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Wednesday, August 28, 2013

#140 - New Application Landing Pages on Nova website

A couple of years ago, we added some content pages to our website in an effort to provide more information on what industries we serve and what our equipment actually does. We already had a product catalog which showcased our products, but this was not the best venue to provide general descriptive information about our industry and company. These new content pages were called ‘landing pages’ by the people who assisted us with them.

The idea behind our landing pages is to provide an interval layer between the home page and the product pages. The landing pages can provide relevant information that is beyond the scope of the home page and that leads into relevant areas of a product catalog.



Our original landing pages represented a first attempt at bringing some organization to our very diverse product line and the many industries we serve. We did a couple pages that featured information on our products from a gas perspective, e.g. oxygen, carbon dioxide, etc. We also did a couple pages that were targeted to the industries we serve, e.g. landfill, power generation, etc.

Historically, we have noticed that our customers often have a general idea what they want, but they select the incorrect instrument for their needs. This is entirely understandable; we don’t expect people to know our product line in detail. We have some evidence that the landing pages were a frequent destination for our website visitors and were hopefully somewhat helpful as a transition into our product catalog.

However, we always felt that our original landing pages were a little light on detail. So we recently revised the content and added more pages. The intent is to provide our visitors with more relevant information and hopefully provide evidence that we have some analytical expertise.

We have done the following pages so far:

Check out whatever interests you.

As we think of more ideas, they will no doubt find their way onto a landing page on the website.














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Friday, August 23, 2013

#139 - Coal Mine Gas Analysis Applications – Part 2

Last time, we talked about some gas analysis applications that emerged from a coal mine project in the southern USA. This mine is equipped with an elaborate tube system which allows air samples to be drawn from different parts of the mine to a central monitoring station.

The first instruments we provided to this facility performed beyond expectations. This enabled further cooperation between our companies on some additional projects. Here are the 3rd and 4th applications from this project.

Application #3 – Carbon Monoxide and Hydrogen Research

The next request from this facility was to expand the baseline air analysis. In detecting fire events in a distant part of the mine, it was suspected that there would be brief spikes of ppm CO and ppm H2 coming in through the relevant areas of the tube bundle.

Previously, measurement of these gases was accomplished using a Tedlar sample bag and an external laboratory located above ground. This process took several days to complete which effectively negated its value as a fire detection methodology. A continuous CO / H2 analyzer would provide an immediate measure of these gases without the inconveniences associated with the existing process.

The requested ranges were:
CO: 0 – 1,000 PPM
H2: 0 – 1,000 PPM

These gases and ranges are frequently achieved in analyzers using electrochemical sensors. However, these sensors have issues with mutual interferences. That is, CO provokes a response on the H2 sensor, and H2 provokes a response on the CO sensor. It would be impossible to obtain a reliable and accurate result where both gases were present in the sample at the same time.

The first and obvious approach was to switch the CO measurement methodology to IR (infrared). We have a long-path IR that is ppm CO capable. This method eliminated one of the interference problems. The IR reading will not be affected by the levels of H2 that were expected in the sample.

We do not have access to an alternate method for measuring ppm H2. However, we can utilize the stable output from the IR CO detector to provide some compensation to the H2 reading. This will subtract some of the CO effects from the displayed H2 result. However, it does not remove the physical effects of the CO on the H2 sensor. A spike of CO would provoke the expected response on the H2 sensor. The compensation circuit would help, but afterwards, the H2 sensor would be slow to recover.

So we devised a calibration procedure which allowed some ‘re-freshing’ of the H2 sensor to occur when needed. However, we noticed that the CO / H2 effects only seemed to occur during the spike periods. At the levels normally present in the mine, there did not appear to be any adverse affects on the continuous analysis. We assume that even if a spike occurred, the elevated readings would be valuable and the post-spike recovery could be managed as needed.

As with the previous applications, this analyzer required a reliable data-logging feature. We upgraded the data logger to a unit with larger capacity and a more convenient data storage process. The collected data is written directly to a SD card similar to what is used in many digital cameras. The SD cards are swapped out weekly for subsequent data analysis. We mounted the logger itself on the inside of the analyzer door. This protected it and allowed easy wiring access.

Data logger mounted on door of
gas analyzer and writes to SD memory card.


Application #4 – Air Flow Research

Very low levels of SF6 (sulfur hexafluoride) can be released in the mine as a tracer gas and tracked using the tube bundle. By ‘sniffing’ for SF6 in the relevant tubes, the air flow in the mine can be modeled. SF6 tends to have a persistent and detectable presence even after a long time and at very low levels. This allows the air flow model to be detailed and to capture subtleties not detectable by other means.

We have produced instruments for 0-100% SF6 for analysis of switch gear atmospheres. (Here is a link.) In large electrical switches where the possibility exists of dangerous arcing, a blanket atmosphere of SF6 will quench the arcs. To check the purity of the SF6 atmosphere, a gas analyzer can be used. The measurement methodology on these models is thermalconductivity.



However, the mine tracer gas application required a range of 0-50ppm. A percent scale instrument would not be useful in this case. The thermal conductivity detector does not have ppm SF6 capability. So we provided an infrared detector which can measure 0-50ppm SF6 in a background of breathable ambient air.

The same style of data logger was also integrated onto the door of the analyzer cabinet. Although it probably wasn’t necessary, we tested the output of this detector in background of air with spikes of H2 & CO as mentioned above in Application #3. No interferences or disruptions to the SF6 reading were observed.

Front view of continuous SF6 analyzer during
inspection phase. SF6 analysis on this instrument
done by infrared detector.

So far, all of the equipment we have supplied into this facility has worked well. The applications discussed in this post were somewhat experimental for us. But are occasionally willing to step outside of our standard designs for projects that interest us. With patience and support from the end-user in this case, we managed to produce instruments that will hopefully make a useful contribution to mine safety research.

For information on these and other gas analyzer systems, give Mike or Dave at Nova a call, or send us an e-mail.
1-800-295-3771
sales at nova-gas dot com
websales at nova-gas dot com
http://www.nova-gas.com/



Friday, August 9, 2013

#138 - China’s Pollution-Fighting Budget Will Have to be Bigger Than its Military Budget

We mentioned air pollution levels in China in a previous post.




The folks at Next Big Future have distilled a couple of articles from various sources into this interesting post about China’s plans for remediation.


A couple of the reader comments are also informative and worth reading.

Wednesday, August 7, 2013

#137 - This Caught our Interest Because We’re Into Hydrogen

We have been providing accurate hydrogen (H2) analysis for many years. Usually, the hydrogen equipment that our analyzers are hooked up to are quite large. Like this H2-cooled power generator:





This article from Wired features a much smaller handheld H2 generator for recharging phones. This is obviously for a very different purpose than the power generator shown above. Interesting stuff. May be coming soon to a store near you.

Photo: Tim Moynihan/WIRED

Friday, August 2, 2013

#136 - Coal Mine Gas Analysis Applications – Part 1

We recently posted some information about air analysis in mine shafts here and here. These discussions reminded me of another series of gas analysis inquiries that we had from the mining industry.

For literally centuries, the problem of subterranean coal mine fires has persisted in many areas of the world.

Just to mention a few:


A couple years ago, a coal mine facility in the southern United States approached us for assistance with gas analysis. In the initial development and construction phases, this mine was considered to be a dangerously high risk for a number of things including fires.

An elaborate system of tubes was built into the mine. These small tubes connected all areas of the mine to a centralized monitoring station. The gas atmosphere in any area of the mine can be accessed by sampling from one of the tubes in the ‘tube bundle’.


Example of tube bundle in underground mine.


Subsequent re-evaluation of the mine’s hazards lead to a down-grading of the fire risk consideration. However, the tube system had already been designed and installed. This allowed the mine to function as a giant research laboratory. Nova’s involvement with the mine began in this capacity in 2009-2010.

Application #1 – Mine Atmosphere Baseline Measurement

To evaluate the mine atmosphere at a somewhat generalized level, a portable analyzer was requested for these three gases and ranges:
Oxygen: 0 - 25.0%
Carbon Monoxide: 0 – 2,000 PPM
Carbon Dioxide: 0 – 3,000 PPM

For this application, long-term analysis of tubes in the bundle allowed for establishment of baseline levels in the mine upon which further research could be done. We provided a special version of the Model 375K for these measurements.

Even though this is only a portable instrument intended for temporary ‘spot-check’ type analysis, it has been running continuously on this experiment for a couple of years now. I think maybe we have replaced the built-in pump once. Other than that, the mine has been very impressed with the performance of this little analyzer. They have since bought one or two more of these units.

The baseline experiment required long-term analysis of each of the tubes in the mine bundle. So it seemed like a good idea to provide a reliable way of logging the data into a format that would allow further evaluation and research. So these versions of the Model 375K were provided with a 4-20mA analog output for each gas reading. A portable data logger was also provided. The outputs wrote to the datalogger during analysis. The data logger has a serial output which can be connected to a computer. Software on the computer captures the data on the logger.



Application #2 - Testing of Gas Diffusion through Coal Core Samples

The mine also briefly used the Model 375K to study a possible dynamic in spontaneous coal combustion. A coal core sample was set up in the lab with a known atmosphere on one side of the core sample. The side with the atmosphere, the ‘input’ side, was subjected to 1psig greater than the output side. The basic idea was that the pressure differential between the two sides would possibly force the gases through the coal to be released at the output side.



The analyzer would measure the output side to help evaluate the rate of gas movement through the coal in this mine. If gas moved through the coal at a particular rate, perhaps it could be a factor in the development of coal combustion in certain areas of the mine.

Last I heard, this experiment was abandoned because the diffusion rate even through a small core sample was insignificant enough to be eliminated as a source of concern. The research people at the mine suspected that to begin with, but there were sufficient reasons to run the experiment at least for a limited time.

Next post will discuss two other interesting gas analysis applications that came out of this mine facility. Part 2 is here.

For information on these and other gas analyzer systems, give Mike or Dave at Nova a call, or send us an e-mail.
1-800-295-3771
sales at nova-gas dot com
websales at nova-gas dot com
http://www.nova-gas.com/