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Gas is a crucial energy source for many people in Victoria. Even though Victoria produces more gas than it uses, gas is getting more expensive.  

Hence, the government introduced Victoria’s gas substitution roadmap to lower bills. This gas substitution roadmap encompasses many energy-related details. Today, we will try to cover everything you need to know.  

The roadmap was mainly introduced because more gas is being exported to other parts of the country, which creates more competition for the gas Victorians need. Recently, disruptions in international supply have also contributed to the price increase. 

In the last three years, many Victorians have increased their gas bills. The connection to international gas prices influences this rise in prices. Global events will keep pushing gas prices higher.

What is the Gas Substitution Roadmap?

The Roadmap outlined a pathway for Victoria to reduce its reliance on fossil gas while maintaining reliable supply and keeping downward pressure on prices.  

It relies on investment in energy efficiency and electrification to replace gas where electric alternatives are readily available, particularly in residential and 

The Roadmap is also a plan to reduce reliance on natural gas and transition to cleaner energy sources.  

The roadmap outlines strategies to increase energy efficiency, promote the use of electric appliances, and support the development of renewable energy alternatives. The goal is to cut greenhouse gas emissions, lower energy costs, and improve energy security for Victorians. 

The Gas Substitution Roadmap is helping our state achieve net zero emissions while cutting energy bills and ensuring reliability. 

The Roadmap outlines how we will use 

  • energy efficiency 
  • electrification 
  • renewable hydrogen 
  • biome thane 
  • to drive down bills and cut carbon emissions.  

The roadmap Outlines a Comprehensive Approach to Achieving this Goal, including:

Promoting Energy Efficiency:

It encourages households and businesses to use energy more efficiently to reduce overall gas consumption. 

Electrification of Australia:

This roadmap promotes the shift from gas-powered appliances and systems to electric alternatives, such as heat pumps and electric stoves, which can be powered by renewable energy.  

Boosting Renewable Energy:

It will increase the production and use of renewable energy sources, like wind and solar power, to replace natural gas in electricity generation.  

Developing Hydrogen:

The roadmap explores hydrogen as a clean alternative to natural gas, including investment in hydrogen production and infrastructure.  

Policy and Regulatory Support:

It implements policies and regulations facilitating the transition from gas to renewable energy, including incentives for adopting new technologies and standards to ensure a smooth transition. 

The Roadmap will help empower Victorian households and businesses to embrace sustainable alternatives to fossil gas and enhance access to an affordable, secure, reliable, and safe energy supply. 

The roadmap aims to reduce greenhouse gas emissions, enhance energy security, and create new economic opportunities within the state. By transitioning away from natural gas, Victoria intends to meet its environmental goals and support a sustainable energy future.  

Why do We Need to Phase Out from Fossil gas?

Victoria's Gas Substitution Roadmap

More than 2 million people in Victoria use gas in their homes and businesses, more than any other state or territory.  

The gas sector in Victoria is responsible for about 17% of the state’s greenhouse gas emissions, so it needs to help reduce these emissions over time.  

Although Victoria produces and exports a lot of gas, moving away from fossil gas is essential for the future of renewable energy. We must balance this with the need for reliable, safe, affordable energy. 

Switching to all-electric homes reduces the demand for gas and protects consumers from international gas price increases. I 

t also helps Victorians save money. New homeowners can save about $1,000 a year by going all-electric, and those with solar panels can save over $2,200 a year.  

Existing homes that switch from gas to electricity and have solar panels can save around $1,700 a year on energy bills, plus an additional $1,000 a year from using a 6.6 kW solar system.  

What are the fundamental changes of the Gas Substitution Roadmap, and how do they affect you?

Switching to electric for homes and businesses:

  • Starting January 1, 2024, new homes requiring a planning permit must be all-electric. 
  • Rental homes will have higher minimum energy efficiency standards. 
  • The VEU program will now include induction cooktops, working with suppliers to quickly bring these products into the program. 
  • A regulatory impact statement (RIS) will explore options to gradually electrify all new homes and commercial buildings with available electric alternatives. 
  • The same RIS will examine the costs and benefits of replacing old gas appliances with electric ones in homes and commercial buildings. 
  • From May 2024, new homes must meet a mandatory 7-star efficiency standard. 
  • All new government buildings, including schools and hospitals, will be all-electric. 

Supporting changes:

  • Development of the renewable gas sector in Victoria. 
  • Ensuring a balanced approach to maintaining enough fossil gas supplies. 
  • Building industry skills and capacity. 

These reforms mean that homes and businesses will move towards using electricity instead of gas, making energy use more efficient and reducing reliance on fossil fuels. This can lead to lower energy bills and a cleaner environment.  

What consultation has been done for the Gas Substitution Roadmap?

The Victorian Government is working with various groups in energy, manufacturing, business, building and construction, trades, local government, environmental organizations, and consumer groups to help the gas sector move towards net zero emissions.  

So far, they have received feedback in several ways: 

  • Three hundred submissions in response to the Victorian Gas Substitution Roadmap Consultation Paper. 
  • About 50 submissions in response to the Renewable Gas Consultation Paper released in October. 
  • Participation in industry forums. 
  • Individual meetings with stakeholders. 

Developments Affected by the Gas Connection Ban

gas bill

The ban on new gas connections applies to any new planning permit application submitted on or after January 1, 2024. This includes: 

  • Building a new house 
  • Developing new apartment buildings 
  • Creating new residential subdivisions  

Effects on new Dwelling:

  • A new building or part of a building meant to be used as a home, excluding caretaker’s houses, not including changes or extensions to existing homes. 
  • A new building or part of a building connected to an existing home is used as a separate home, not using the gross floor area of the existing house. 
  • A new outbuilding or swimming pool linked to an existing or proposed home, not within the gross floor area of an existing home. It doesn’t include new apartment buildings. 

New apartment development:

A new building or part of a building with one or more apartments, even if it includes other uses, but not extensions or changes to existing apartment buildings or adding new apartments to existing developments. 

Developments Not Affected by the Gas Connection Ban

The gas connection ban does not apply to:

  • Planning permit applications submitted before January 1, 2024. 
  • Amend permits if the original application was submitted before January 1, 2024. 

Types of Developments Exempted:

  • Building a new home, outbuilding (like a garage), or swimming pool that doesn’t need a planning permit. 
  • Extending or altering an existing home or apartment, including adding new apartments to an existing development. 
  • Converting an existing outbuilding (like a garage) into a new home. 
  • Building a second home on a lot, partially or entirely within the gross floor area of the existing house. 
  • Laying gas infrastructure through easements on lots with existing homes or for new homes. 

Heat Pump to Progress Your All Electrification Journey

renewable gas

Air-sourced heat pumps can help Victorians avoid using fossil fuel gas by providing an efficient and eco-friendly alternative for heating and cooling.  

Here’s how they work and their benefits: 

Energy Efficiency:

Air-sourced heat pumps are highly efficient. They use electricity to transfer heat from the air outside to inside a home. They can produce several units of heating or cooling for each unit of electricity consumed, making them more efficient than traditional gas heaters. 

Reduced Greenhouse Gas Emissions:

Since they rely on electricity, air-sourced heat pumps can significantly reduce greenhouse gas emissions, especially with renewable energy sources like solar power. This helps Victoria meet its environmental goals. 

Lower Operating Costs:

Although the initial installation cost of a heat pump might be higher than a gas heater, the operational costs are typically lower. Heat pumps use less energy, lowering homeowners’ energy bills. 

Versatility:

Heat pumps can provide heating and cooling, eliminating the need for separate systems. This makes them a versatile and cost-effective solution for year-round climate control. 

Improved Indoor Air Quality:

Heat pumps do not burn fossil fuels, so they don’t produce indoor air pollutants like carbon monoxide. This can improve the air quality inside homes.  

Incentives and Rebates:

The Victorian government offers incentives and rebates for installing energy-efficient appliances, including heat pumps. These programs can offset the initial costs and make the transition more affordable. 

Supporting the Grid:

As more homes adopt heat pumps, the demand for gas decreases. This reduces the strain on gas supplies and infrastructure, leading to more stable energy prices and supply. 

By adopting air-sourced heat pumps, Victorians can enjoy efficient, cost-effective heating and cooling while reducing their reliance on fossil fuel gas and contributing to a cleaner, greener environment. 

Contact Cyanergy to get the best heat pump in your area!  

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Victoria’s Gas Substitution Roadmap To Lower Bills

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Malloy Wind and NSK on Main Bearing Failures

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Weather Guard Lightning Tech

Malloy Wind and NSK on Main Bearing Failures

Cory Mittleider of Malloy Wind and Loren Walton of NSK on main bearing failures, why the industry is pulling DLC coatings, and the material changes replacing them.

Sign up now for Uptime Tech News, our weekly newsletter on all things wind technology. This episode is sponsored by Weather Guard Lightning Tech. Learn more about Weather Guard’s StrikeTape Wind Turbine LPS retrofit. Follow the show on YouTubeLinkedin and visit Weather Guard on the web. And subscribe to Rosemary’s “Engineering with Rosie” YouTube channel here. Have a question we can answer on the show? Email us!


Allen Hall: Cory and Loren, welcome back to the podcast.

Cory Mittleider: Thanks for having us.

Allen Hall: So we’ve got two bearing experts in one location, and this is the point where we start asking all of our bearing questions. Cory, you’re with Malloy Wind, and we’ve had you on the podcast two or three different times. Loren’s with NSK — we’ve had Loren on at least once before.

Loren Walton: Once, yes.

Allen Hall: Yeah, and that was good.

Loren Walton: I appreciate that. It was fun.

Allen Hall: There are a lot of bearing issues happening in the States at the moment, but also globally. Whatever happens in the States, you can pretty much find in Australia, Canada, Singapore, Mexico, South America, Brazil — everywhere. We’re hearing a lot about main bearings, and there’s a variety of things that I think you two know from being on the inside that we on the outside haven’t heard yet. I want to get some of those stories out and understand what’s going on, because operators are trying to keep their assets running, and bearings are a big issue. Let’s talk main bearings. What are you seeing in the field right now? What kinds of problems are happening?

Cory Mittleider: It seems like operators are coming to us and asking us to supply bearings that no longer have DLC. That’s a bit of a phenomenon lately. For a little over a decade we spent our time supplying bearings with DLC on the rollers to address problems found fifteen years ago.

Allen Hall: DLC is diamond-like coating.

Cory Mittleider: Correct.

Allen Hall: Which is a really hard specialty coating applied to the bearing surfaces to provide hardness and durability — or it’s supposed to provide durability.

Cory Mittleider: That’s a good point. It’s a coating that’s one to two microns thick — one to two thousandths of a millimeter — and a very hard material. The big feature was that it’s a dissimilar material to the steel. So when we break through the mixed and boundary lubrication regimes and those asperities touch each other, that dissimilar material prevents the welding and tearing that leads to the peeling damage we saw fifteen years ago. That peeling damage eventually turned into spalling, cracking, and other failures. So it made a lot of sense at the time to turn to something like this to mitigate the peeling.

Allen Hall: So the peeling damage was one of those issues where you basically had some sliding happening. In my electrical world, and from looking at these on the ground, you see things moving relative to one another instead of rolling relative to one another.

Loren Walton: It’s more of a welding and shearing of the contacts. I used a finger analogy last time: think of your asperities as fingers — one set is the roller, one set is the outer raceway. They weld under high load and high pressure, then they shear, leaving behind debris. That’s what creates the beginning of the peeling damage, and then it continues to create more debris, and the bearing starts to basically eat itself alive.

Allen Hall: The start of that process, though — is that a lack of lubrication, or a finish or hardness issue on the bearing?

Loren Walton: I love that question, because this is the crux of the whole thing, and I think it’s the part that gets missed. People immediately want to throw the whole thing out and start over with something different. Fundamentally, when we fixed the surface issue by adding the coating, the problems pretty much went away. We went from one-to-five years of life to ten-plus years, depending on the application — without changing the construction, the bearing type, or the contact angle. Just by adding the coating, we increased life significantly. The root of what you’re asking is that the bearing would operate better if it had the proper amount of separation. It’s not a fatigue issue and it’s not a loading issue. At its heart, the bearing isn’t able to create that separation. There isn’t enough speed, and there isn’t enough of a gap created by the lubricant.

Allen Hall: So ideally you have this almost molecular-scale film of lubricant between the two surfaces. If it isn’t designed properly, or you have an issue, that lubricant gets squeezed out of the space, and at that point you have trouble. That’s some of what I’m hearing on main bearings — especially when turbines have been curtailed and aren’t turning. Is that partly just the fact that there’s so much load?

Cory Mittleider: I think that’s a fundamental difficulty of the main shaft bearing. You’ve got extremely variable loads, from full load to idle, and a wide range of operating conditions — from northern North Dakota in the winter to Texas in the heat this week. High load, heavy load, incredibly slow speed, and even slower if it’s idling. It’s hard to reliably build that film. It’s not necessarily that there isn’t enough lubrication; it’s that the film isn’t building properly where it needs to be to separate the metal and the rolling elements.

Allen Hall: So the diamond-like coating was meant to solve that welding problem — you put the coated bearing in, and it worked okay until more recently, when all of a sudden we started having other issues. To me those aren’t related to the coating itself, but to other things happening up in the nacelle.

Loren Walton: If we recall some of your previous episodes, you were on the forefront of understanding and talking about DLC starting to become an accelerant to failure. I know you talked about it with Cory. Those episodes have aged very well. A lot of people now are recognizing what we were saying years ago and changing their strategy toward removing DLC — whether on bearings for newer turbines, typically two megawatts and greater, or in some cases going backwards and removing DLC as they do additional replacements, and looking for another solution, because there’s potential for additional issues you weren’t expecting by adding the coating.

Allen Hall: The coating is non-conductive, which is part of the issue, because you wouldn’t think bearings are conducting electricity. But as turbines got some of these uptower and downtower converters and inverters connected to the generator, we started seeing current levels — according to Motor Doc, where people like Howard Penrose have gone out and measured currents in the nacelles — of well over a hundred amps running through ground straps and the like, into bearings. That’s a lot of current. If you’re shoving that into a bearing that has DLC on it, you’re going to break it down and create these really hard steel bits stuck inside the bearing, which wear it like pouring sand inside a bearing. That’s what eventually happens, and it has nothing to do with the bearing. It has more to do with the electrical and control systems we stuck up top and didn’t pay much attention to, but probably should have. We created an electrical situation, and now all the upkeep comes to people like you to deal with. You haven’t seen a lot of work to eliminate it, although there are a couple of good attempts happening. The reality is: okay, we have to have a bearing, and I’ve got this current going around from the nacelle. How do I put those together in a way that removes the DLC?

Cory Mittleider: That’s what we’ve spent the last ten-plus years on. As a bearing supplier, we can’t change the whole system. We have to do the best we can to accommodate what’s happening in your system. We would absolutely encourage you, if you can identify and remove the electricity, please do that.

Allen Hall: They should. And there are a lot of people who do.

Cory Mittleider: There’s a pursuit of that, absolutely. But the turbine still needs to run.

Loren Walton: We work very closely with an owner-operator that did a lot of that work. To your point from before, it does sound like, from what they’ve investigated, the current has been there for a while. It’s been there in different models and different turbines. Maybe the way it presented, or its impact, wasn’t to the same extent as what we’re seeing now. That’s where I’d say there’s more to it than just the current. I think I said last time it’s not just a smoking gun. The bearing is sitting in front of a firing squad. You put it all together and now we’re in a tough position. But to Cory’s point, we get brought the application, we get brought the environment, and we get told, “Here, make it work.”

Allen Hall: And you don’t actually see everything that’s happened. You get all the mechanical loads, but they don’t tell you, “Hey, we’re running a hundred amps through this nacelle.”

Loren Walton: No, I don’t remember hearing that.

Cory Mittleider: No, that’s not usually disclosed.

Allen Hall: No one’s ever said that. So that’s a real troubling thing happening in the industry — we’re assigning blame to mechanical components when really it’s an electrical mistake. When you dig into it, what you find is that currents have been running up top for years, but what’s changed now is that with more focus on emissions from inverters, they’ve pushed things into higher frequencies. Higher frequency bands are harder to ground out and get rid of. When things were in the kilohertz range, we could partly ground them and they’d go away. Now we’re working at ten kilohertz and up, and that energy distributes into a lot of places, including the bearings, where it wasn’t before. That’s really hard to deal with. Some electrical designer sitting in a remote location, probably in Germany, designs the circuit, and now you bearing gurus have to go fix it.

Cory Mittleider: And that system’s probably well optimized for that particular package.

Allen Hall: For that particular package, right. It meets all the requirements and does everything they wanted — except for the effect on the bearings.

Loren Walton: You solve one problem and move it to another. That’s ultimately how it works.

Allen Hall: If you’re an electrical engineer, you’d never have thought you were destroying the bearings. The industry has moved quite quickly, though. Everybody started noticing this problem with DLC. They went out to check and figure out what the problem was, and, more importantly, to find a solution. Those solutions are unique, because the reason DLC went on in the first place was to extend lifetime. So if you’re taking the DLC out of the equation, can you still get to those lifetime numbers without it?

Loren Walton: Yeah, and that’s where our message has been that adjusting the material will get you the difference you’re looking for. I want to be very clear: I’m not saying DLC as a solution is bad. When it was applied in the right space — turbines with a lighter duty — it worked great. But once you add in additional factors, it becomes an accelerant to failure at certain points. So it definitely still has its place. But once you move away from DLC, you’re going to be right back where you started — regardless of construction — with the life that was always aided by DLC. Once you’ve removed it, you have to know for sure you’re not going right back to the peeling layers and the spalling you were seeing. From what we’ve investigated, the material changes are where you get that. Having a harder surface combats it, and having a better way to combat any additional debris introduced into the system helps.

Allen Hall: And reducing the possibility of generating that debris.

Loren Walton: Correct.

Allen Hall: So what does that mean in terms of bearing design — different alloys, different heat treats, different coatings?

Loren Walton: The first two, not the third. From the recipe of the steel, adjusting some of the alloying elements, there’s a lot you can do. A lot of people think of engineering mostly through the mechanics of it, but one part of mechanical engineering that doesn’t get talked about is material science. That’s the part we dive into extremely deeply, and it gives you the biggest bang for your buck when you’re moving away from a coating as your — I don’t want to call it a crutch, but as the thing helping you get by — toward changing the bearing from the inside so it lasts better once the coating is gone.

Cory Mittleider: I like describing it as being baked into the cake. It’s not a nice thing added afterward like a coating that’s one to two microns thick. It is the bearing.

Allen Hall: It’s hard to think about steel and a lot of the metals used in the bearing industry as unique chemistries, but they are. There are a lot of varieties of steel, just like there are a lot of varieties of copper or aluminum.

Loren Walton: Yes.

Allen Hall: You’d think steel is just steel — we make cars out of it, airplanes, whatever.

Loren Walton: I was talking to someone who’s more into gears, and even when I spoke of a carbon-nitride version of a bearing versus a carbon-nitride version of a gear, it’s not exactly the same. For all intents and purposes it’s easier for everyone to consider it as steel — one word, means the same thing. But once you get into how much chromium is in it, how much molybdenum, how much manganese —

Allen Hall: It comes down to that, and it can be very small percentages of the total.

Loren Walton: It can make a huge difference. And then you get into the heat treat — your time, your soaking, what you do for quenching. It all matters, and everyone does it differently, so you get different results.

Allen Hall: That’s the kicker. You see a lot of discussions where it’s just, “Oh, it’s been heat treated.” As an electrical engineer I used to see it that way too. But there’s heat treatment and there’s heat treatment. It depends on what you’re doing and what the result needs to be, because you’re changing the whole crystalline structure of the steel. The way you do it and the way you quench it all matters. It’s not one size fits all.

Loren Walton: That’s the part that gets glossed over so quickly, because everyone’s eyes go to what they can see. You change an angle here or there, or the bearing type, and you can see that. It’s different when you don’t have X-ray vision to tell you where all the alloying elements are and in what percentages, and then whether you carburized it, through-hardened it, or carbonitrided it. There’s so much to it that I can see people’s heads start to spin. That’s where we say there are a lot of experts out here — you two are among them, and there are others. Engage in conversations. Ask questions.

Allen Hall: That’s a great call to action — “Cory, help me understand what’s going on.” There’s a variety of bearings out there. Loren’s with NSK, a great bearing company with tremendous history. Those are a couple you can trust. But operators can feel inundated by the guy down the street trying to sell them a bearing, and you don’t know if that’s the right solution for your two-million-dollar wind turbine.

Cory Mittleider: These are critical infrastructure assets. Let’s make sure we understand what we’re doing and why. To Loren’s point, you can open three boxes and they all look the same, but what’s inside is what really matters.

Allen Hall: It’s a tremendously difficult business. With as many main bearings getting swapped out today, over the last couple of years there have been a lot of decisions made on the fly — some correct, some really wrong.

Loren Walton: I’d hesitate to say wrong, because I think people are doing the best they can. It’s not because they’re not trying.

Allen Hall: It’s because they don’t have the knowledge in front of them, or maybe they haven’t made the call to Malloy or NSK yet to get the ground truth.

Loren Walton: What you mentioned a second ago is pivotal. There’s been enough selling that we’ve kind of gotten away from the engineering. People hear “sales engineer” and they cut off at “sales.” If we can get back to the engineering, a lot more people will improve their assets. And it doesn’t have to be just listening to Cory and me — poll the audience. There are a lot of us out here. Everybody has a different background; we all know a little about this or a lot about that. Take the opportunity to learn. I’d liken it to your personal life: you wouldn’t buy a new vehicle or a stereo system without doing your own research. You wouldn’t just listen to the salesperson and buy the first thing you see. It’s the same here. If you’re making decisions without engaging at least the top three to five people in this space, you’re doing yourself a disservice.

Allen Hall: And that’s what happens a lot, because people get pushed. There’s a timeline, especially now with the repower situation — “I’ve got to put something on now.”

Cory Mittleider: Right. And new platforms — the next-generation three, four, five, six megawatt platforms, and offshore — are having their first failures. We need to learn from it. That’s where we’ve worked with operators to participate in the teardown and collect the sample. We get clues, we mark it up, and we do a lot of the investigation — metallurgy, metrology, raceway traces — to inform us on what the problem is on that specific platform.

Allen Hall: As we get to these bigger turbines, some data is coming back on O&M costs relative to a one or two megawatt machine, and it doesn’t scale linearly. It goes almost exponentially, because everything is more expensive. Replacing a bearing on a six megawatt machine is a much more expensive ordeal than on a two megawatt machine. What should we be paying attention to and monitoring more closely on these larger machines? The new shiny turbine is great, but that doesn’t mean you don’t have to monitor and maintain it.

Loren Walton: I’d start with verifying all your original fits and clearances. We’ve had cases with a four-point mount main shaft — two main bearings — where one side wasn’t installed properly from the beginning, so it didn’t actually float. It’s supposed to be a fixed side and a floating side; now you’ve got one side that’s not floating, and you get overload. So make sure you’re set from the start. A lot of machines now come already outfitted with instrumentation — vibration monitoring, oil monitoring, different ways to start trending from the beginning. Back when we got started, that wasn’t the case. You got your new turbine and in a lot of cases it had nothing on it — you were flying blind. Now that it’s there, use it.

Cory Mittleider: That’s a good point. Specifically to bearings, something earlier versions didn’t have, and newer ones mostly do, is auto-lubers.

Allen Hall: I see more of those lately.

Cory Mittleider: That’s great from a lubrication-delivery and reliability point of view, but it’s its own little machine. We’ve heard of cases where the auto-luber failed, or ran when it shouldn’t have, or for whatever reason had very large output. So you need regular assessment of the entire system, including uptower.

Allen Hall: You’ve got to monitor everything that’s uptower.

Cory Mittleider: It’s its own little machine. It requires its own maintenance. If you’re relying on it, you’ve got to check it.

Allen Hall: As we move into these larger machines and see more of them deployed, what are the useful things you should be doing in that first year to make sure your bearing is working optimally? Is it just checking vibration levels? Is it getting uptower and doing a quick sweep to confirm the grease isn’t oozing out where it shouldn’t be? Is it that simple?

Loren Walton: Having a regular maintenance interval definitely helps. Even getting grease sampling to understand your baseline levels after the first six months and the first year. In a lot of cases the turbines are under a couple-year warranty, so maybe you don’t have as much access. But as much as you can, getting a baseline is huge, because you’re going to want to compare later. You’ll want to say, “Okay, I took this grease sample — what does it mean? Does it normally run that high or not?” Same for vibration, getting the trending. For main bearings in general, more grease is better than less, because you can never quite get it all out when you’re regreasing. So a lot of that first year or two is about getting a good baseline so you know what you’re actually expecting, and what it means when you take a reading in year two or three.

Allen Hall: What does a grease sample look like in terms of the response you get back? I take a sample, send it to a lab, and it comes back with — what? Is it “good or bad,” or a bunch of chemical numbers about composition and dirt? I’ve never seen one.

Cory Mittleider: It’s a matrix. You can request different versions, but probably ten or fifteen different elements they give you numbers on, in parts per million. Iron and brass will be up there.

Allen Hall: So if you see something floating in the grease —

Cory Mittleider: Silicon, phosphorus, water.

Allen Hall: Water would not be great.

Cory Mittleider: No.

Allen Hall: So those reports come back, and I assume there’s more knowledge needed to interpret the results. What do you do?

Loren Walton: We have some guidelines we share with our partners and customers. If you see a certain amount of parts per million of copper, ferrous material, or the like, we can say, “That’s worth monitoring for a while,” or “You should probably purge it, try to get it out, and see if it stabilizes.” We get those questions and respond in kind. There’s definitely help available. If we work together, we typically have a lot more success. A lot of people right now feel like they’re trying to work in their own silos, and you don’t have to do that. You don’t have to be the subject-matter expert for lubricants, gears, bearings, and everything else. You can reach out to experts who can help, and hopefully that frees up your time to assess and work on other things.

Allen Hall: The turbines are so complex today. It used to be you could have one person on site who knew most of what was going wrong, because they’d made thousands of these things — there was a legacy. When you get to six megawatt machines, where you don’t have a lot of history, particularly in the United States, there’s really no one to ask. You’d better find somebody who knows what they’re talking about.

Cory Mittleider: And the operators are responsible for multiple systems — six or seven or eight systems they’re looking at. We can help with bearings; we’re niche and focused on that. If we can take that off your plate, now instead of six systems you’ve got five to worry about.

Allen Hall: That’s key. There are experts out there, and one thing the podcast is trying to do is give those experts a chance to talk so you know who to ask. Your phones should be ringing right about now, because it’s repower time, and it’s main-bearing repair and replace time, pitch-bearing repair and replace time. There’s a lot of bearing activity going on. I always say call Malloy Wind if you need somebody who really knows their stuff, the technology, and what’s going on internally. How do people get ahold of you two if they have questions? What’s the easiest way?

Loren Walton: I try to be at most of the industry events. We usually hold a booth. And my email, my phone number — I’m on LinkedIn, so reach out there. After our last discussion I had a few folks reach out, actually mostly from other countries. It was interesting; we heard about a few issues before they even hit the US. Some folks were having problems with the larger turbines, and we were able to get our teams in Brazil and Spain involved right away. Then once it started cropping up in the US, I could say, “Yeah, I already solved that.” We can put my email in the show notes.

Allen Hall: We’ll put it in the show notes for sure. And Cory, how do people get ahold of you?

Cory Mittleider: I’m pretty active at the events — ACP, and the Drivetrain Reliability Collaborative is another one we had a couple of months ago. Email, phone, and I’m pretty active on LinkedIn. I’ve had similar experiences to Loren, getting contacted from other countries across the globe. It’s fun to investigate problems and share results in the technical articles on our website, and have people send me a picture of an article I wrote and say, “Hey, let’s talk about this.”

Allen Hall: Your articles are great. Check out malloywind.com — just Google it and it’ll come right to the top. If you have bearing questions or something you’ve seen, that website is a great first place to get some answers. It’s very helpful. Well, Loren and Cory, I love having you on the podcast. We need to have you on more, because there’s a lot going on in the bearing world.

Loren Walton: There are things we didn’t even touch on today.

Allen Hall: You’re always welcome back.

Loren Walton: Awesome. Appreciate it.

Allen Hall: Thank you.

Malloy Wind and NSK on Main Bearing Failures

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Renewable Energy

Wrong State

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Minnesota is home to intelligent, well-educated people whose approval of Trump is lower than that of toenail fungus.

If Lindell wants to lead a state, he needs to choose one at least 800 miles away. Oklahoma?

He may also want to consider that Trump is easily the most detested person in this nation.

Wrong State

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Renewable Energy

The Existence of God

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I wouldn’t say that the burden of proof lies on religion.  No one knows how the universe got here.

The Big Bang was an event in which there was no chaos, no “entropy,” as we say in thermodynamics.  How did all this orderliness get there 13.87 billion years ago? No one knows. This is an issue in cosmology which is quite likely to outlast human civilization on this planet.

I’m an atheist for a few reasons, one of which is that saying that God created the universe doesn’t get us any closer to an understanding of the cosmos, if only because it raises the question: Who made God?

More to the point, there are hundreds of moral reasons to disbelieve in God.  Each year, 9 million children will die unbaptized on this planet before their fifth birthdays.  In the bible, we learn that God punishes them all with an eternity of torture in hell.  To what sort of weirdo does this make sense?

The Existence of God

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