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ENVIRONMENTAL
Monitoring

Sampling and monitoring instruments for air, water and soil for the environmental, agricultural, mining and forestry markets.

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GEOTECHNICAL & MATERIALS Testing

Materials and Product testing for soil, asphalt, petroleum, concrete, cement, food and cosmetic industries.

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View the Products in Test and Measurement Instrumentation

TEST & MEASUREMENT
Instrumentation

Sensors, transducers and instrumentation for industry, manufacturing, research and development and factory automation.

View the Products in Test and Measurement Instrumentation

Rental Equipment Sell-off – Save up to 80%!

March 24, 2021
Category: Environmental Monitoring

Heat Flux Sensing in Battery Monitoring

November 28, 2019
Category: News

The article below is from greenTEG.

Heat FluxBatteries are critical devices for many people today: they power smartphones, laptops, and even cars! The wide adoption of batteries was possible because of the invention of the lithium-ion battery (whose inventors won the Nobel Prize this year). If we look at its results, the Li-Ion battery was surely one of the most important engineering achievements of the last 50 years.

Given its importance, during the past decades, many researchers have been working to better understand how batteries work, as a mean to improve its efficiency and performance.
For that purpose, it is fundamental to correctly monitor the calorimetric performance of batteries, a critical indicator of the phase change of lithium-ion in the battery’s electrodes. Through that, we can figure out the state of charge (SOC), and the state of health (SOH) of any battery.
Hence, it is very important to set up a reliable monitoring system. Using heat flux sensors for that purpose has the advantage of downsizing the measurement device and saving quite a lot of money. It also improves features resolution, reduces the noise level, and has no offset.
Moreover, heat flux sensors combined with external temperature sensors allow measuring the inner temperature of batteries, helping to prevent the thermal runaway of the device.
At greenTEG, we have been helping battery researchers all over the world to monitor batteries with accuracy, efficiency, and at a very reasonable price. If you want more information about this topic, click here to download our latest presentation about this topic.

 

Fiber Optic Testing Helps Ensure EV Battery Health and Safety

October 30, 2019
Category: News

The article below is from Luna Blog

EVs face unique design challenges in order to be competitive with gasoline-powered vehicles. The root of many of these challenges is in the EV battery pack. Drivers want similar vehicle range per charge when compared to a tank of gas, as well as the convenience they are used to with refilling a tank in just a few minutes. This means battery packs need to be able to store enough energy to go comparable distances without stopping and to get back on the road quickly once depleted.

Many EVs today use thousands of lithium ion cells to form the complete battery pack that powers a vehicle. Lithium ion batteries come with certain limits. They do not charge well at very low temperatures, and they can be dangerous if overheated, overcharged, charged too quickly or physically damaged.

 The understanding of lithium ion batteries … and by extension their safety is continuously evolving. However, in a system that has thousands of cells packed in close proximity, a defective battery could cause thermal runaway and lead to a chain of violent cell failures. While rare, such an event is of concern in a passenger-filled vehicle that can sustain physical damage, especially one that uses a pack that is charged as quickly as possible.

High Definition Fiber Optic Sensing is a valuable tool for ensuring battery health and driver safety. Sensors are electrically passive, corrosion resistant and immune to EMI, allowing them to make measurements within a battery pack or an individual cell without risking a short circuit or picking up noise from electronics. The temperatures of all battery cells can be monitored during recharge or discharge to quickly look for damaged or faulty cells, which need to be replaced.

One possible future for EVs is detachable battery packs where a car pulls into a recharge station but instead of plugging in and charging its battery, the pack is removed and quickly replaced with a different fully charged pack, leaving the previous one to be charged and stored at the station. Packs would not belong to any individual driver. In this case, fiber could be placed within each pack and then while being recharged at the station, each battery pack could also be scanned to ensure the health of all cells in circulation. This application would grow in importance over time as the average age of battery packs in use rises. This application would allow batteries to charge at a safe rate in climate-controlled environments for an overall increase in battery life.

Check out our Video – Mapping and Monitoring the Temperature of a Battery Pack Using High Definition Fiber Optic Sensing

Remote Sound Level Monitor

August 1, 2019
Category: Rentals

EM2030 Sound Level Monitor

Sequoia invents Super-Turbidity methodology (Patent Pending)

June 25, 2019
Category: News

The article below is from Sequoia Press Release 

12776146-lisst-aobs (1)

In a world’s first, Sequoia Scientific, Inc. of Bellevue, WA, USA has invented a method (patent pending) to pair data from a turbidity meter (e.g. an OBS) with Sequoia’s acoustic backscatter sensor, the LISST-ABS. The pairing of the acoustic and the optical data leads to a much-improved estimate of suspended sediment concentration (SSC), compared to the estimate that either sensor can provide on its own. The new methodology allows for measurements of SSC that is within a factor of 2 of the actual value, e.g. based on sampling and subsequent filtration. This is an order of magnitude improvement over currently used technologies.

Sequoia is also introducing a new instrument system based on this technology, the LISST-AOBS Super-Turbidity Meter. All existing LISST-ABS sensors can be expanded to the LISST-AOBS Super-Turbidity Meter. Also, all existing turbidity sensors can be expanded to the LISST-AOBS Super-Turbidity Meter – contact Sequoia for details!

The implications of the new method and the introduction of the LISST-AOBS Super-Turbidity Meter are two-fold:

1) existing regulations (e.g. for stormwater, construction, environmental monitoring) that calls for monitoring of turbidity can be adhered to while

2) the user AT THE SAME TIME can obtain an ACCURATE estimate of SSC.

According to the US EPA, excessive sediment is the leading cause of impairment of the Nation’s waters . High SSC values influence virtually all aspects of aquatic life in a detrimental manner. Accurate measurements of SSC with low-cost sensors that can be deployed for months or years are therefore of importance for a wide range of environmental quality programs, remediation efforts, court cases etc.

The LISST-AOBS Super-Turbidity meter can help provide the data needed to make the decisions that will protect the Nation’s waters.

Link to Press Release on Sequoia website:  https://www.sequoiasci.com/about/news/sequoia-invents-super-turbidity-patent-pending-methodology/

Link to LISST-AOBS product page on Sequoia website:
https://www.sequoiasci.com/product/lisst-aobs/

Portable Ground Penetrating Radar – Proceq GPR Live

April 16, 2019
Category: Rentals

NEW: Worldwide smallest draw-wire sensor

April 8, 2019
Category: News

The article below is from Micro-Epsilon Press Release

smallest draw-wire sensor

The new wireSENSOR MT series from Micro-Epsilon includes extremely compact draw-wire displacement sensors which can be integrated into very tight spaces. The wireSENSOR MT19 model is the smallest draw-wire sensor in the world. With a measuring range up to 40 mm and wire accelerations up to 60 g, the sensor is particularly suitable for use in applications where high dynamics are required (crash tests, simulators or test benches).

This series comprises two more miniature draw-wire sensors – the MT33 and MT56 models which cover measuring ranges up to 130 mm. In relation to their measuring ranges, their design is kept as compact as possible.

Equipped with a robust aluminum housing, these three miniature draw-wire sensors are ideally suited to industrial applications. Two through-bores in the housing and an integrated eyelet attached to the measuring wire enable fast and easy mounting.

 

Accurate dosing of corrosion inhibitors

March 18, 2019
Category: News

The article below is from Bronkhorst Press Release

Cori-Flow

In industrial applications, especially in the chemical, process and oil and gas industry, corrosion can be a real challenge. These types of industries are coping with demanding environmental and process conditions in production and operation. Prevention or control of corrosion by inhibiting often proves to be an economic solution.

A corrosion inhibitor system will add small concentrations of (bio)chemicals into the process. The effectiveness of an inhibitor system greatly depends on the correct injection amount, and can be influenced by the environmental and process conditions; so accuracy is crucial here.

Using a low flow control system containing a Bronkhorst (mini) CORI-FLOW mass flow meter can help you dose amounts of corrosion inhibitors more accurately. High accuracy and high turndown ratio is achieved based on pure mass flow measurement with this flow meter. It can directly control valves and pumps by on-board PID control and can be further optimised with PLC and HMI control extending both performance and flexibility.

Bronkhorst’s Coriolis dosing system approach enables real-time monitoring, control and logging of injection rates. This allows online checking of flow rates and instantaneous re-setting of the required flow rate. Asset management and preventive maintenance is supported with several active diagnostics.

ARAMIS – From 3D Measuring Data to Vibration Types

February 22, 2019
Category: News

The article below is from GOM website.csm_news_aramis-vibration-types

Calculation models show the type of vibration of parts. Measurements are carried out to help to understand which types of vibration are formed during operation of the part. GOM offers the sensor system for carrying out these measurements.

The ARAMIS 3D sensor is a stereo camera system and provides accurate 3D coordinates using the triangulation principle. The sensor measures 3D coordinates dynamically and provides measuring results such as strains, 3D displacements and 3D deformations. The 3D displacements captured with a high temporal resolution are used for the vibration analysis. The optical metrology offers many advantages for the vibration analysis such as:

  • Non-contact measuring principle
  • No wiring of accelerometers required
  • Fast setup and calibration of the sensor
  • Compact dimensions of the sensors
  • Ultra-light and lasting measurement targets
  • Synchronous measurement of many points in 3D – thus points can be measured also unsteadily
  • 3D displacement results for each measuring point

Depending on the application, measurements on the part are carried out in a point-based or full-field manner. To specify the type of vibration with the ARAMIS sensor, the excitation of the parts can be different. A simple harmonic excitation, an impact test or a rotating part during operation can be measured. The frame rate depends on the excitation. The ARAMIS SRX system of the ARAMIS sensor family has a maximum image recording rate of 335 Hz with a 12-megapixel resolution. In addition, by reducing the image height, the image recording rate can be increased up to 2000 Hz.

From the captured image data, surface components or point components are created. These components are inspected for 3D displacements over time.

Read more -> Here

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