P&R Labpak - Everything for your laboratory

P&R Labpak - Everything for your laboratory
Our Head Office in St Helens

Friday, 11 April 2014

On this day - April 11th 1970

Apollo 13 was launched on April 11, 1970, at 13:13 CST from the Kennedy Space Centre, Florida.  It was the seventh manned mission in the American Apollo space program and the third intended to land on the Moon. The lunar landing was aborted after an oxygen tank exploded two days later, crippling the Service Module (SM) upon which the Command Module (CM) depended. Despite great hardship caused by limited power, loss of cabin heat, shortage of potable water, and the critical need to jury-rig the carbon dioxide removal system, the crew returned safely to Earth on April 17.

Apollo 13 launches from Kennedy Space Center, April 11, 1970
A film was made regarding the Apollo 13 mission in 1995 directed by Ron Howard who went to great lengths to create a technically accurate movie, employing NASA's technical assistance in astronaut and flight controller training for his cast, and even obtaining permission to film scenes aboard a reduced gravity aircraft for realistic depiction of the "weightlessness" experienced by the astronauts in space.

Three days into the mission, the crew send a live television transmission from Odyssey, but the networks, believing the public now regards lunar missions as routine, decline to carry the broadcast live. Astronaut Swigert is told to perform a standard housekeeping procedure of stirring the two liquid oxygen tanks in the Service Module. When he flips the switch, one tank explodes, emptying its contents into space and sending the craft tumbling. The other tank is soon found to be leaking, prompting Mission Control to abort the Moon landing.

The crew is soon subjected to freezing conditions.  When the carbon dioxide exhaled by the astronauts reaches the Lunar Module's filter capacity and approaches dangerous levels, an engineering team quickly invents a way to make the Command Module's square filters work in the Lunar Module's round receptacles.  The crew eventually get the Odyssey going and make a safe return to earth.

The Apollo 13 Command Module
The Apollo 13 incident gave rise to the famous line 'Houston, We've Got a Problem'.

Further Apollo missions continued which resulted in successful manned landings on the moon.  There are a number of proposed future missions to the moon - most of them robotic or remote missions using rovers.  However the Russians did announce in 2007 their intention to send cosmonauts to the moon by 2025 and establish a permanent robotically operated base there in 2027–2032.

For more information visit:-
http://en.wikipedia.org/wiki/Apollo_13

Friday, 4 April 2014

Kevlar

Kevlar® is the registered trademark for a para-aramid synthetic fiber, related to other aramids such as Nomex and Technora. Developed by Stephanie Kwolek at DuPont in 1965, this high strength material was first commercially used in the early 1970s as a replacement for steel in racing tires. Typically it is spun into ropes or fabric sheets that can be used as such or as an ingredient in composite material components.

Kevlar® is a material formed by combining para-phenylenediamine and terephthaloyl chloride. Aromatic polyamide (aramid) threads are the result. They are further refined, by dissolving the threads and spinning them into regular fibres. When woven, Kevlar® forms a strong and flexible material. If layers of the woven Kevlar® are combined with layers of resin, the resulting ‘rigid’ material is light and has twenty times the strength of steel. It is also superior to specialist metal alloys. However, Kevlar® is expensive due to the demands of the manufacturing process and the need for specialist equipment.

Currently, Kevlar® has many applications, ranging from bicycle tires and racing sails to body armor because of its high tensile strength-to-weight ratio; by this measure it is 5 times stronger than steel on an equal weight basis.
Aramid Fibre
Kevlar® is a well-known component of personal armour such as combat helmets, ballistic face masks, and ballistic vests. Other military uses include bulletproof facemasks used by sentries and spall liners used to protect the crews of armoured fighting vehicles.  Emergency Service's protection gear also uses Kevlar® sometimes if it involves high heat (e.g., tackling a fire), and Kevlar® body armour such as vests for police officers.
Bullet Proof vests
 
Kevlar® is used to manufacture gloves, sleeves, jackets, chaps and other articles of clothing designed to protect users from cuts, abrasions and heat. Kevlar® based protective gear is often considerably lighter and thinner than equivalent gear made of more traditional materials.
For more information visit:-
 
 
 


Friday, 28 March 2014

What is absolute zero?


In theory, absolute zero is the temperature where the particles of matter stop moving. Absolute zero is impossible to achieve, because all particles move, even if it is just a small vibration. Some people have created temperatures very close to absolute zero, but the record temperature was 100 pK (Picokelvin) above absolute zero.  Even getting close to absolute zero is difficult because anything that touches an object being cooled near absolute zero would give heat to the objects. Scientists use lasers to slow atoms when cooling objects to very low temperatures.

The Kelvin and Rankine temperature scales are defined so that absolute zero is 0 kelvins (K) or 0 degrees Rankine (°R). The Celsius and Fahrenheit scales are defined so that absolute zero is −273.15 °C or −459.67 °F.

At this stage the pressure of the particles is zero. If we plot a graph to it, we can see that the temperature of the particles is zero. The temperature cannot go down any further. Also, the particles cannot move in "reverse" either because as the movement of particles is vibration, vibrating in reverse would be nothing but simply vibrating again. The closer the temperature of an object gets to absolute zero, the less resistive the material is to electricity therefore it will conduct electricity almost perfectly, with no measurable resistance.

The Third Law of Thermodynamics says that nothing can ever have a temperature of absolute zero.

The Second Law of Thermodynamics says that all engines that are powered by heat (like car engines and steam train engines) must release waste heat and can not be 100% efficient. This is because the efficiency (percent of energy the engine uses up that is actually used to do the engine's job) is 100%×(1-Toutside/Tinside), which only is 100% if the outside temperature is absolute zero which it can not be. So, an engine can not be 100% efficient, but you can make its efficiency closer to 100% by making the inside temperature hotter and/or the outside temperature colder.

In September 2013, MIT scientists cooled a sodium gas to the lowest temperature ever recorded -- only half-a-billionth of a degree above absolute zero.

Absolute zero is defined to be −273.15°C, or 0 K.
 
For more information visit:-


Friday, 21 March 2014

Holmium

Holmium is a chemical element with the symbol Ho and atomic number 67 and is a rare earth element. It was discovered by Swedish chemist Per Theodor Cleve. Its oxide was first isolated from rare earth ores in 1878 and the element was named after the city of Stockholm.

It is a relatively soft and malleable silvery-white metal. It is too reactive to be found uncombined in nature, but when isolated, is relatively stable in dry air at room temperature. However, it reacts with water and rusts readily, and will also burn in air when heated.


Holmium has the highest magnetic strength of any element and therefore is used for the polepieces of the strongest static magnets.

Holmium oxide appears to have different colours depending on changes in ambient lighting. Under natural light, it's yellow, but under fluorescent lighting, it's pink.

Ho2O3, left: natural light, right: fluorescent lamp light
Holmium is used in yttrium-iron-garnet (YIG)- and yttrium-lanthanum-fluoride (YLF) solid-state lasers found in microwave equipment (which are in turn found in a variety of medical and dental settings). Holmium lasers emit at 2.08 micrometres, and therefore are safe to eyes. They are used in medical, dental, and fibre-optical applications.

Holmium is one of the colorants used for cubic zirconia and glass, providing yellow or red colouring.  Glass containing holmium oxide and holmium oxide solutions (usually in perchloric acid) have sharp optical absorption peaks in the spectral range 200–900 nm. They are therefore used as a calibration standard for optical spectrophotometers and are available commercially.

For more information visit:-
http://en.wikipedia.org/wiki/Holmium
http://www.theguardian.com/science/grrlscientist/2012/aug/10/1?guni=Article:in%20body%20link

Friday, 14 March 2014

Traceability and Uncertainty

Traceability & Uncertainty
 
Kelvin Quote
Quote by Lord Kelvin on the importance of measurement 

Introduction

Measurement today is more valuable than ever. We depend on measurement for almost everything - from time keeping to weather forecasts, from DIY work at home to heavy-duty manufacturing, industrial research and medical science.
Since measurement plays such a fundamental part in our lives, it is important that the accuracy of the measurement is fit for purpose, i.e. it fully meets the requirements of the application. Every measurement is inexact and therefore requires a statement of uncertainty to quantify that inexactness. The uncertainty of a measurement is the doubt that exists about the result of any measurement.
One way of ensuring that your measurements are accurate is by tracing them back to national standards. This method of guaranteeing a measurement's accuracy through an unbroken chain of reference is called traceability.
Scientist with Scales Cartoon
Scientist with scales 

Accurate Measurement

Accurate measurement enables us to:
  • Maintain quality control during production processes
  • Comply with and enforce laws and regulations
  • Undertake research and development
  • Calibrate instruments and achieve traceability to a national measurement standard
  • Develop, maintain and compare national and international measurement standards
Successful measurement depends on the following:
  • Accurate instruments
  • Traceability to national standards
  • An understanding of uncertainty
  • Application of good measurement practice
There are many factors that can cause inaccuracy:
  • Environmental effects
  • Inferior measuring equipment
  • Poor measuring techniques
 
Bent Ruler
Ruler melting in the sun 
Inferior Ruler
Inferior measuring equipment 
Butcher Scales
Poor measurement techniques


In the United Kingdom, the National Measurement System (NMS) is in place to enable measurements to be traced back to their national standards. As the UK's national standards laboratory, NPL is at the pinnacle of this system guaranteeing the accuracy of physical measurements for the nation and abroad.

What is Uncertainty?

No measurement is ever guaranteed to be perfect. Uncertainty of measurement is the doubt that exists about the result of any measurement. By quantifying the possible spread of measurements, we can say how confident we are about the result.
Explanation Quote
Explanation of the error vs uncertainty 

Expressing Uncertainty

A measurement result is only complete when accompanied by a statement of its uncertainty. A statement of uncertainty is required in order to decide if the result is adequate for its intended purpose and consistent with other similar results.
It does not matter how accurate a measuring instrument is considered to be, the measurements made will always be subject to a certain amount of uncertainty.
In order to express the uncertainty of a measurement, we need to evaluate as accurately as possible the errors associated with that particular measurement.
For example - we might say that a particular stick is 200 centimetres long, plus or minus 1 centimetre, at a 95% confidence level. This is written:
200 cm ±1 cm at a level of confidence of 95%
This means we are 95% sure that the length of the stick is between 199 centimetres and 201 centimetres.

Why does Uncertainty Matter?

Calculating and expressing uncertainty is important to anybody wishing to make good quality measurements.
It is also crucial where uncertainty can influence a pass or failure in a particular test, and must therefore be reported on a calibration certificate.
There are established rules for the evaluation of uncertainty. [More information can be found in NPL's Good Practice Guide (011) 'A Beginner's Guide to Uncertainty of Measurement'.] Of course, we must all make every effort to 'control' the uncertainty in our measurements. This is done by regular inspection and calibration of our instruments, careful calculation, good record-keeping.
Various Accuracies
                        Various accuracies 

What is Traceability?

Traceability is a method of ensuring that a measurement (even with its uncertainties) is an accurate representation of what it is trying to measure.

What is Traceability to National Standards?

The simple and basic concept behind calibration is that measuring equipment should be tested against a standard of higher accuracy.
It should be possible to demonstrate an unbroken chain of comparisons that ends at a national standards body such as NPL. This demonstrable linkage to national standards with known accuracy is called 'traceability'.
National standards laboratories such as NPL also routinely undertake international comparisons in order to establish worldwide consensus on the accepted value of fundamental measurement units.
Representatives of seventeen nations signed the Convention of the Metre (Convention du Mètre) on 20th May 1875 in Paris. This diplomatic treaty provided the foundations for the establishment of the Système International d'Unités (International System of Units, international abbreviation SI) in 1960. Since then, national standards laboratories have cooperated in the development of measurement standards that are traceable to the SI.
Any organisation can achieve traceability to national standards through the correct use of an appropriate traceable standard from NPL.

Who is Who in the Measurement World?

International Committee for Weights and MeasuresCIPM - Comité International des Poids et Mesures) the world's highest authority in the field of measurement science.
International Bureau of Weights and Measures(BIPM - Bureau International des Poids et Mesures) co-ordinating body for international metrology, based in Sèvres, France.
National Physical Laboratory(NPL) is the UK's national standards laboratory, a world-leading centre in the development and application of highly accurate measurement technology and material science.

What is the Difference Between ACCURACY and PRECISION?

The difference between accuracy and precision is illustrated below by 4 different archers… each with varying degree of ability. The bull's-eye in the target represents the true value of a measurement.
 
Target1
Low accuracy and low precision (poor repeatability)
Stone age man missed the bull's-eye and the 3 attempts were not near each other.
Archer1
Target2
Low accuracy but high precision
Robin Hood's Merry Man missed the bull's-eye but the 3 attempts were near each other.
Archer2
 Target3
Higher accuracy but low precision
Native American's 3 attempts were near the bull's-eye, but were not near each other.
Archer3
Target4
High accuracy and high precisionOlympic archer hit the bull's-eye 3 times!
Archer4
Accuracy is a qualitative term relating the mean of the measurements to the true value, while precision is representative of the spread of these measurements. Even when we are precise and accurate, there will still be some uncertainty in our measurements; the scientists challenges are to evaluate the uncertainty and make this as small as possible. When the uncertainty of a measurement is evaluated and stated, then the fitness of purpose for a particular application can be properly understood.

For more details and to download a poster with this information visit:-
http://www.npl.co.uk/educate-explore/factsheets/traceability-and-uncertainty/

Friday, 7 March 2014

On this day......

On March 7th 2009, the Kepler space observatory, designed to discover Earth-like habitable planets orbiting other stars, is launched.  The spacecraft is named after the Renaissance astronomer Johannes Kepler who is best known for his laws of planetary motion.

Kepler is designed to survey a portion of our region of the Milky Way to discover dozens of Earth-size extrasolar planets in or near the habitable zone and estimate how many of the billions of stars in our galaxy have such planets.


Kepler uses a photometer that continually monitors the brightness of over 145,000 main sequence stars in a fixed field of view. This data is transmitted to Earth and analysed to detect periodic dimming caused by extrasolar planets that cross in front of their host star.

As of July 2013, Kepler had found 134 confirmed exoplanets in 76 stellar systems, along with a further 3,277 unconfirmed planet candidates. In November 2013, astronomers reported, based on Kepler space mission data, that there could be as many as 40 billion Earth-sized planets orbiting in the habitable zones of sun-like stars and red dwarf stars within the Milky Way Galaxy.  11 billion of these estimated planets may be orbiting sun-like stars.  The nearest such planet may be 12 light-years away, according to the scientists.

For more information visit:-
http://en.wikipedia.org/wiki/Kepler_(spacecraft)
http://kepler.nasa.gov/

Friday, 28 February 2014

Timers!

Many laboratories use timers for various purposes - timing heating applications, cooling periods, cycling events, enzyme tests, viscosity measurements, animal studies, and other timed lab tests etc..

When choosing the best timer or stopwatch for your lab you should take into consideration ease-of-programming as well as ease-of-use. You can select from a variety of models based on timing modes, timing capacities, count directions, resolution, and accuracy. General -purpose timers can time the length of events with an alarm function for your laboratory. They are generally available in several styles - single channel, multi channel, count up, count down etc..
VWR Traceable Timers

Labs these days need to have traceable results and the introduction of Traceable® timers has proved popular initially in America and more recently in Europe.
 
P&R Labpak are able to offer VWR Brand Traceable® timers and also some traceable tools.

Items are individually serialised, calibrated and certified, traceable to NIST.


Various timers available including multi coloured ones, jumbo versions, four channel, flashing LED, Extra-extra LOUD ones for use in high-noise areas, waterproof and steamproof ideal for use in wash-down areas.  Also available are traceable® thermometer/clock/humidity monitor, calendar clock, wall clock models.


Finally there are some traceable® tools such as Digital Calipers, SpatulaBalance and Counter-Pens.  Traceable® products are provided with a Traceable® Calibration Certificate from an ISO 17025 calibration laboratory.
 
 
Visit http://www.prlabs.co.uk/news/article.php?Id=245 to download the brochure and find out more.