Posts Tagged ‘Else Lie’

“Sensational” 15% can become up to 50% oil recovery rate from dead oil wells with nanoparticle-enhanced water

Monday, June 17th, 2013

Texas, the Middle East, and/or Alberta leap to mind before Norway and China when one thinks of research into oil extraction, which makes this June 14, 2013 news item on Nanwerk about a Norway-China collaboration particularly intriguing,

When petroleum companies abandon an oil well, more than half the reservoir’s oil is usually left behind as too difficult to recover. Now, however, much of the residual oil can be recovered with the help of nanoparticles and a simple law of physics.

Oil to be recovered is confined in tiny pores within rock, often sandstone. Often the natural pressure in a reservoir is so high that the oil flows upwards when drilling reaches the rocks containing the oil.

In order to maintain the pressure within a reservoir, oil companies have learned to displace the produced oil by injecting water. This water forces out the oil located in areas near the injection point. The actual injection point may be hundreds or even thousands of metres away from the production well.

Eventually, however, water injection loses its effect. Once the oil from all the easily reached pores has been recovered, water begins emerging from the production well instead of oil, at which point the petroleum engineers have had little choice but to shut down the well.

The petroleum industry and research community have been working for decades on various solutions to increase recovery rates. One group of researchers at the Centre for Integrated Petroleum Research (CIPR) in Bergen, collaborating with researchers in China, has developed a new method for recovering more oil from wells – and not just more, far more. [emphasis mine]

The Chinese scientists had already succeeded in recovering a sensational 15 per cent of the residual oil in their test reservoir when they formed a collaboration with the CIPR researchers to find out what had actually taken place down in the reservoir. Now the Norwegian partner in the collaboration has succeeded in recovering up to 50 per cent of the oil remaining in North Sea rock samples.

The ?, 2013 article (Nanoparticles helping to recover more oil) by Claude R. Olsen/Else Lie. Translation: Darren McKellep/Carol B. Eckmann for the Research Council of Norway, which originated the news item, explains what is left after the easy oil has been extracted and how this news technique squeezes more oil out of the well,

Water in an oil reservoir flows much like the water in a river, accelerating in narrow stretches and slowing where the path widens.

When water is pumped into a reservoir, the pressure difference forces the water away from the injection well and towards the production well through the tiny rock pores. These pores are all interconnected by very narrow tunnel-like passages, and the water accelerates as it squeezes its way through these.

The new method is based on infusing the injection water with particles that are considerably smaller than the tunnel diameters. When the particle-enhanced water reaches a tunnel opening, it will accelerate faster than the particles, leaving the particles behind to accumulate and plug the tunnel entrance, ultimately sealing the tunnel.

This forces the following water to take other paths through the rock’s pores and passages – and in some of these there is oil, which is forced out with the water flow. The result is more oil extracted from the production well and higher profits for the petroleum companies.

The article writers do not provide a description of the nanoparticles but they do describe the genesis of this Norwegian-Sino collaboration,

The idea for this method of oil recovery came from the two Chinese researchers Bo Peng and Ming yuan Li who completed their doctorates in Bergen 10 and 20 years ago, respectively. The University of Bergen and China University of Petroleum in Beijing have been cooperating for over a decade on petroleum research, and this laid the foundation for collaboration on understanding and refining the particle method.

At first it was not known if the particles could be used in seawater, since the Chinese had done their trials with river water and onshore oilfields. Trials in Bergen using rock samples from the North Sea showed that the nanoparticles also work in seawater and help to recover an average of 20?30 per cent, and up to 50 per cent, more residual oil.

 

 

Tags: , , , , , , , , , , , ,
Posted in energy, mining, nanotechnology | No Comments »

Nano sense of snow

Wednesday, December 19th, 2012

According to a Dec. 19, 2012 news item on Azonano there’s a nanotechnology-enabled sensor which can identify snow depth,

Snow is the be-all and end-all for alpine ski resorts. Now a tiny sensor has been developed to determine how much cold gold there is on the slopes and how much more should be produced. The sensor is based on Norwegian radar technology and is no larger than a match head.

The processor chip from Novelda is the result of high-level nanotechnology. The minuscule Norwegian-designed silicon chip has already become an international success. Customers around the world are creating applications based on the technology.

The US-based company Flat Earth has drawn on Novelda’s technology to develop the SDS-715 snow-depth sensor. [emphasis mine] It is capable of measuring snow depth from 15 cm to 2 m with a margin of error of 3.5 cm.

The sensor is mounted beneath the vehicle that prepares the tracks. Snow depth is measured at one-second intervals. A separate application can be used to display snow depths via Google Earth.

There are widespread applications for the nanoscale sensor. Eirik Næss-Ulseth, Chairman of the Board in Novelda, envisions integrating the chips into athletic garments to replace pulse sensors that are currently held in place with an elastic band.

“We have already proven that the chips can be used to measure pulse and breathing rates at a distance,” he explains.

Novelda was founded as a spin-off company from the University in Oslo. …

The Research Council of Norway provided the Dec. 17, 2012 news release, written by Siw Ellen Jakobsen/Else Lie and translated by Glenn Wells/Carol B. Eckmann, which originated the news item. Oddly, Novelda issued a June 5, 2011 news release about a similar, if not identical, product,

Flat Earth Incorporated announced today they have developed the first mobile snow depth sensor based on the Novelda AS NVA6000 CMOS impulse radar chip. The SDS-715 provides a non-contact approach for determining snow depth on the go. [emphasis mine] Measurement range is 0.15 to 2.0 meters with an accuracy of approximately 3.5 cm, snow condition dependent.

This rugged low cost snow depth measurement system is designed for snow grooming operations at Alpine and Nordic ski resorts. Snow depth beneath the snowcat is measured every second, approximately every 3 meters at 8 kmph. The SDS-715 is cheaper than current ground penetrating radar systems on the market today. When used with Flat Earth’s CatWorks Snowcat navigation and information system, depth maps of the resort trails can be created and viewed in Google Earth.

For those new to marketing and promotion, it never hurts to reissue or send more information about a previously announced product, especially when it can be tied in with a season. Still, this is a bit longer than usual between campaigns.

For anyone interested in Flat Earth; nanoscale radar products and consulting, the company’s website is under construction and due to be unveiled sometime December 2012 (or, later this month).

Tags: , , , , , , , , , , , ,
Posted in nanotechnology | No Comments »