Pairing up with local basketball team

UK thermometer manufacturer, TM Electronics (TME), are proud to announce their partnership with local National Basketball League team, Worthing Thunder. TME have supplied brand new uniforms for the Worthing Thunder U13 Juniors team 2014/2015 season.

Image courtesy of Worthing Thunder

Technology in Temperature

Temperature specialists, TME, are UK leaders in the manufacture and design of temperature sensors, thermometers and probes, ever pushing the boundaries of technology and producing more innovative developments. Based in Worthing, TME aim high and strive to be the best – as does Worthing Thunder, making this pairing of a local manufacturer with a local team a perfect match.

Worthing Thunder

Worthing Thunder Juniors are currently joint top of their league, and is comprised of a team of selected players from Worthing, Brighton, Crawley and Haywards Heath, among other places. This team is part of an elite programme that provides a natural pathway for the players to progress from the age of 13 years all the way to the men’s first team, who play in the National Basketball League, Division 1 (the second highest league in the country!)

The boys love their new kit, and have been storming through the current season – recently beating the league leaders 58-47!

Daniel Hildreth, Head Coach Worthing Thunder: “We have played one game in the new kit and the boys love it! It looks really smart.”


For more details on TME’s extensive range of thermometers and temperature sensors visit www.tmethermometers.com for online purchasing or contact the Sales Team on 01903 700651 or sales@tmethermometers.com

Spotlight on...Legionnaires' Disease

TME temperature sensors, thermometers and probes are used across a huge range of different industries and applications. In this series of posts, we'll shine a spotlight on some of the most troublesome temperature problems, and how TME helps to solve them.

Legionella Bacteria (Photo sourced from: http://www.theguardian.com)

Legionnaires' Disease is an incredibly dangerous illness, caused by the legionella bacteria. It is the most serious of a group of diseases caused by this bacteria, which are known collectively as Legionellosis. 

The disease presents with symptoms of high fever, muscle pain and chills. If the bacteria spreads to infect the lungs, it can result in a persistent cough, chest pains and breathing difficulties. 

Certain members of the public, such as people over 45, people with impaired immune systems and smokers, are much more susceptible to contract Legionnaires' disease than the general population. Although the disease is generally treatable with antibiotics, it can lead to complications such as septic shock or some organs, such as lungs and kidneys, ceasing to work correctly. A 2014 outbreak of the disease in Portugal was been the cause of at least 7 deaths.

Legionnaires' disease is contracted when people inhale small droplets of water which contain the legionella bacteria. There are certain conditions in which the legionella bacterium thrives. One of the most common of these is when water is stored/distributed at a tepid temperature.

The potential effects of an outbreak of Legionnaires' disease are so severe that the HSE (Health and Safety Executive), which is a UK government agency, have put in place requirements for helping businesses to prevent outbreaks.

According to the HSE guidelines, to prevent an outbreak of Legionnaires’ disease water should be supplied at at least 60°C from the heat source, and should return to the source from each water circulating loop at at least 50°C (or 55°C in healthcare premises). All individual outlets should reach 50°C (or 55°C in healthcare premises) within one minute of turning on the tap. Cold water should be distributed below 20°C.

The HSE’s code of practise L8 requires all businesses to implement a full legionella risk assessment, and to maintain an effective water temperature testing regime in order to prevent outbreaks of the disease.

Solutions from TME

TME are offering a range of solutions to help streamline water temperature testing for preventing Legionnaires' disease, including dual purpose surface/immersion probes, barcode scanning thermometers to help make record-keeping paperless and effortless, and, most recently, the TC Wall Port System.

TME's TC Wall Port System is a quick and easy solution that centres around the TC Wall Port, a small, unobtrusive thermocouple monitoring point that enables remote testing of difficult to access temperature testing points from up to 20m away.

Depending on the number of showers, taps and water tanks present, a reliable legionella control regime could require thousands of temperature tests every year. Taking temperatures from running taps is straightforward but boxed-in pipes and TMV’s can be awkward and time consuming as are tanks located at high level or in confined spaces.

TME’s innovative TC Wall Port System speeds up temperature checks on sentinel points, pipes, mixer valves, calorifiers and cold water tanks. Easy-to-use kits combine accurate thermometers with discrete, wall-mounted thermocouple monitoring points for immediate temperature readings up to 20 metres away with no loss of accuracy.Main Applications

• Boxed-in TMVs – no need to access the valve each time to check hot water temperature
• Pipework including boiler flow and return points
• Water Storage Tanks (with special immersion probe)
• High-level test points - avoid using ladders and Working at Height restrictions
• Remote measurement of cold storage, environmentally sensitive rooms or hazardous areas

How does the system work?This system uses a low-cost fine wire temperature sensor, attached to the temperature test point (pipe, valve etc) and left in-situ. The wire is then run to the TC Wall Port, sited in a convenient position. Temperature is read by plugging a thermometer into the port. Compatible thermometers include TME’s MM2000 or for paperless recording our MM7000 ThermoBarScan. For water tanks, the KM07immersion probe is also ideal. See attached information sheet.

The products that make up the TC Wall Port System:

The Wall PortThe new device is a thermocouple temperature sensor monitoring point which can be conveniently mounted to facilitate spot checks on any test point with difficult or impaired access. The port is designed for use with fine wire probes which are attached to the temperature test point and left in-situ. These wires are then run to the port – a wall-mounted, small white box measuring just 52 x 52mm. This allows temperatures to be taken by simply ‘plugging’ a standard thermocouple thermometer into the wall port – much easier and less time-consuming than dismantling boxing below sinks or using ladders to access covered tanks, necessitating working at height. 
The Fine Wire
When using the TC Wall Port, a fine wire probe is run from the port to a temperature testing point. The KA01 Fine Wire Probe is a simple sensor which can be attached to anything from a pipe to a calorifier. The probe comes in a variety of lengths up to 20m, so, however far away a temperature test point is, the TC Wall Port System can monitor it.

The Immersion ProbeFor the measurement of water tanks, the KM07 Water Tank Immersion Probe can be immersed in the tank and stay there permanently, enabling the remote monitoring of water tank temperature. The KM07 is also available up to 20m in length, so even if your water tank is in the roof or attic, you can still monitor its’ temperature accurately using the TC Wall Port SystemRemarkably cost-effectiveThe TC Wall Port System is an affordable option. Got a problem test point in mind? With our standard wall port equipment you could simplify your legionella prevention regime for less than £25 including VAT.



The Connection Cable
If you are using the TC Wall Port System, you will need a connection cable. TME’s KMPC1MP Connection Cable plugs into the two-pin plug at the front of the Wall Port at one end, and to the identical plug in your thermometer at the other. Now you’re ready to take your remote temperature readings.

The Dual Purpose Probe
Most water temperature spot checks require testing of running water and testing of surface temperature of a pipe. When the test points are easy to access, both of these jobs can be carried out using TME’s KS16-S Dual Purpose Probe. This strong and durable probe is able to carry out both surface and immersion temperature testing, giving facilities managers an all-in-one solution to water temperature spot checks.

The ThermometersIf you’re planning on carrying out water temperature tests, you’ll need a thermometer! Below are two of TME’s bestselling digital thermocouple thermometers, which are compatible with all TME probes.
The MM2000TME’s bestselling thermometer, the MM2000 Handheld Thermometer, is a single-input, IP67 waterproof digital thermometer which is both highly accurate and cost-effective. All MM2000 Thermometers are entered into the Thermometer for Life scheme, which guarantees to replace/repair any thermometer you break for no more than £35.The MM7000
For complete paperless recording, the MM7000 ThermoBar Scan Thermometer can record and download not only temperature, time and date but also the unique location of every pipe, tap or calorifier tested. This is possible through its’ integrated barcode scanner. Downloads are made via the inbuilt Bluetooth technology, to any PC, PDA, tablet or smartphone. Keeping accurate, reliable records of every test point will considerably reduce the risk of the spread of legionella in your facility.




Trust the experts
The TC Wall Port System is the most recent in a range of innovative products developed specifically by TM Electronics to support water temperature monitoring, and remote monitoring of sensitive or hazardous environments. The company leads the field in producing robust, waterproof equipment and portable kits to improve on reliability and convenience.

For more information on TME thermometers and probes for legionella monitoring, visit www.tmethermometers.com for online purchasing or contact the Sales Team on 01903 700651, sales@tmethermometers.com

History of Thermometery, Part 4: Thermocouples

The history of temperature stretches back for thousands of years. Temperature has always been an important and essential part of daily life and society, ever since bakers and blacksmiths relied on temperature to control chemical reactions.

Nowadays, temperature is better understood than ever, and a wide range of temperature-measuring equipment – thermoscopes, thermocouples and many types of thermometer – is necessary to measure and to help control it.

This blog series hopes to open your eyes about the history of temperature measurement, from the ancient through to the modern day. Enjoy!

Some of TME's thermocouple probes

The thermocouple is now the most widely used thermometer, or 'temperature sensor.' It uses electrical technology to show temperature. The principle behind thermocouples was discovered by the German-Estonian physicist Thomas Johann Seebeck in 1821, and is known as the 'thermoelectric effect' or 'Seebeck effect'.

Two metals are used, one contained within the thermocouple, and one forming a probe which acts as a sensor to test the temperature of a substance or atmosphere. The word 'thermocouple' comes from the idea of the 'coupling' of two different metals.

The difference between their temperatures is expressed electrically through their difference in voltage. As the temperature of the metal inside the thermocouple is already known, the difference between the two temperatures can let us easily deduce the temperature of the metal attached to the probe.

This deduction is usually carried out electronically by a tiny microchip inside the instrument, so that the scale or display on a thermocouple thermometer simply shows the temperature which the probe has sensed. 

Thermocouples are used extensively in electrical engineering and industry. For instance, they are essential in fields such as heating appliance safety, radiation testing and in many areas of manufacture. 

Thermocouples can be found in many different types (such as K, T, J, E, N and B), named after the metals from which their wires are made. Two popular thermocouple types are K and T.

K type thermocouples are known for offering a wide temperature range (-200 to +1372 degrees C) at low cost, and are popular across a wide range of uses.

T type thermocouples do not have such a wide temperature range (-200 to +400 degrees C), however they are known to be highly accurate, with an accuracy of 0.25 of a degree C. This makes them ideal for use in food manufacturing, processing or catering, as temperature regulations in the food industry tend to be very strict, and very small fluctuations of temperature can make a huge difference.

Thermocouple probes can be adapted to cater for a wide variety of specific usages. Penetration, or needle probes are perfect for identifying the core temperature of semi-solid products, such as a pack of meat. Air probes register the temperature of still or moving air around the probe. General purpose, or immersion probes can be immersed in liquid, or held under a flowing tap, which is very useful for testing the temperature of a tank of liquid, and surface probes are used primarily to measure the surface temperature of items such as pipes or radiators.

These days, most industries have requirements for measuring or monitoring temperature, from food manufacture to legionella prevention, building, transport and even space travel, as well as medical thermometers. We've come a long way since Philo of Byzantium noticed bubbles appearing in a jug left in the sun!

History of Thermometery, Part 3: Explosive Development

The history of temperature stretches back for thousands of years. Temperature has always been an important and essential part of daily life and society, ever since bakers and blacksmiths relied on temperature to control chemical reactions.

Nowadays, temperature is better understood than ever, and a wide range of temperature-measuring equipment – thermoscopes, thermocouples and many types of thermometer – is necessary to measure and to help control it.

This blog series hopes to open your eyes about the history of temperature measurement, from the ancient through to the modern day. Enjoy!

The Allbutt clinical thermometer (photo sourced from http://www.ssplprints.com/)

The development of thermometers has exploded since the eighteenth century. In 1866, Sir Thomas Clifford Allbutt devised a clinical thermometer which produced a body temperature reading in five minutes rather than twenty. 

 Since then, development has followed development, with the invention of the ear thermometer in 1964 by medical researcher Dr. Theodor H. Benzinger, invention of the liquid crystal thermometer by inventor Bob Parker in the 1970s, and invention of the electronic digital thermometer by a group of inventors from Hunstville, Alabama in 1970.

Increasingly throughout the 20th century, thermometers became essential and highly accurate devices used to analyse and control chemical reactions in fields as diverse as astrophysics, restaurant catering, and industrial manufacture.

Since the introduction of the International Temperature Scale in 1990 (ITS-90), many different thermometer designs have been required to cover the whole range of temperatures. These range from ‘absolute zero’, where all energy (expressed as heat) has been removed from a substance or atmosphere, to very hot temperatures – thermometers have been developed that can even measure the temperature of the surface of the sun (5526 degrees Celsius)!

Nowadays, many different types of thermometer exist, including the alcohol thermometer, the mercury thermometer, the medical thermometer, the reversing thermometer, the maximum minimum thermometer, the thermistor, the thermocouple, the coulomb blockade thermometer, the Beckmann differential thermometer, the bi-metal mechanical thermometer, the silicon bandgap temperature sensor, and the liquid crystal thermometer. 

However, the most common in general manufacturing purposes remains the electronic thermometer, which uses tiny microchips to pick up and to measure information on temperature. This is safer than mercury thermometers, as mercury is harmful to humans. Electronic thermometers are also much more precise, reliable and much quicker than traditional thermometers. 

For manufacturing purposes, when delicate processes are taking place which need to be controlled, it is important to be able to rely on an accurate thermometer. Equally, in food manufacture and catering, harmful bacteria can thrive and multiply on food that is kept at too high a temperature, or on food that is cooked at too low a temperature. 

Next in this series of posts, learn about the most widely used modern thermometer; the thermocouple.

History of Thermometery, Part 2: Establishing a Scale

The history of temperature stretches back for thousands of years. Temperature has always been an important and essential part of daily life and society, ever since bakers and blacksmiths relied on temperature to control chemical reactions.

Nowadays, temperature is better understood than ever, and a wide range of temperature-measuring equipment – thermoscopes, thermocouples and many types of thermometer – is necessary to measure and to help control it.

This blog series hopes to open your eyes about the history of temperature measurement, from the ancient through to the modern day. Enjoy!

The Fludd Thermometer (Photo sourced from: http://www.kumc.edu/)

The invention of the first true thermometer is generally credited to Robert Fludd (1574 – 1637 A.D.), an English Paracelsian physician, astrologer, and mystic. Although the first detailed diagram of a thermoscope was created by Giuseppe Biancini (1566 – 1624 A.D.), an Italian Jesuit astronomer and mathematician, it was Robert Fludd who produced the first diagram of a true thermometer with both a temperature sensor and a scale.

The first person who developed the idea of the thermometer and actively used it was Santorio Santorio (1561 – 1636 A.D.), an Italian physiologist, physician and professor. He developed a clinical thermometer for use in his experiments at the University of Padua, and claimed to have produced it by adapting the design from Heron of Alexandria’s thermoscope. Santorio Santorio used his thermometer to produce an estimated heat of a patient’s heart by measuring the heat of his expired air.

All these early thermoscopes and thermometers had the same design flaw. They were all sensitive to air pressure as well as temperature, and therefore also functioned as barometers rather than as pure thermometers. The first thermometer which gave a clear reading of temperature, unaffected by any other factor, was invented by Ferndinando II de’Medici in 1654. 

Medici (1610 – 1670 A.D.), Grand Duke of Tuscany, created the first modern thermometer, and the blueprint for many successive thermometer manufacturers. This was a sealed tube partially filled with alcohol, with a bulb and a stem. Because the tube was sealed, air pressure no longer affected the movement of the alcohol up or down the stem, leaving temperature as the only thing which was measured.

However, there was still one big problem in the thermometer industry. Every thermometer manufacturer had his own scale and his own system for measuring temperature. The scales and measurements were not standardised or calibrated to one another.

An early attempt at encouraging the use of a universal scale was in October 1663. The Royal Society in London proposed the use of one of Robert Hooke’s many thermometer scales as standard in the industry (Hooke was an English natural philosopher, architect and inventor).

Still, the Royal Society had no real power to implement its recommendation, and a variety of thermometers and measures remained in use. Slowly a scale evolved: Christian Huygens in 1665 suggested the melting and boiling points of water as standard lower and upper limits, and in 1701 Isaac Newton proposed a scale of twelve degrees, with the extremes being melting ice and body temperature.

Eventually, it was market forces which decided which thermometer scale would become standard use. Ole Christiansen Romer (1644 – 1710 A.D.), the royal mathematician of Denmark and a noted astrologer, created a scale where the upper limit was body temperature (the temperature of a healthy adult male’s armpit), and the lower limit a mixture of salt and ice. This is known as a ‘frigorific’ mixture: two materials whose temperatures can vary, but which always produce the same temperature when mixed together.

However, it was when Daniel Gabriel Fahrenheit visited Romer in 1708, and started using his scale in 1724, that it really caught on. Fahrenheit (1686 – 1738 A.D.), a German physicist and engineer, was the first thermometer manufacturer to make his thermometers with mercury instead of alcohol. 

Mercury is a better substance to use because its movement corresponds more exactly to temperature change, and so a thermometer containing it can produce a more accurate reading than a thermometer using alcohol. So Fahrenheit’s thermometers became the most popular designs, and eventually the standard ones. Because those buying the thermometers had to use the scale with which they came equipped, his scale eventually became the standard one as well, and still bears his name today.

Fahrenheit wanted a scale which was divisible by twelve, and so he called his upper point (body temperature) 96 degrees. As body temperature varies, the upper limit of the Fahrenheit scale was later changed to the temperature of boiling water, which was said to be 212 degrees. Nowadays, the Fahrenheit scale is only used widely in the United States of America and a few other countries (for example, Belize). The scale most widely used in thermometers of all kinds is the Celsius scale.

The Celsius scale was developed by Anders Celsius (1701 – 1744 A.D.), a Swedish astronomer who devised a scale of 100 degrees, with zero as the boiling point of water and 100 as its freezing point. He set this scale out in his paper ‘Observations of two persistent degrees on a thermometer’ in 1742. As he died just two years later, his assistant Carolus Linnaeus was instrumental in developing and publicizing the scale, and in encouraging its use among thermometer manufacturers.

Linnaeus reversed the scale, making zero the freezing point of water and 100 its boiling point, and used it in his patented linnaeus-thermometers, which were thermometers for use in greenhouses.

The scale caught on, with the endorsement of such figures as Daniel Ekstrom, Sweden's leading instrument-maker at the time, and Pehr Elvius, the secretary of the Royal Swedish Academy of Sciences. Since about 1950, the ‘centigrade’ scale (officially named the Celsius scale in 1948) has been the most widely used thermometer scale worldwide, and is used in thermometers of all kinds and in all industries, with the exception of some scientific fields (e.g. astrophysics or low-temperature research) where the specialised Kelvin scale is used instead.

Next in this series of posts, learn about the explosion of thermometer development that occurred in the 20th century.

New Developments: MM7005 USB Barcode Scanning Thermometer

Here at TME, we're always squirrelling away to develop new time, money and problem-solving temperature technology. In this series of posts, we'll keep an up-to-date log of all of our latest developments and newest products. 

The MM7005 USB Barcode Thermometer

Would you like all the benefits of a paperless temperature monitoring system, but are unable to wirelessly download data? TME is proud to announce its' newest development: an alternative to their best-selling MM7000 Bluetooth Barcode Thermometer: the MM7005 USB Barcode Thermometer.

Why USB?

Whilst Bluetooth downloading is a perfect solution for a lot of users, as Bluetooth is quick, easy to use, and most modern devices are Bluetooth-enabled, some users prefer a wired connection. This is where USB comes in. With USB, there’s no need to worry about connectivity or discoverability. Simply plug a USB cable into the MM7005 and download your data to computer, PDA, tablet or smartphone.

Who uses USB?

• Public environments, such as exhibition halls that have a lot of background wireless traffic going on, resulting in slower Bluetooth signals
• Organisations that hold sensitive information, and may have security worries about sending information wirelessly
• Medical environments, such as hospitals and nursing homes, where wireless signals can interfere with medical equipment
• Any organisation that prefers to download data using a wired connection

How does it compare?

The new MM7005 is very similar to the MM7000, in that it harnesses barcode technology to deliver sophisticated paperless temperature data recording across a range of industries and applications – from food manufacturing and food service to industrial processing, water temperature monitoring and logistics. Both models boast an integrated barcode scanner which logs not only the temperature, time and date of each scan, but also, for complete due diligence, the unique identity and location of the test point.

The MM7000’s recently-introduced alarm function is also present in the MM7005. This function allows users to set their own critical alarm values for every temperature test point, which, when breached, instantly display a Low or High visual alarm so that remedial action can be quickly taken.

For more details on this and other innovative temperature measurement solutions, visit www.tmethermometers.com for online purchasing or contact the Sales Team on 01903 700651 or sales@tmethermometers.com

History of Thermometery, Part 1: The Ancients

The history of temperature stretches back for thousands of years. Temperature has always been an important and essential part of daily life and society, ever since bakers and blacksmiths relied on temperature to control chemical reactions.

Nowadays, temperature is better understood than ever, and a wide range of temperature-measuring equipment – thermoscopes, thermocouples and many types of thermometer – is necessary to measure and to help control it.

This blog series hopes to open your eyes about the history of temperature measurement, from the ancient through to the modern day. Enjoy!

The ancient Philo Thermometer (Photo sourced from http://collectionsonline.nmsi.ac.uk)

The first known writers on temperature and its measurement were Philo of Byzantium and Heron of Alexandria. Both of these men wrote in Ancient Greek, and the word ‘thermometer’ comes from the Ancient Greek words ‘thermo,’ meaning ‘heat’, and ‘meter,’ meaning ‘to measure’; therefore the word ‘thermometer’ literally means ‘to measure heat.’

Philo (ca. 200BC) was a Greek engineer who conducted an early experiment on the expansion of air with heat. He created a device which has been called the first thermometer, now known as the Philo thermometer. A tube connected to a hollow sphere was extended over a jug of water. Philo noticed that if the sphere was in the sun, bubbles were released in the jug as air expanded out of the sphere, whereas when the device was placed in the shade, the air contracted with the cooler temperature and the water rose up the tube again.

Philo was a big influence on Heron of Alexandria (10 – 70 A.D.), an Ancient Greek mathematician and engineer, who wrote about temperature and drew up plans for a basic thermometer for use in medicine.

However, neither of these writers worked on or developed their designs for thermometers. The invention and creation of the first working thermometer has been credited variously to Abu Ali Ibn Sina (known as Avicennna in the Western world), Cornelius Drebbel, Robert Fludd, Galileo Galilei, and Santorio Santorio.

Abu Ali Ibn Sina (980 – 1037 A.D.) was a Persian polymath, physician and Islamic philosopher, who created a simple thermometer to test the temperature of air.

Cornelius Drebbel (1572 – 1633 A.D.) was a Dutch engineer and inventor of the submarine. Interestingly, Drebbel discovered carmine dye when one of his thermometers, which used coloured liquid, broke on a windowsill and he noticed that the dye grew more intense in colour when exposed to the sun.

Galileo Galilei (1564 – 1642), the famous Tuscan physician, mathematician and astronomer, came up with a device for registering temperature change at the height of the Scientific Revolution. He also noticed the principle behind the device known today as ‘Galileo’s thermometer’ - that is, that glass spheres filled with aqueous alcohol of slightly different densities would rise and fall.

However, none of these early designs were true thermometers. They were in fact thermoscopes rather than thermometers, as the absence of a scale meant that they only registered changes in temperature rather than measuring it. A true thermometer must include a temperature sensor - where physical change occurs with changes in temperature - and a means of converting that physical change into a readable value.

The next blog post in this series will expand on the invention of the first true thermometer, and how universal temperature scales came into being.