31,557,600Lyear=31,557.6Lyear1 \frac{cm^3}{s} = 0.001 \times 31,557,600 \frac{L}{year} = 31,557.6 \frac{L}{year}

Therefore, 1cm3s1 \frac{cm^3}{s} is equal to 31,557.6Lyear31,557.6 \frac{L}{year}.

Formula:

Liters per Year=Cubic Centimeters per Second×0.001×31,557,600\text{Liters per Year} = \text{Cubic Centimeters per Second} \times 0.001 \times 31,557,600

or

Liters per Year=Cubic Centimeters per Second×31,557.6\text{Liters per Year} = \text{Cubic Centimeters per Second} \times 31,557.6

Conversion: Liters per Year to Cubic Centimeters per Second

To convert liters per year (L/yearL/year) to cubic centimeters per second (cm3/scm^3/s), you need to reverse the process above.

Step-by-Step Conversion:

  1. Liters to Cubic Centimeters:

    • 1 L = 1000 cm3cm^3

  2. Years to Seconds:

    • 1 year = 31,557,600 seconds

  3. Combining the Conversions:

    • 1Lyear=1000cm3year1 \frac{L}{year} = 1000 \frac{cm^3}{year}
    • 1cm3year=131,557,600cm3s1 \frac{cm^3}{year} = \frac{1}{31,557,600} \frac{cm^3}{s}
    • So, 1Lyear=100031,557,600cm3s0.0000317cm3s1 \frac{L}{year} = \frac{1000}{31,557,600} \frac{cm^3}{s} \approx 0.0000317 \frac{cm^3}{s}

Therefore, 1Lyear1 \frac{L}{year} is approximately equal to 0.0000317cm3s0.0000317 \frac{cm^3}{s}.

Formula:

Cubic Centimeters per Second=Liters per Year×100031,557,600\text{Cubic Centimeters per Second} = \text{Liters per Year} \times \frac{1000}{31,557,600}

or

Cubic Centimeters per Second=Liters per Year×0.0000317\text{Cubic Centimeters per Second} = \text{Liters per Year} \times 0.0000317

Relevant Information and Historical Context

Volume flow rate is a fundamental concept in fluid dynamics, a branch of physics and engineering.

  • Archimedes (287–212 BC): Though not directly related to modern unit conversions, Archimedes made significant contributions to understanding fluid mechanics, which is the basis for measuring flow rates. His principle of buoyancy is a cornerstone of fluid statics.

Real-World Examples

  1. Small Stream Flow:

    • Consider a small stream flowing at a rate of 500cm3s500 \frac{cm^3}{s}. Converting this to liters per year:
      • 500cm3s×31,557.6=15,778,800Lyear500 \frac{cm^3}{s} \times 31,557.6 = 15,778,800 \frac{L}{year}

  2. Intravenous (IV) Drip:

    • An IV drip might deliver fluid at a rate of 2cm3s2 \frac{cm^3}{s}. Converting to liters per year:
      • 2cm3s×31,557.6=63,115.2Lyear2 \frac{cm^3}{s} \times 31,557.6 = 63,115.2 \frac{L}{year}

  3. Laboratory Experiment:

    • A pump in a lab experiment controls fluid flow at 0.1cm3s0.1 \frac{cm^3}{s}. Converting to liters per year:
      • 0.1cm3s×31,557.6=3,155.76Lyear0.1 \frac{cm^3}{s} \times 31,557.6 = 3,155.76 \frac{L}{year}

These examples illustrate how different flow rates in cubic centimeters per second translate to annual volumes in liters.

How to Convert Cubic Centimeters per second to Litres per year

To convert Cubic Centimeters per second to Litres per year, multiply the flow rate by the unit conversion factor. In this case, use the verified factor from cm3/s to l/a.

  1. Write the given value: Start with the flow rate you want to convert.

    25 cm3/s25 \ \text{cm}^3/\text{s}

  2. Use the conversion factor: The verified conversion factor is:

    1 cm3/s=31557.6 l/a1 \ \text{cm}^3/\text{s} = 31557.6 \ \text{l/a}

  3. Set up the multiplication: Multiply the given value by the conversion factor.

    25 cm3/s×31557.6 l/a per cm3/s25 \ \text{cm}^3/\text{s} \times 31557.6 \ \text{l/a per cm}^3/\text{s}

  4. Calculate the result: Perform the multiplication.

    25×31557.6=78894025 \times 31557.6 = 788940

  5. Result: Therefore,

    25 cm3/s=788940 l/a25 \ \text{cm}^3/\text{s} = 788940 \ \text{l/a}

Using a direct conversion factor makes this type of volume flow conversion much faster. For quick checks, estimate first so you can spot any decimal-place mistakes.

Cubic Centimeters per second to Litres per year conversion table

Cubic Centimeters per second (cm3/s)Litres per year (l/a)
00
131557.6
263115.2
394672.8
4126230.4
5157788
6189345.6
7220903.2
8252460.8
9284018.4
10315576
15473364
20631152
25788940
30946728
401262304
501577880
601893456
702209032
802524608
902840184
1003155760
1504733640
2006311520
2507889400
3009467280
40012623040
50015778800
60018934560
70022090320
80025246080
90028401840
100031557600
200063115200
300094672800
4000126230400
5000157788000
10000315576000
25000788940000
500001577880000
1000003155760000
2500007889400000
50000015778800000
100000031557600000

What is Cubic Centimeters per second?

Cubic centimeters per second (cc/s or cm3/s\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 (cm3cm^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=VtQ = \frac{V}{t}

Where:

  • QQ = Volumetric flow rate (in cm3/s\text{cm}^3/\text{s})
  • VV = Volume (in cm3\text{cm}^3)
  • tt = 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 cm3/s\text{cm}^3/\text{s} = 0.000001 m3/s\text{m}^3/\text{s} (cubic meters per second)
  • 1 cm3/s\text{cm}^3/\text{s} ≈ 0.061 in3/s\text{in}^3/\text{s} (cubic inches per second)
  • 1 cm3/s\text{cm}^3/\text{s} = 1 mL/s\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:

    A1v1=A2v2A_1v_1 = A_2v_2

    where AA is the cross-sectional area and vv 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 Litres per year?

Litres per year (L/year) is a unit used to express volume flow rate, indicating the volume of liquid (in litres) that passes through a specific point or is consumed over a period of one year. While not as commonly used as other flow rate units like litres per minute or cubic meters per second, it's useful for quantifying long-term consumption or production rates.

Understanding Litres per Year

  • Definition: Litres per year represent the total volume of liquid that flows or is used within a single year.
  • Formation: It's derived by measuring the volume in litres and the time period in years. It can be calculated from smaller time intervals by scaling up. For example, if you know the daily consumption in litres, multiplying it by 365 (or 365.25 for accounting for leap years) gives the annual consumption in litres per year.

Litres per year=Litres per day×365.25\text{Litres per year} = \text{Litres per day} \times 365.25

Practical Applications & Examples

Litres per year are particularly useful in contexts where long-term accumulation or consumption rates are important. Here are a few examples:

  • Water Consumption: Household water usage is often tracked on an annual basis in litres per year to assess water footprint and manage resources effectively. For example, the average household might use 200,000 litres of water per year.
  • Rainfall Measurement: In hydrology, the annual rainfall in a region can be expressed as litres per square meter per year, providing insights into water availability. The formula to convert annual rainfall in millimetres to litres per square meter is:

Litres/m2/year=Millimetres/year\text{Litres/m}^2\text{/year} = \text{Millimetres/year} 

Since 1 millimetre of rainfall over 1 square meter is equal to 1 litre.
  • Fuel Consumption: Large industrial facilities or power plants might track fuel consumption in litres per year. For example, a power plant might use 100 million litres of fuel oil per year.
  • Beverage Production: Breweries or beverage companies might measure their production output in litres per year to monitor overall production capacity and sales. A large brewery might produce 500 million litres of beer per year.
  • Irrigation: Agricultural operations use litres per year to keep track of how much water is being used for irrigation purposes.

Conversion to Other Units

Litres per year can be converted to other common flow rate units. Here are a couple of examples:

  • Litres per day (L/day): Divide litres per year by 365.25.

    L/day=L/year365.25\text{L/day} = \frac{\text{L/year}}{365.25}

  • Cubic meters per year (m3m^3/year): Divide litres per year by 1000.

    m3/year=L/year1000{m^3}\text{/year} = \frac{\text{L/year}}{1000}

Interesting Facts

While there isn't a specific "law" or famous person directly associated with litres per year, the concept is fundamental in environmental science and resource management. Tracking annual consumption and production rates helps in:

  • Sustainability: Monitoring resource usage and identifying areas for improvement.
  • Environmental Impact Assessments: Evaluating the long-term effects of industrial activities.

Frequently Asked Questions

What is the formula to convert Cubic Centimeters per second to Litres per year?

To convert Cubic Centimeters per second to Litres per year, multiply the flow rate by the verified factor 31557.631557.6.
The formula is: l/a=cm3/s×31557.6l/a = cm^3/s \times 31557.6.

How many Litres per year are in 1 Cubic Centimeter per second?

There are 31557.631557.6 Litres per year in 1cm3/s1 \, cm^3/s.
This means a continuous flow of 11 Cubic Centimeter per second adds up to 31557.6l/a31557.6 \, l/a over a full year.

Why is the conversion factor 31557.631557.6 used?

The factor 31557.631557.6 is the verified relationship between cm3/scm^3/s and l/al/a.
It combines the unit change from cubic centimeters to litres and the time change from seconds to years into one constant.

How do I convert a larger flow rate from cm3/scm^3/s to l/al/a?

Multiply the number of Cubic Centimeters per second by 31557.631557.6.
For example, 10cm3/s=10×31557.6=315576l/a10 \, cm^3/s = 10 \times 31557.6 = 315576 \, l/a.

Where is converting cm3/scm^3/s to l/al/a useful in real life?

This conversion is useful when comparing small continuous flow rates to annual liquid usage or output.
It can help in water system monitoring, laboratory dosing, irrigation planning, and estimating yearly consumption from a steady flow.

Can I use this conversion for water, fuel, or other liquids?

Yes, this conversion works for any liquid when you are converting volumetric flow units only.
Since cm3/scm^3/s and l/al/a both measure volume over time, the factor 31557.631557.6 stays the same regardless of the liquid type.

People also convert

cm3/s to mm3/scm3/s to dm3/scm3/s to dm3/mincm3/s to dm3/hcm3/s to dm3/dcm3/s to dm3/acm3/s to ml/scm3/s to cl/s

Complete Cubic Centimeters per second conversion table

cm3/s
UnitResult
Cubic Millimeters per second (mm3/s)1000 mm3/s
Cubic Decimeters per second (dm3/s)0.001 dm3/s
Cubic Decimeters per minute (dm3/min)0.06 dm3/min
Cubic Decimeters per hour (dm3/h)3.6 dm3/h
Cubic Decimeters per day (dm3/d)86.4 dm3/d
Cubic Decimeters per year (dm3/a)31557.6 dm3/a
Millilitres per second (ml/s)1 ml/s
Centilitres per second (cl/s)0.1 cl/s
Decilitres per second (dl/s)0.01 dl/s
Litres per second (l/s)0.001 l/s
Litres per minute (l/min)0.06 l/min
Litres per hour (l/h)3.6 l/h
Litres per day (l/d)86.4 l/d
Litres per year (l/a)31557.6 l/a
Kilolitres per second (kl/s)0.000001 kl/s
Kilolitres per minute (kl/min)0.00006 kl/min
Kilolitres per hour (kl/h)0.0036 kl/h
Cubic meters per second (m3/s)0.000001 m3/s
Cubic meters per minute (m3/min)0.00006 m3/min
Cubic meters per hour (m3/h)0.0036 m3/h
Cubic meters per day (m3/d)0.0864 m3/d
Cubic meters per year (m3/a)31.5576 m3/a
Cubic kilometers per second (km3/s)1e-15 km3/s
Teaspoons per second (tsp/s)0.2028841362 tsp/s
Tablespoons per second (Tbs/s)0.0676280454 Tbs/s
Cubic inches per second (in3/s)0.06102402537402 in3/s
Cubic inches per minute (in3/min)3.6614415224414 in3/min
Cubic inches per hour (in3/h)219.68649134648 in3/h
Fluid Ounces per second (fl-oz/s)0.0338140227 fl-oz/s
Fluid Ounces per minute (fl-oz/min)2.028841362 fl-oz/min
Fluid Ounces per hour (fl-oz/h)121.73048172 fl-oz/h
Cups per second (cup/s)0.0042267528375 cup/s
Pints per second (pnt/s)0.00211337641875 pnt/s
Pints per minute (pnt/min)0.126802585125 pnt/min
Pints per hour (pnt/h)7.6081551075 pnt/h
Quarts per second (qt/s)0.001056688209375 qt/s
Gallons per second (gal/s)0.0002641720523438 gal/s
Gallons per minute (gal/min)0.01585032314063 gal/min
Gallons per hour (gal/h)0.9510193884375 gal/h
Cubic feet per second (ft3/s)0.00003531468492103 ft3/s
Cubic feet per minute (ft3/min)0.002118881095262 ft3/min
Cubic feet per hour (ft3/h)0.1271328657157 ft3/h
Cubic yards per second (yd3/s)0.000001307949370859 yd3/s
Cubic yards per minute (yd3/min)0.00007847696225152 yd3/min
Cubic yards per hour (yd3/h)0.004708617735091 yd3/h

Volume flow rate conversions