Natural Resources Committee on May 9th, 2007

Mr. Chairman, thank you for inviting me to speak to the committee.

You have invited us here to speak about cogeneration, or the simultaneous production of thermal heat and electrical energy. While cogeneration is not the main focus of our work, it is nonetheless one of the many factors to be considered in our market and energy analyses. We are planning to publish one of these analyses, the Report on Energy Futures, in October 2007.

Like many of the reports of this nature, it is a long-term balance of supply and demand in Canada, going out to the year 2030.

We have a number of other studies that we have conducted over the years, and I've distributed to the members of the committee a list of those studies. The ones I'd like to draw attention to, which will be the basis of our remarks today, are a study on emerging technologies that was conducted in June 2006 and a report that we completed on the challenges related to oil sands, which we produced in October. We were here with the committee in October to discuss that report.

We undertake all this work in the context of our mandate under the National Energy Board Act. Today I'd just like to very briefly touch on our mandate. I'm sure most of the committee is very familiar with it, and I won't go into great detail. I'll talk briefly about cogeneration, and my colleague Mr. Bob Modray will focus more on some sectoral and regional aspects of cogeneration, some benefits and challenges that come from the work. Then we will talk a little bit about our ongoing work on energy futures, which I referred to earlier.

Firstly, with respect to the National Energy Board, we are an independent federal tribunal. We are located in Calgary. We have been there since 1991.

Our responsibilities are twofold: regulatory as well as advisory. It's in the construct of the advisory role that we're here today, primarily talking about how we monitor energy markets and how they're functioning, and we produce a number of reports.

Just moving on to cogeneration, the focus of our comments today, it really has to do with the simultaneous production of thermal heat as well as electric energy, and it's often referred to as combined heat and power. Generally speaking, conventional power plants will emit a fair amount of heat that's created as a byproduct in the production of electricity, and cogeneration systems are a means to capture that lower-grade heat and turn it into a useful purpose, such as paper drying from the chemical processing, or space heating. The important thing is that you do need a use for that heat in order for cogeneration to work.

The next two slides are really just a very simplified process of how that heat is captured and reused. Essentially, you can take a standard thermal generation station from an efficiency of about 35% of the usage of the heat, and through cogeneration you can bring it up to 75% efficiency. So it's a significant gain as far as the reduction of waste heat and the use of that energy.

With that, I'll turn it over to my colleague, who's one of our senior economists who has been focusing mostly on electricity markets.

Bob.

Thanks, John.

What I would like to do over these next few slides is give a bit of the sectoral and provincial perspective, and, as John mentioned a little earlier, some of the benefits and challenges associated with cogeneration. Then I would like to bring it back to some of the long-term outlook work that we're doing.

I'm on slide 8 now. With respect to the sectoral applications, cogeneration currently occurs mostly in the industrial sector, in the industries indicated here. Somewhat less than commercial, this is more in the institutional setting. There are very limited, if any, commercial applications right now in the residential sector. As mentioned, electricity is often a by-product of the primary uses for process and heat in a lot of these sectors.

Regionally, cogeneration occurs on a volume basis. It's obviously predominant in some of the gas producing and consuming regions, Ontario and Alberta. With respect to B.C. and some of the eastern areas, there are fairly big applications in the forest industry.

The main fuels tend to be biomass or wood waste in the forest products area. Natural gas is increasing. Of course one of the big emerging uses—and I'll talk a bit about that later—is in the oil sands.

Going down the road, with respect to emerging technologies, we have tremendous waste heat being produced from fuel cells and coal gasification, which could also go into a combined cycle mode.

In terms of the benefits of cogeneration, there's a clear efficiency benefit that translates eventually into lower energy costs and lower emissions. From the standpoint of a producer, it can provide him with energy system reliability, and from the social standpoint, system security.

To the extent that we get into going down the road of more uses for distributed generation, say in an urban setting or in some of these bigger institutional settings, we can see cogeneration being an enabler to allow those distributed generation systems to occur.

With respect to the challenges, one of the big things with respect to cogeneration is that you've made an investment in these facilities, and if you're using something like natural gas or another fuel that has volatile prices, then you could be in a situation of not making the return on your investment.

Some of the other challenges we've listed here are ones we noticed in a study John referred to, which we released about this time last year. It was entitled “Emerging Technologies in Electricity Generation”. There are such factors as sometimes cogenerators cannot always access their markets. At other times, there are difficulties in obtaining access to the transmission grid.

It's sometimes stated that some of these technologies have social and environmental benefits and perhaps they are not able to capture the value of that. Perhaps there should be some sort of environmental premium attached to them.

When it comes back to large-scale application, say in the commercial sector, perhaps even in the residential sector too, so far in Canada and North America overall, there has not really been a lot of the coordinated planning that needs to be happen in an urban setting. Perhaps that's something that will be there in the future.

With respect to the oil sands, this is one area that has really been growing. I'm sure members on this committee know that we currently produce close to a million barrels a day. The study we did last year indicated a future range of something like two million to four million barrels over the next ten years.

Coming along with that will be tremendous process heat and opportunities to produce electricity in that cogeneration mode.

One interesting thing about the oil sands use is that a few years ago the producers wanted to size their facilities more for their own heat and power requirements. There was the real prospect of making a lot of power available--oversizing the cogeneration units and shipping that power south. Although that idea is still there and still a prospect, it seems to be less of one than it was a few years ago.

Another issue with the oil sands as a fuel source is the higher gas consumption coming very soon. I think there will certainly be other options pursued there. One of the most recent has been talk about nuclear in that area. It's quite speculative at this point.

On program incentives, I have a page here on some of the federal programs that are available through taxation, and some direct assistance as well. The provinces have some programs geared for cogeneration as well, through direct purchases that some of them are arranging.

On our energy futures work, a report will be coming out in October. We've consulted quite broadly across the country. We've had two rounds of consultations on this document.

We're basing it on three scenarios. We've represented the scenarios in terms of price tracks on slide 14. We have a reference or continuing trends case, with prices receding to the $50 range in the future. We have what we call a fortified islands scenario that results in a higher price track--over $80. Then we have what we call our triple E scenario, where we have a balance between energy, economy, and the environment. It shows higher prices initially but then receding, with a number of options available relative to the current conventional fields.

On the next slide we show those prices and the implications they have through the pricing system for the other main energy products--coal, natural gas, and the renewable fuels. Based on that we've done a preliminary projection. We still have some work to finish it up, but this is what we were talking to people about in our last round.

I guess what's evident on this chart is that all scenarios show significant growth in electricity demand. The other thing that stands out is that hydro will continue to dominate over the next 25 years or so. Particularly in the triple E case, we see more of the emerging technologies. One of the big ones there is wind, growing rapidly from less than 1% now to perhaps 11% in the triple E case.

In the other scenarios we have variants on that, obviously less in the case of the fortified islands, which has more traditional fuels; and continuing trends where we are today, moving ahead more gradually with respect to those fuels.

Overall we would look to something like a triple E scenario that has more emphasis on efficiency, and this balance being more amenable to a cogeneration situation.

I just want to summarize our thoughts here. First, we feel that cogeneration offers significantly improved efficiency in energy use. It can reduce the demand for primary fuels, reduce emissions per unit of energy consumed, and make lower-cost power available.

There are also the benefits of more diverse sources of energy, with diversification in the locations of energy generation. But there are associated risks with respect to capital costs and price volatility when you're working in two markets--a heat market and an electricity market.

The opportunities vary significantly from coast to coast and are dependent upon a need for the waste heat that's located where you're going to be generating the electricity. The oil sands is a good example of where that waste heat will be needed. Finally, it complements strategies toward distributed generation.

Mr. Chairman, I hope that gives you an overview of cogeneration.

In speaking with the researcher in advance, he mentioned that there may be some interest among committee members in natural gas. The last slide shows the same scenarios but with Canadian gas production taken out, so you can see what our view is there.

This again is preliminary work. We're finalizing it and incorporating the consultations that are just concluding. We will be publishing in October. I would be more than happy to come back to meet with the committee at that time to present our final results.

Thank you.

I can't help but remark that it's quite charming to see so many carnations. Not since my high school prom have I seen so many people dressed like this. When I came in, I thought no one told me about the dance and you guys had all rushed in from some prom to do this.

Thank you for inviting us. The Forest Products Association of Canada represents the industry from coast to coast: lumber, wood, pulp and paper. I've come here to give you some good news, in fact some great news: that it is possible to generate green energy. It's possible to be environmentally responsible and it's possible to make a buck while doing it. Cogeneration in Canada's forest industry is the example of that good news.

We have switched our fuel usage to renewable biomass, sawdust, bark, chips, stuff that would otherwise have gone to landfill. When we did this, we reduced what goes to landfill by 40%, stuff that would have rotted in the ground.

We have reduced our greenhouse gases by 44%, not in intensity but an absolute reduction, and 54% in intensity. We've reduced our air pollution by 70% and we've improved our cost-effectiveness, because we are no longer dependent upon fossil fuels. Our fossil fuel use is down by 45%, and we're now at about 54% cogeneration.

So instead of bemoaning the price of fossil fuels, instead of polluting through the use of fossil fuels, we've switched to renewable biomass. We use what's at hand and we are now generating enough clean, green energy just in our mills to replace three nuclear reactors. We generate enough electricity just in our mills to power all of Ottawa-Gatineau, and we're not stopping there.

Our intention is to become energy self-sufficient. Our intention is to export green energy to the communities where we work. So instead of sending expensive energy through long grid lines from some coal or nuclear plant in southern Ontario or southern Quebec, our plan is to work to the point where our mills generate not only enough energy to run the mill, but also to run to the nearby town and thereby have a more sustainable, affordable, and environmentally responsible approach to energy generation.

All of this will be done through industry innovation, through business innovation. It's not through regulation, not through government intervention, but by business, by local communities finding solutions that work using materials at hand.

We can go further, of course, and faster if the policy climate favours us: if there's a robust trading regime for greenhouse gas credits so that we can use that to help finance new boilers; if all renewable energy, not just wind and solar, is recognized in government programs; and if the accelerated capital cost depreciation is extended from two to five years. All of these things would make it possible for us to speed up this good news revolution by retooling our mills still faster.

But even if government does nothing, we will continue down this road, because it makes sense and because we didn't wait for regulation to start and we're just going to do the right thing regardless.

Thank you so much for inviting us, and we're ready for questions.

Yes, but I'd probably phrase it a little differently. We use scenarios because we can't predict the future. We can't predict the policy or environment that we're going to be working in, particularly up to the 2030 timeline, so we create a scenario.

We have created three scenarios to kind of give us a balance, a spread, if you will, of what's possible. Through that analysis, we hope that we can identify pinch points, identify things that are common across the scenarios, identify things that influence one scenario over another, and then try to understand the system a little better.

We don't necessarily choose one option over the other. It is difficult for us to model. One scenario we have is what we call “continuing trends”, which takes into account all existing policy decisions. Those are changing rapidly. We're trying to model that.

So that does make it difficult for us, but I think our work will help to give people a sense of what might be the long-term implications of some of these decisions, or what might be the pinch points that perhaps wouldn't be considered.

One thing that I think is unique about our work is that we do integrate all energies. We look at it with a completely holistic approach with respect to energy. That's unique in the Canadian economy or in the Canadian resource review.

One thing we do with our scenarios is that we do make a balance. We do make demand and supply meet. That's one of the outcomes that happens in all of our scenarios.

You asked me a couple of questions there. One was with respect to whether the increase is reasonable. I'm not familiar with the data you referred to, and I couldn't say exactly what the numbers are that we're using. But one thing we do note is that there seems to be a very strong link between energy usage and GDP growth. As we all get a little more wealthy as a country and as an economy, we tend to use energy a little bit more. So we tend to see there is an overall linkage towards those.

At the same time, we're seeing a significant improvement in efficiencies. Energy use is still growing. It's not growing as fast as GDP, but it is growing, and it's growing faster than population. If you look at it, it's sort of between the two.

With regard to the percentage, if we're talking about the energy needs increasing over time, I think that's true; they will increase over time, and that's what we indicated. We just looked at the electricity demand aspect in our slide. You can see there's quite a significant growth. From now until 2030, I think in one case there was a 25% increase up to about a 50% increase in energy demand over that period of time. And that's only electricity; there are other forms of energy as well, of course.

The other thing to note is that where you source that energy changes. It doesn't change significantly, but there are shifts. For example, in one of the scenarios, we had a significant growth in wind contributing to the larger consumption needs in that period of time up to 2030.

So to answer your questions, it's a bit of both; it's both.

The line you're referring to is the production of gas from Canada. As a bit of background, the majority of Canadian gas currently comes from the western Canada sedimentary basin, and the basin is mature, in that the ability for the basin to increase its production is very much dependent upon the economic incentives, if you will, or the environment, including price, that's provided to the folks who produce that natural gas.

In the scenario here, we have reflected a steady state as far as level of price and level of activity are concerned. We can see that if that assumption continues, we will continue to see a slow decline in western Canada sedimentary basin gas.

No, the green below is.... One thing I should say is that this is “all of Canada” natural gas. I've been focusing on the western Canada sedimentary basin, but it is all of Canada.

Concerning the green line, you may remember from the scenario that we used a much lower price for energy. At the lower price there was less activity. With less activity you have a steady decline in the amount of production of natural gas from Canada. One of the assumptions that's part of this scenario is that the decline in natural gas from Canada is made up with natural gas sourced from elsewhere in the world through liquefied natural gas. That is part of this scenario.

The big story from this is that there isn't a huge amount of new natural gas within Canada. There is an ability to increase it, but it's limited. Even maintaining it will be difficult.

That's a very good question.

Time is very important when we are doing this work. This document comes from our consultation document, which we consulted with over the period probably from March to.... It's ongoing. Since then, the policy environment has changed significantly, and what we thought was a rather aggressive policy environment when we were setting it out turns out to be in fact a little soft copmared with what people are actually moving towards. When we are re-doing our numbers, first of all in the triple-E scenario, for example, which is our most aggressive policy scenario, you will see some shift.