YOUNG Wind Sentry Anemometer

For wind speed only, Model 03102 Wind Sentry Anemometer is available separately.

Features

  • Anemometer uses three lightweight hemispherical cups to measure wind speed
  • Cup wheel rotation produces an AC frequency with optional mA or VDC output
  • Precision stainless steel ball bearings are used throughout
Your Price $338.00
Drop ships from manufacturer
YOUNG
Government and Educational PricingGovernment and Educational Pricing
Free Lifetime Tech SupportFree Lifetime Tech Support
Free Ground ShippingFree Ground Shipping
ImagePart#Product DescriptionPriceStockOrder
YOUNG Wind Sentry Anemometer03102 Wind Sentry anemometer
$338.00
Drop ships from manufacturer
YOUNG Wind Sentry Anemometer 03102L Wind Sentry anemometer, 4-20 mA = 0-50 m/s
$640.00
Drop ships from manufacturer
YOUNG Wind Sentry Anemometer 03102V Wind Sentry anemometer, 0-1 V = 0-50 m/s
$648.00
Drop ships from manufacturer
YOUNG Wind Sentry Anemometer
03102
Wind Sentry anemometer
Drop ships from manufacturer
$338.00
YOUNG Wind Sentry Anemometer
03102L
Wind Sentry anemometer, 4-20 mA = 0-50 m/s
Drop ships from manufacturer
$640.00
YOUNG Wind Sentry Anemometer
03102V
Wind Sentry anemometer, 0-1 V = 0-50 m/s
Drop ships from manufacturer
$648.00
ImagePart#Product DescriptionPriceStockOrder
YOUNG Sensor Cables 18641 Sensor cable, 2 conductor shielded, 22 AWG, per ft.
$0.72
Drop ships from manufacturer
RM Young Cables 18446 Sensor cable, 5 conductor shielded, 22 AWG, per ft.
$0.92
Drop ships from manufacturer
Sensor cable, 2 conductor shielded, 22 AWG, per ft.
Drop ships from manufacturer
$0.72
RM Young Cables
18446
Sensor cable, 5 conductor shielded, 22 AWG, per ft.
Drop ships from manufacturer
$0.92

For wind speed only, Model 03102 Wind Sentry Anemometer is available separately. The anemometer uses three lightweight hemispherical cups to measure wind speed. Cup wheel rotation produces an AC frequency that is linearly proportional to wind speed. Precision stainless steel ball bearings are used throughout.

Range:
Wind Speed: 0-50 m/s (112 mph)
Accuracy:
Wind Speed: ±0.5 m/s (1.1 mph)
Threshold*:
Anemometer: 1.1 m/s (2.5 mph)
Signal Output:
Wind Speed Signal: AC sine wave, 1 pulse per rev.
Power Requirement: Potentiometer excitation 15 VDC max

Questions & Answers
No Questions
Please, mind that only logged in users can submit questions

In The News

Charles River Algal Blooms Stop Swimming and Launch a Floating Wetland

The Charles River used to be a swimming hotspot for Cambridge and Boston residents. Decades of industrial pollution and nutrient runoff have degraded water quality and eliminated public swimming in the Lower Charles, but a movement is afoot to get Boston and Cambridge back in the water. One step toward the goal of a safely swimmable river—without the need to obtain a permit, as is now necessary—is detecting and managing the harmful algal blooms that appear on the river. An experimental floating wetland and new research and analysis of water quality data that shows a possible effective detection system for algal blooms on the Charles River are two new steps toward the goal of safe, accessible swimming.

Read More

Harnessing the Gulf Stream for Renewable Energy

The Gulf Stream, the massive western boundary current off the east coast of North America, moves water from the Gulf of Mexico north and west across the Atlantic Ocean. There’s a lot of energy in that much moving water and researchers are trying to put it to use. Although the Gulf Stream’s path shifts (researchers say it acts like a wiggling garden hose), in a couple of spots, it stays relatively stable. At one such spot off the coast of Cape Hatteras, North Carolina, researchers have dropped moorings and research instruments to study the current with the eventual goal of harnessing it for renewable energy.

Read More

Buoys in the time of Covid: Delays to important information

In early 2020, Michigan found itself facing one of the worst outbreaks of Covid-19 in the country. Though it’s close to second nature now, businesses, schools and governments were suddenly forced to conduct business without close contact. Universities and research institutions had to pause some scientific research. Whatever was able to continue slowed to a crawl. Around the Great Lakes, a network of buoys monitors dozens of water quality parameters and lake conditions, reporting them in real time. This year, the monitoring season was cut a bit short as Covid-19 restrictions hit in the weeks before buoys were set to be deployed.

Read More