Hi Boiler and Pressure Vessel Code.

Hi Boiler and Pressure Vessel Code.

What is Boiler and Pressure Vessel Code, Section IV? 

What kinds of boilers are affected? 

How do I know if my heater's manufacturer is qualified?

What are the new requirements for these heaters? Do I need to swap out my existing heater to keep my boiler in compliance?

Download the FAQs of Boiler and Pressure Vessel Code sponsored by Watlow to get the answers to these questions and more.

Hi Nuclear fusion, JET and ITER: Your questions answered:

Hi Nuclear fusion, JET and ITER: Your questions answered:

Two European projects are hoping to pave the way for commercially viable power generation using nuclear fusion – a breakthrough that could make a massive contribution to our energy and climate change worries. We put your questions to the scientists and engineers working on these ambitious and fascinating schemes.

Thank you to all readers of The Engineer who sent in questions for the teams at ITER – the project to demonstrate the feasibility of magnetic-confinement nuclear fusion that is currently under construction in Cadarache, France – and its predecessor and pilot project, the Joint European Torus (JET) at Culham in Oxfordshire.

In 1997, JET set the world record for producing the largest amount of power (16MW) from fusion using deuterium-tritium (D-T), the fuel proposed for the first generation of fusion power plants. After a period of upgrades, the project is preparing an attempt at breaking that record.

The follow-up programme, ITER (International Thermonuclear Experimental Reactor), will attempt to go a step further and generate more power than is used to start the process.

Experts from both projects have provided the answers to your questions you’ll see here. The Engineer will continue to report on this fascinating project, as well as the parallel efforts in intertial-confinement or laser fusion currently taking place in the US.

Inside the JET tokamak, (inset) during a plasma run.

What are the safety and environmental hazards of fusion (including waste), what protection systems do you have in place to deal with this and how does this compare to nuclearfission plants?

The fuels used in the fusion reaction are inherently less hazardous that those used in fission. Typical input fuels for fusion will be deuterium and tritium – both isotopes of hydrogen with the latter being radioactive. The products of the reaction will be helium and fast neutrons. The neutrons can cause activation of materials they pass through. As a radioactive gas, tritium is a very low energy beta emitter and has a half-life of about 12.6 years. However, it is highly mobile and can contaminate most materials it comes in contact with. All fusion machines vary but JET, located at Culham in Oxfordshire, and ITER, being constructed at Cadarache in France, will both have their inner, plasma-facing walls constructed mostly of beryllium – a toxic metal, which presents significant health hazards if minute particles are inhaled.

In practice this means the major hazards associated with operating JET or ITER are beryllium contamination, radiation from fast neutrons, tritium and the activation products in components removed from the machine. There is no possibility of the reaction going critical – a major failure of the tokamak and loss of vacuum will merely lead to the loss of the plasma and thus the reaction extinguishing. During a reaction the level of neutron flux is such that all personnel are excluded from within the biological shield (thick concrete containment) whilst the machine is operating. All operation and maintenance of the machine is overseen by health physics staff who monitor levels of tritium and beryllium, declaring radiological and/or beryllium contaminated controlled or supervised areas as necessary.

With regard to waste, the first thing to say is that the production of waste is relatively modest, with most coming from maintenance activities or redundant components when the current research machines are re-configured. The main concern with the waste is radioactive contamination both from tritium and activation products, which will be relatively short-lived. Whilst much of the waste will be below the thresholds to even be considered as radioactive waste, there is some low level waste and a very small proportion will be classified as intermediate level waste. However, within 100 years or so, all of this material can be recycled or disposed of conventionally, leaving no long-term radioactive legacy for future generations to deal with.

Colin Shimell, Head of Assurance at Culham Centre for Fusion Energy;

ITER will not generate any long-lived nuclear waste. Irradiated material will be transferred within a confinement cask to enclosed, shielded compartments (“hot cells”). Inside the hot cells several operations will be performed, such as cleaning and dust collection, detritiation, refurbishment, and disposal. The waste, which is classified as medium level, will be stored in the ITER hot cells. All of these procedures are a part of the ITER operation as presented in the Preliminary Safety Report, and consequently are also submitted to examination of the French Nuclear Safety Authority as part of the licensing process.

Detritiation systems in ITER have been designed to remove tritium from liquids and gases for reinjection into the fuel cycle. Remaining effluents will be well below authorized limits: gaseous and liquid tritium releases to the environment from ITER are predicted to be below 10 µSv per year. This is well under ITER’s General Safety Objective of 100 µSv per year and 100 times lower than the regulatory limit in France of 1,000 µSv per year. Scientists estimate our exposure to natural background radiation to be approximately 2,000 µSv per year.

ITER response

The poloidal coils wrap around the tokamak providing one component of the magnetic field that contains the hot fusion plasma.

Why is it taking such a long time to return to experimenting with deuterium and tritium (D-T) fuel and how are you overcoming the problems you’ve experienced?

The vast majority of JET experiments are done using deuterium only – which allows us to study most of the physics we need. JET has run experiments with deuterium and tritium (D-T) in 1991, 1997 and 2003, and it is proposed to perform further D-T experiments in the coming years. The overall use of tritium at JET is limited, as D-T fusion neutrons cause radioactivity in the JET vessel and the cumulative radioactivity of the JET vessel is limited due to decommissioning requirements. One of the problems encountered in the D-T experiments in 1997 was the in-vessel retention of tritium in carbon-based deposits. JET has addressed this issue with the installation of all metal plasma-facing components, avoiding the use of carbon.

Duarte Borba, Senior Scientific Advisor, EFDA-JET.

It was reported recently that there were problems with winding the superconducting magnet coils you plan to use for ITER. Has this issue been solved? What progress is being

madeon the magnet manufacture?

Significant progress has been made in the manufacturing of ITER magnets. More than 350 tons of toroidal field conductor (Nb₃Sn strand), which corresponds to 75% of the total amount needed, have been produced by the 6 Members involved. This is the biggest production ever in the world. Also, 65 tons of poloidal field conductor (25% of supply) have been produced by China, Europe and Russian Federation. It is true that we have some delays in the manufacturing of the poloidal field coils due to complications in placing the contract rather than due to any technical issue) and it took also some time to develop high performance conductors for the central solenoid (the big central magnet (transformer) of the ITER tokamak). But work is progressing well. There is also good progress on toroidal field coil winding in Europe. ITER Members are still discussing possible testing at low temperature the toroidal field coils prior their assembly in the tokamak. These discussions are normal and are not seen as a major issue. All Parties remain committed to delivering on all fronts and in line within the ITER schedule.

ITER response;

A prototype of the poloidal coils that will wrap around the tokomak. Once wound with superconducting wire, the coil will be impregnated with epoxy resin to stabilise its structure.

Could fusion energy be used in a different way to driving steam turbines for electricity production, either for commercial power generation or more niche applications suchasspacecraft propulsion?

Many people over the years have suggested using fusion for spacecraft propulsion. The ideas range from various types of direct thruster using the very high energy plasma ions emerging from the reactor vessel like a rocket jet (which would suffer from the generally small burn-up fraction of the nuclear fuel), through to variants where a reactor broadly similar to those we have in mind for electricity generation is used to do that in space, driving conventional electrically accelerated xenon (etc) plasma thrusters.

Marine propulsion units, akin to today’s nuclear submarine reactors, have also been looked into. The presently valid scaling laws for fusion power gain lead to machine designs with large mass that are not suitable for mobile applications, but perhaps in the future more favourable empirical scalings will have emerged and such applications can be realised. Other applications include: the combined generation of electricity and hydrogen from a single fusion power plant, as part of a hydrogen economy; and the use of fusion energy to create heat to grow biomass plants, or at much higher temperatures to be used as process heat in industrial chemical plant.

Elizabeth Surrey, Head of Fusion Technology at Culham Centre for Fusion Energy

Fusion could be used as a source of neutrons. With ITER, we will have proved that we can harness a plasma and produce a steady stream of highly energetic neutrons. So an interesting question is: Can we find a better use for these neutrons? In a pure fusion reactor, the 14 MeV neutrons are slowed down in the blanket to produce heat, but they are not used to their full potential. Another solution could be to take advantage of their considerable energy to induce fission reactions in a blanket that would include some fission fuel, like natural Uranium (U 238) or Thorium. By doing this, the energy produced could be multiplied by a factor 10. This is what the ‘hybrid reactor’ is about.

ITER response;

How has JET advanced material science and what other possible applications could there be for the materials created for JET?

JET has had to develop materials technologies to meet its goals. A good example of the types of challenges and solutions is given by the ‘ITER-like Wall’ project which involved replacement of the carbon fibre reinforced carbon lining of the JET machine with ITER-relevant beryllium and tungsten. Vacuum casting of the high-strength alloy Inconel 625 was used to manufacture the carriers which supported the bulk beryllium tiles. Prior to this, the orthodox view was that cast components would not be viable in an ultra high vacuum due to gas trapped in leaky voids but vacuum casting followed by HIPing (annealing under high pressure) produced fully acceptable components. The JET requirements for beryllium machining also pushed the technology to the point that R&D was required on the limits of wire erosion and methods to remove zinc and copper deposited in narrow features during the machining process. To create a full tungsten surface in the divertor (the high heat load area in the bottom of the machine), a new process had to be developed for coating two dimensional carbon fibre material with thin layers of tungsten, which was challenging due to the anisotropic expansion of the material which compresses the coating in one direction and stretches in another during high-temperature cycling.

These materials-related developments have proved very successful in JET. It is hard to say how these developments may be used in other areas, but we know that by asking manufacturing companies to go outside their normal comfort zone and supporting them through the process, we do help enhance their capabilities and give them the confidence to bid for more challenging work in the future. 

Guy Matthews, Leader of EFDA-JET’s ‘ITER-like Wall’ project;

Cutaway view of the ITER cryostat, showing the tokamak surrounded by its field coils, kept cold to activate their superconducting properties.

What is the biggest obstacle to making fusion technology commercially viable and what steps will we need to take after ITER to get there?

There are many challenges to creating a commercially viable fusion power plant, which is a complex integration of many systems ranging from plasma physics, through manufacturing to economics, that are intricately connected such that no single entity can be identified as the “major obstacle.”

One of the most interesting challenges is developing materials and manufacturing processes that can withstand the hostile environment of a fusion reactor where a high level of fast neutron irradiation causes damage at the atomic structure level and creates impurities by nuclear transmutation. This affects the bulk properties of the materials so that structural design is complicated due to variation of the material property throughout the body. When coupled with high heat flux and surface erosion rates, these effects preclude the use of most common structural materials; some special alloys have already been developed for fusion applications but more work is needed.

Elizabeth Surrey, Head of Fusion Technology, Culham Centre for Fusion Energy;

To make fusion energy commercially viable, future fusion reactors will need to produce a positive balance of energy, to harness plasmas for several hours, avoid too expensive materials and, last but not least, find materials that are capable to withstand the enormous heat loads and neutron fluxes that are expected in a fusion power plant (some factors higher than in ITER).The objective of the ITER project is to gain the knowledge necessary for the design of the next-stage device: a demonstration fusion power plant. In ITER, scientists will study plasmas under conditions similar to those expected in a future power plant. ITER will be the first fusion experiment to produce net power; it will also test key technologies, including heating, control, diagnostics, and remote maintenance.

But ITER is not an end in itself: it is the bridge toward a first plant that will demonstrate the large-scale production of electrical power and tritium fuel self-sufficiency. This is the next step after ITER: the Demonstration Power Plant, or DEMO for short. A conceptual design for such a machine could be complete before 2020. If all goes well, DEMO will lead fusion into its industrial era, beginning operations in the early 2030s, and putting fusion power into the grid as early as 2040. Actually, there is not one DEMO concept being discussed, but there are several concepts developed by various countries. We can mention here the recent IAEA workshop in Los Angeles.

ITER response;

What is your best estimate of when fusion power will be able to supply electricity to the grid?

The most recent European roadmap for the realisation of fusion energy foresees a demonstration fusion power plant to put electricity on the grid in the early 2040s. JET has demonstrated fusion power – however, the challenge of making electricity continuously and at a competitive price is considerable. Much of this challenge involves the development of suitable materials that remain robust and strong in the challenging environment of a future fusion power station. 

Duarte Borba, Senior Scientific Advisor, EFDA-JET;

The build sequence for the ITER tokamak;

Are there likely to be any problems in obtaining enough fuel to run an industry’s worth of power plants and, if so, how will we tackle this issue?

The fuels that will be used in fusion power plants are deuterium and tritium. Deuterium is extracted from seawater and supplies are therefore virtually limitless. Tritium is more of a problem as its natural abundance is low and it must be produced from lithium in nuclear reactors. A fusion reactor generating 1GW(e) at 40% thermal efficiency will burn about 0.5kg of tritium per day and the burn-up fraction of the tritium is approximately 3%, so 15kg of tritium must be circulated to generate that 1GW(e). Given that the current world civil tritium stock is around 30 kg, it is essential for the fusion reactor to have an efficient tritium breeding system. This is planned in the form of lithium-containing blankets surrounding the tokamak in a fusion power plant.

Present technology being developed uses the reaction between the neutrons produced in the fusion process and lithium held within a ceramic-beryllium matrix or as a LiPb eutectic liquid. The beryllium and lead act as neutron multipliers as the blanket must produce more than one tritium atom per incident fusion neutron (the tritium breeding ratio, TBR) to be viable. Simulations to date imply TBRs around 1.2 might be achievable but, as yet, there is no source of 14MeV neutrons of sufficient intensity to test these designs. Tritium can also be trapped inside the fusion plant by the action of the plasma driving the ions into the wall and diffusion effects. This increases the required TBR; in the case of carbon walls TBR~1.3 is needed, which is the reason for abandoning this material in future tokamaks. Clearly efficient recovery and recirculation of the tritium, in addition to effective TBR, is necessary to the fusion economy.

Elizabeth Surrey, Head of Fusion Technology, Culham Centre for Fusion Energy;

On paper, there is enough fuel to run fusion plants worldwide. However if the aim is to use a mix of deuterium and tritium, you have to sort out the issue of tritium supply. Tritium virtually does not exist in nature (it has a half-life of 12.5 years). So the success relies on breeding the tritium inside the reactor. One of the missions for the later stages of ITER operation is to demonstrate the feasibility of one or more concepts of tritium production through the so-called “Test Blanket Module” (TBM) program. The TBM program will build on tritium breeding studies that have been carried out for a number of years, in particular by the European Union which has substantial expertise in this field. The accumulated knowledge permits a high level of confidence that results from ITER will contribute to full tritium self-sufficiency in next-generation devices. 

ITER response;

A prototype of the support plate for one of the toroidal field coil windings, at Camerana in Italy.

In your opinion, is support for fusion among politicians growing or declining?

Political support has increased, especially in China and South Korea, where the desire to see commercial fusion is highest. Support in Europe remains robust, which is crucial as Europe contributes to almost half of the ITER costs. In the UK, there is good support from the Chief Scientist to the UK Government, Sir John Beddington, and the Science Minister David Willetts.

Duarte Borba, Senior Scientific Advisor, EFDA-JET;

I would say it is stable. This is actually a very good result, given the current difficulties (economic crisis etc). However, there are big differences from one country to another. Germany, for example, which is opposed to nuclear fission, is becoming very critical about fusion.

ITER response;

The foundation piles for the ITER tokamak are in place at Cadarache; the people show the scale;

Several readers have questioned the value of committing such large amounts of money to a project that has already taken many years and isn’t likely to produce a commercialsolution to our energy needs for decades to come (if at all). What would you say to them to persuade them that fusion is a worthwhile investment, particularly over other already-proven alternative energy technologies such as renewables?

Energy is such a fundamental aspect to our lives and a key component in the world’s economy, that spending on research into all forms of alternative energy production should be much higher than it presently is. Current spending on fusion, and other alternative systems, is virtually negligible when you consider the size of the energy market globally and the scale of the problem that will face future generations if we don’t make an investment now.

The intermittent availability of renewable energies, such as solar and wind, limits their use for large-scale electricity production in the absence of viable energy storage solutions. Therefore, more research is required to further develop wind and solar technologies, together with the development of Generation IV fission stations, carbon capture and storage and fusion.

With energy demand growing at an alarming rate, fusion energy has the potential to provide a long-term environmentally responsible solution for baseload electricity production. Today at JET, it is a fairly routine operation to heat plasmas to 200 million degrees, initiate and maintain a fusion reaction in a controlled and predictable way, and understand and improve plasma performance. ITER is designed to achieve an energy gain of at least ten, and should demonstrate that a fusion power plant is feasible. This means that fusion could be providing an invaluable extra energy option from the middle of this century.

In David MacKay’s book “Sustainable energy without the hot air” he says about nuclear fusion that:  “…there’s enough deuterium to supply every person in a ten-fold increased world population with a power of 30 000 kWh per day (that’s more than 100 times the average American consumption) for 1 million years”. It is this potential that justifies the fusion programme.

Duarte Borba, Senior Scientific Advisor, EFDA-JET;

It is very simple: we cannot afford not doing ITER and not trying to show that fusion could become a new energy source on Earth.If ITER succeeds, it will open the doors not only to a new source of energy on Earth but also to peace worldwide as the very large inventory of hydrogen (the fusion fuel) on Earth is expected to diminish geopolitical tensions. With regards to the money, the cost of ITER construction is estimated at 13 billion euros. This has to be divided by 34 countries and 10 years. It is therefore a small amount in the Member’s budget.

Hi Search the site Advanced Search From summer schools to solar chimneys.

Hi Search the site Advanced Search From summer schools to solar chimneys.

Mechanical engineer Patrick Cottam is at the heart of efforts to develop a bizarre new form of solar energy technology, all thanks, he says, to a work experience stint with ballooning pioneer Per Lindstrand:

Patrick Cottam.

Growing up I was always interested in novel technical challenges. Perhaps unsurprisingly, I jumped at every chance to attend engineering Summer schools and school trips. One of those was the Schools Aerospace Challenge where a team from my school was shortlisted for our design of a long endurance airship, giving us the opportunity to fly a plane and a helicopter. This is also how I first met Per Lindstrand, the inventor and explorer, who ran a company that specialised in creating brand new solutions for specific applications - exactly what I’d always been interested in.

Later on, when completing my undergraduate degree at Warwick, I remembered Per Lindstrand and Lindstrand Technologies. I needed to work during my holidays to earn money, and so decided to apply for work experience there. Per gave me responsibility for my own project designing and building a machine for testing the rate of helium permeation through fabrics. It fitted me perfectly – no such machine was commercially available, it was entirely novel. After one successful summer, I returned for Christmas and the following year.

The solar updraft chimney uses rising air heated by the desert sun to drive turbines that generate electricity.

Clearly used to having me around, my boss there one day left the details of a doctoral programme at UCL next to me saying only, “This sounds interesting…”. Needless to say it was enough to pique my interest. Per Lindstrand had actually conceived the programme, which was to design a fabric thermal chimney. I applied and was accepted, in large part because I had already had experience working in the field and with the company.

Working on the fabric solar thermal chimney project:

Per Lindstrand knew a physicist who worked on the new Atacama Large Millimeter/submillimeter Array (ALMA) at the European Southern Observatory (ESO), in the Atacama Desert, Chile. The system, under construction at the time, was to consume a huge amount of power. The ESO is currently powered by diesel generators but transport of diesel fuel and reduced efficiency at high altitude contribute to enormously high CO₂ emissions and energy costs.

The concept was inspired by the energy needs of the ALMA observatory, in the Atacama desert, Chile.

Solar thermal chimney power plants offered the potential to reduce cost and environmental damage. To operate a solar thermal chimney you first cover large areas with transparent material (plastic film or glass) to create a solar collector which heats up the air underneath via the greenhouse effect. The air becomes buoyant as its temperature increases and its density decreases. Hot air rises under buoyancy (think of a hot air balloon – Lindstrand Technologies’ original products).

A tall chimney is placed at the centre of the collector and the buoyant air flows through the collector and up the chimney. A set of air turbines is located at the base of the chimney to extract power from the airflow. If you can build one on a large scale, with the chimney 500-1000m tall, you can get around 150 MW out of it - which is enough to power more than 50,000 homes in the UK.

Furthermore, the power source needn’t be the sun; the thermal chimney concept could be used to extract power from low-temperature industrial waste heat or any other low-temperature heat source.

However, tall chimneys are very difficult and expensive to build. This is where Per Lindstrand had the idea of a fabric chimney. Because it would be very light, transport requirements would be minimal and it could also be deployed in months rather than years. However, manufacturing a chimney from fabric and holding it aloft with envelopes of lighter-than-air gas is quite a challenge and technologically beyond the remit of one student working on a four year programme. My project is therefore a feasibility study taking the first step towards that goal.

I started with in-depth studies of thermodynamics and then moved on to applying this to a solar thermal chimney. Currently, I’m starting to look more at inflatable chimneys and have built a small-scale prototype to get data on stiffness and to provide a benchmark for future designs.

The EngD programme is designed with company involvement in mind. It keeps me in touch with the commercial world and with industry, whilst Lindstrand gets access to research as it progresses and has a say in where it goes.

An inflatable solar updraft tower would not be susceptible to earthquake damage

I was happy to be able to take advantage of another important opportunity in the form of the Industrial Fellowship programme run by the Royal Commission for the Exhibition of 1851. A friend prompted me to apply after learning that the Commission provides funding for projects investigating novel technological ideas with the potential to contribute to British industry. The Fellowship provides a total of £80,000 of funding over three years to students from any British university pursuing a PhD or EngD with industrial involvement. This financial backing has enabled me to do more than I would have been otherwise able to. In fact, I wouldn’t have been able to build the first prototype without it!

Beyond financial backing, my Industrial Fellowship has also connected me with new, invaluable contacts, and access to lots of useful events. One event at the Royal Society, about agricultural technology, opened up a whole new world of potential applications for the chimney that I hadn’t even thought about: using the equipment to aid solar drying (of wheat, tomatoes, minerals).

If I were to do it all again…

I’ve been lucky to have found a niche that excited me and that I’m suited to, but there are ways you can create your own luck. The most valuable thing for me was the work experience I gained during holidays. These months working exposed me to industry whilst I was still at university and gave me an insight into the potential work out there.

Summer work isn’t always easy to come by and I applied to 30 or 40 engineering internships before securing one. I’d also recommend that everyone take a look at the smaller companies- they can often be the ones offering something a little more interesting and innovative. Because they’re smaller you have the potential to make more of an impact, be more involved and see more of the company.

Finally, always look at what funding opportunities might be out there. Getting financial support for the valuable work you are doing can allow you to pursue things in much more detail and continue your academic education at the same time as helping industry - which can ultimately be to the benefit of you personally, the company you are working with and the economy in general.

Hi Application note: designs for voltage-to-frequency converters.

Hi Application note: designs for voltage-to-frequency converters.

‘Designs for high-performance voltage-to-frequency converters’

A variety of high-performance V/F circuits is presented in this application note from Linear Technology. Included are a 1Hz to 100MHz design, a quartz-stabilised type and a 0.0007 per cent linear unit. 

Other circuits feature 1.5V operation, sine wave output and non-linear transfer functions. A separate section examines the trade-offs and advantages of various approaches to V/F conversion.

Hi Technical article: what makes stainless steel 'stain-less'?

Hi Technical article: what makes stainless steel 'stain-less'?

‘What makes stainless “stain-less”?’

A common misconception about stainless steel is that it is not affected by corrosion. While misleading, the success of the metal makes this common belief understandable. One of New York City’s most impressive landmarks is the stainless-steel-clad peak of the Chrysler Building. Built in 1930 of 302 Stainless, a recent inspection revealed no signs of corrosion or loss of thickness. The tallest manmade monument in the US, the St Louis Arch, is entirely clad in 304 stainless steel plates. Except for cleaning, the stainless exterior of this monument has required no corrosion maintenance. As this article from Envirotech explains, while the name correctly signifies the rust-resistant properties of the metal, ‘stain-less’ is not 100 per cent ‘stain-proof’ in certain applications.

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Hi OSHA TOP 10 Violations FY 2013.

Hi OSHA TOP 10 Violations FY 2013.

OSHA recently posted  its top 10 most frequently cited 

violations for FY2013.While 2 of the top 3 are 

Construction, the balance are General Industry and 

General Requirements applicable to our shops.

1. Fall protection, construction (29 CFR 1926.501) [related OSHA Safety and Health Topics page]
2. Hazard communication standard, general industry (29 CFR 1910.1200) [related OSHA Safety and Health Topics page]
3. Scaffolding, general requirements, construction (29 CFR 1926.451) [related OSHA Safety and Health Topics page]
4. Respiratory protection, general industry (29 CFR 1910.134) [related OSHA Safety and Health Topics page]
5. Electrical, wiring methods, components and equipment, general industry (29 CFR 1910.305) [related OSHA Safety and Health Topics page]
6. Powered industrial trucks, general industry (29 CFR 1910.178) [related OSHA Safety and Health Topics page]
7. Ladders, construction (29 CFR 1926.1053) [related OSHA Safety and Health Topics page]
8. Control of hazardous energy (lockout/tagout), general industry (29 CFR 1910.147) [related OSHA Safety and Health Topics page]
9. Electrical systems design, general requirements, general industry (29 CFR 1910.303) [related OSHA Safety and Health Topics page]
10. Machinery and Machine Guarding, general requirements (29 CFR 1910.212) [related OSHA Safety and Health Topics page]

Savvy managers will make sure that their safety training plans cover the General Industry and General Requirements topics listed above.

And frankly, I’d add GRINDERS to my personal walk around inspection list. 

Hi Pipe Steel: Internal Defect!.

Hi Pipe Steel: Internal Defect!.

Definition: A central cavity formed by contraction of the metal during solidification is called pipe.

- "When this cavity is found in wrought or cast products, this is also called pipe."

Pipe steel centerline defect in wrought steel bar. We had this specimen hard chrome plated and made it into a bookend.

In the days of ingot casting, the location of the shrinkage cavity was controlled by ingot mold design and the addition of hot tops to assure that after cropping the material containing the void off, there would remain sufficient sound material to roll into product.

Today with modern computer controlled billet and bloom casting processes, pipe steel and center porosity is very seldom encountered.

Recently a question was asked about centerline defects on cast billets in one of my LinkedIn Groups.

"hello can any one tell us why some times whe have holes along the center of the billets just casted thanks"

Despite a lack of specifics about grade, deoxidation, and many other factors, we can make some comments based on the fact that this is continuously cast billets according to question.

Here are comments addressing the continuous billet casting process and how it can be implicated in the creation of centerline voids (pipe steel defects).

The three key parameters in the casting process that are most likely to result in centerline pipe are:

1. Casting speed
2. Superheat
3. Electromagnetic Stirring. EMS amperage and frequency (Together they drive intensity.)

1. Casting Speed- Incorrect casting speed can result in pipe/ centerline looseness/ porosity. This can be aggravated by issues with mold level control. Slow down your casting speed to get sufficient solidification.

2. Superheat is critical to maintaining the proper fluidity and solidification dynamics in the mold. Liquid metal shrinks in three steps; 1) volume decreases the liquid cools goes from the pouring temperature to the freezing temperature; 2) volume decreases as the metal solidifies. This is reinforced by the driving out of dissolved gases as the metal freezes; 3) the metal shrinks as it cools from solidification temperature to ambient temperature.

3. Electromagnetic Stirring (EMS)- If you macroetch transverse sections of the billets and still see columnar rather than equiaxed grain structure in the cast billet, it is a sign that the EMS is ineffective.

There are a host of other operating parameters as well as chemistry and processes that can contribute to porous centers or central cavity pipe steel defects. Here is a list of questions to help address these:

Do you have adequate cooling water through the molds? Are you running EMS? What is the metallurgical distance on this caster? What is the mold level control? Evidence of turbulence into the mold? Meters per minute for casting speed? Shrouding status on nozzles? What was superheat? What was water flow?

Do you have chemistry in control, steel deoxidized, so that the large void is a result of solidification shrinkage, not divorce of gas from the liquid steel? What is grade? What was deoxidizer?

Continuous casting of steel is a complex process with a large number of operating parameters and processes that need to be in close control. 

Understanding how these parameters can impact the final product is critical to eliminating defects that result from lack of control.

Hi Technical Whitepapers Collection A: Vibration, Noise & Motion Control!.

Hi Technical Whitepapers Collection A:  Vibration, Noise & Motion Control!.

How Adaptive Systems unlock big productivity gains;

When manufacturers seek to increase throughput in an automation system, one issue they can quickly encounter is unwanted vibration. This useful and informative Technical Paper from Bosch Rexroth provides a detailed investigation into these challenges, and discusses how new Adaptive Systems motion control technology provides a solution: drive-based intelligence that intelligently applies vibration damping to sustain increased throughput and extend machine life.

Tuning intelligent servo drives to filter mechanical “white noise” resonance;

Controlling machine resonance—the “white noise” generated by machine motion—in servo-driven printing and converting machines is a crucial motion control challenge. Discover how Rexroth intelligent IndraDrive servo drives provide advanced programming tools, diagnostic features and integrated filtering capabilities to intelligently combat mechanical resonance, improving accuracy by as much as 50 percent.

Rexroth Flex Profile for event-driven control of machine motion;

Fully realize the potential for integrating event-driven and objective-driven strategies into motion control schemes, optimizing automation beyond what’s possible with traditional electronic cams or motion profiles. Until now, such strategies have tended to be limited by point-to-point motions and ad hoc methods. Bosch Rexroth’s Flex Profile technology provides a structure under which event-driven strategies may be fully realized.

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Hi Technical Whitepaper Downloads! Bearings & More...,

Hi Technical Whitepaper Downloads! Bearings & More...,

Demystifying Ball Spline Specs:

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Hi Designing Water Cooled Condenser Tube Bundles!.

Hi Designing Water Cooled Condenser Tube Bundles!.

In application a water cooled condenser must reject the heat removed from the chilled water circuit plus the compressor work at specified water flow and entering & leaving temperatures. Water-cooled condenser has water on the tube side & refrigerant on the shell side. The unit compressor capacity and power consumption are functions of the refrigerant saturation temperature, among other operating parameters.

For the tube bundle, determine the flow areas and heat transfer areas.

A_f=N_t*(π*D_i²/4)/N_p, tube side flow area, ft²

A_o=N_t*π*D_o*L, shell side heat transfer area, ft²

A_i=N_t*π*D_i*L, tube side heat transfer area, _ft2

A_ia= N_t*a_i*L, tube side heat transfer area for fouling, ft²

a_i=actual enhanced tube side area/ft, ft²/ft

B= A_o/ A_i

WhereB₂=A_o/ A_ia

N_t=number of tubes

N_p=number of tube passes

D_i=inside tube diameter, ft

D_o=outside tube diameter, ft

L=length of tube, ft

There are two equations that apply

Q=U_o*A_o*LMTD

and

Q=m_w*c_p*( Tw_o -Tw_i)

Where

Q=Capacity, BTU/ Hr

U_o=Overall Heat Transfer Coefficient, BTU/ (Hr-Ft²-^oF)

LMTD=Log Mean Temperature Difference, ^oF

LMTD=(Tw_o-Tw_i)/ln((T_s-Tw_i)/ (T_s-Tw_o))

m_w=Mass Flow of water, Lb/Hr

c_p=Specific heat of water, BTU/(Lb-^oF)

T_s=Refrigerant saturation temperature, ^oF

Tw_i=Entering Water Temperature, ^oF

Tw_o=Leaving Water Temperature, ^oF

The overall heat transfer coefficient is a function of the refrigerant side coefficient, the tube metal resistance, the water side coefficient and the fouling resistance.

U_o=1/((1/h_o')+(B/h_i)+(B₂*R_f))

Where

h_o'=refrigerant side heat transfer coefficient, BTU/(hr-ft²-^oF)

Note: The metal wall resistance is commonly included with the refrigerant side heat transfer coefficient. No fouling resistance allowance is needed on the refrigerant side.

h_i=water side heat transfer coefficient, BTU/(hr-ft²-^oF)

R_f=water side fouling resistance, (hr-ft²-^oF)/BTU

A common engineering problem is to determine the refrigerant saturation given the condenser heat rejection, the water flow rate and the entering water temperature. The solution for T_s is as follows:

Using the two equations that determine Q

U_o*A_o*LMTD=m_w*c_p*(Tw_o-Tw_i)

Substituting the equation for LMTD

U_o*A_o*( Tw_o-Tw_i)/ln((T_s-Tw_i)/ (T_s-Tw_o))=m_w*c_p*(Tw_o-Tw_i)

U_o*A_o/ln((T_s-Tw_i)/ (T_s-Tw_o))=m_w*c_p

ln((T_s-Tw_i)/ (T_s-Tw_o))= U_o*A_o/m_w*c_p

Define

C= U_o*A_o/m_w*c_p

Then

ln((T_s-Tw_i)/ (T_s-Tw_o))=C

(T_s-Tw_i)/ (T_s-Tw_o)=e^C

T_s-Tw_i =e^C* T_s - e^C * Tw_o

e^C * Tw_o- Tw_i= e^C* Ts-Ts

T_s=(e^C*Tw_o- Tw_i)/( e^C -1)

Designers can perform these calculations using spreadsheets or computer programs to determine the operating saturation temperature for a given tube bundle in a chiller application, or to size heat exchanger tube bundles to meet the required heat rejection, saturation temperatures and water temperatures.