Types of rain gauges include
graduated cylinders, weighing gauges, tipping bucket gauges, and simply buried pit collectors. Each type has its advantages and disadvantages while collecting rain data.
U.S. standard rain gauge The standard United States
National Weather Service rain gauge, developed at the start of the 20th century, consists of an funnel emptying into a metal graduated cylinder, in diameter, which fits inside a larger container that is in diameter and tall. If the rainwater overflows the graduated inner cylinder, then the larger outer container will catch it. When measurements are taken, then the height of the water in the small graduated cylinder is measured, and the excess overflow in the large container is carefully poured into another graduated cylinder and measured to give the total rainfall. A cone meter is sometimes used to prevent
leakage that can result in alteration of the data. In locations using the metric system, the cylinder is usually marked in mm and will measure up to of rainfall. Each horizontal line on the cylinder is . In designs made for areas using Imperial units, each horizontal line represents inches.
Pluviometer of intensities The
pluviometer of intensities (or Jardi's pluviometer) is a tool that measures the average intensity of rainfall in a certain interval of time. It was initially designed to record the rainfall regime in Catalonia but eventually spread throughout the world. It consists of a rotating drum that rotates at constant
speed, this drum drags a graduated sheet of cardboard, which has the
time at the
abscissa while the y-axis indicates the
height of rainfall in
mm of rain. This height is recorded with a pen that moves vertically, driven by a buoy, marking on the paper the
rainfall over time. Each cardboard sheet is usually used for one day. As the rain falls, the water collected by the funnel falls into the container and raises the buoy that makes the pen arm rise in the vertical axis, marking the cardboard accordingly. If the rainfall does not vary, the water level in the container remains constant, and while the drum rotates, the pen's mark is more or less a horizontal line, proportional to the amount of water that has fallen. When the pen reaches the top edge of the recording paper, it means that the buoy is "up high in the tank" leaving the tip of the conical needle in a way that uncovers the regulating hole,
i.e., the maximum flow that the apparatus is able to record. If the rain suddenly decreases, making the container (as it empties) quickly lower the buoy, that movement corresponds to a steep slope line that can reach the bottom of the recorded cardboard if it stops raining. The rain gauge of intensities allowed precipitation to be recorded over many years, particularly in Barcelona (95 years), apart from many other places around the world, such as Hong Kong.
Weighing precipitation gauge A weighing-type precipitation gauge consists of a storage bin, which is weighed to record the mass. Certain models measure the mass using a pen on a rotating drum, or by using a
vibrating wire attached to a
data logger. The advantage of the tipping bucket rain gauge is that the character of the rain (light, medium, or heavy) may be easily obtained. Rainfall character is decided by the total amount of rain that has fallen in a set period (usually 1 hour) by counting the number of pulses during that period. Algorithms may be applied to the data as a method of correcting the data for high-intensity rainfall. Modern tipping rain gauges consist of a plastic collector balanced over a pivot. When it tips, it actuates a switch (such as a
reed switch) which is then electronically recorded or transmitted to a remote collection station. Tipping gauges can also incorporate elements of weighing gauges whereby a
strain gauge is fixed to the collection bucket so that the exact rainfall can be read at any moment. Each time the collector tips, the strain gauge (weight sensor) is re-zeroed to null out any drift. To measure the
water equivalent of frozen precipitation, a tipping bucket may be heated to melt any ice and snow that is caught in its funnel. Without a heating mechanism, the funnel often becomes clogged during a frozen precipitation event, and thus no precipitation can be measured. Many
Automated Surface Observing System (ASOS) units use heated tipping buckets to measure precipitation.
Optical rain gauge This type of gauge has a row of collection funnels. In an enclosed space below each is a
laser diode and a
photo transistor detector. When enough water is collected to make a single drop, it drops from the bottom, falling into the laser beam path. The sensor is set at right angles to the laser so that enough light is scattered to be detected as a sudden flash of lights. The flashes from these photodetectors are then read and transmitted or recorded. Different type of optical range gauges have been used throughout the decades. The technology has also improved.
Acoustic rain gauge Acoustic
disdrometers, also referred to as hydrophones, are able to sense the sound signatures for each drop size as rain strikes a water surface within the gauge. Since each sound signature is unique, it is possible to invert the underwater sound field to estimate the
drop-size distribution within the rain. Selected moments of the drop-size distribution yield rainfall rate, rainfall accumulation, and other rainfall properties. ==See also==