Natural Resources Committee on April 23rd, 2007

Regarding the $40 million, we actually contribute to a survey every year for the International Energy Agency. These numbers show what energy work we're doing.

A number of areas—I mentioned many of them—are related to industry and priorities. We don't have a concentrated program in renewable energy, particularly. We haven't had that since the early eighties, when we had the solar program and the other program in energy. But priorities have changed, and NRC doesn't—

We look at how we can actually help industry meet the demands on them to meet energy requirements or reduce their energy use. As you probably heard from industry at committee, in manufacturing, one of their major concerns is increasing energy costs, and these are the things we work on. One is to use renewable energy and new fuels and so on to try to reduce their costs.

So we may put that in the industry pocket. That's how we can help industry, but it's not really renewable energy. We don't give—We don't characterize our work as alternative energy; we characterize it as industry needs.

Yes, certainly, I can do that.

Certainly the building code and general construction is a provincial jurisdiction. What NRC does is work with the provinces—it's a very close collaboration—to produce a model code. The model code then has to be adopted into force by provincial legislation. It can't be effective until the province says it will use that code as its energy code and actually puts it into effect.

This did not happen for the past code. The difficulty is that the cycles change, with energy. By the time we produced the code, energy and environment were not at the top of their priorities, and no province has adopted it. There is, in Quebec and Ontario, some energy.... Quebec has adopted energy measures that were produced back in 1983. Ontario has energy requirements in its building codes. But there isn't an energy code per se.

I think the intention now is really to take the leadership with NRCan in the discussion with the provinces that we update that energy code. The hope—actually, maybe the promise—is that they're going to put it in effect for buildings this time.

We have a code from 1997. It needs to be updated, because energy costs and the cost of construction have gone up and changed, and so has the financial position. So we have that, and provinces such as British Columbia have used it as guidelines for a long time. Now they would like to update it to the new realities. They agree with NRCan to start on updating very soon, so it's actually an agreement almost in effect now to start updating the code.

There's definitely an international direction looking at sustainability in general, and one of the areas is life cycle analysis of building materials and components, where you choose a material and you have to look at it from the source, all the way to decommissioning, when you throw it away, even the disposal. There is work around databases that actually show concrete versus wood versus steel, and that sort of thing, so people can make decisions.

However, it hasn't penetrated the industry. The industry still goes with traditional wood frame with whatever new materials come in. When you look at the sustainability, at the same time you have to look at a number of things—how it will perform, and as you mentioned, how it will last with time, and so on, not only the price and the sustainability.

It hasn't been taken on. The industry hasn't really picked up the life cycle analysis as a means for choosing materials. There's other work on the materials even in terms of what does it emit inside a home, emissions and indoor air quality. That work exists, but it hasn't penetrated as much in the construction sector yet, not only here but worldwide, I would say. There are some countries doing better than others.

But definitely that's the trend, to look at life cycle analysis—and at the same time, performance. You look at the performance and the longevity of these materials. Sometimes it's not the materials per se. We now use composite materials, plastic and wood together, so we can use the waste wood along with polymers, and so on. The material may be good and stay, but if you look at it from one end to the other, it may or may not be better than wood. I don't have the answer, but it's really something to look at.

The difficulty with using materials in buildings, as well, is how you integrate that material within the system. The wood chipboard, or whatever, the OSB, oriented strand board, can be a good material if you really build it right, if you include it as a system, rather than putting it as you used to put other sheathing. It's a different material. It has to be integrated within the system. You have to look at how the system will behave with that material in it. If we don't do that, it will be what you've seen, early rotting and so on.

Yes, there's quite a bit of work on hybrids as well. The NRC has not worked on the whole system, but we have worked, in one of our institutes, on batteries, lithium batteries and other batteries, new technology for batteries that actually work in hybrids.

As to fuel cell cars, there are still few around, I guess, until China builds up their—A thousand cars is probably the largest fleet. The industry is looking at fuel cell cars, but they will probably be on the market only in 15 years or so. Fuel cells for other applications are moving faster than for cars.

Actually, the NRC is not doing any work on hydro-electricity. The only work I mentioned is some work where IRAP funded some companies to look at small systems to place in the middle of a river or stream, or even a waste stream. It's the idea of an egg beater that rotates and generates electricity from the stream. It takes about 40% or 50% of the stream energy to actually generate it. That's one.

For the rest of small hydro and the rest of the alternatives, there's quite a bit of work supported by Natural Resources Canada, so we haven't got into that. The mandate is at NRCan, and we get into areas where we can work with industry, whether with NRCan or with our expertise, and bridge the gap between them, but not much in hydro-electricity.

We did work a long time ago, about 20 years ago, on horizontal wind turbines. At that time, we called them “egg beaters”. You may have seen the pictures. The work was done at NRC, and it was tested at the wind tunnels as well, but it didn't actually take off. I guess the Europeans have somehow taken hold of the wind energy file or wind energy production. Most of the wind turbines being used now come from places like Denmark and Holland, the Netherlands.

There are small wind turbines, as I mentioned. A company makes small ones that you can put on top of a house to run a heat exchanger, a small hot-water system, or something like that. This is a new development. It can be integrated with energy systems for a single unit or a small building, where you can combine wind, small hydro near a stream, or fuel cells in the future. It will become an integrated system that you won't supply through only one item. You can supply electricity and heat from difference sources and integrate that within a building.

The research we're doing at the Canadian Centre for Housing Technology is part of that. When we put in a fuel cell, the first fuel cell to be put in a residential building, the idea was to integrate it with other sources within the house to supply energy. The next step, which is the thinking now and is not in place, is to try to put an integrated energy system in a house, working with NRCan and others in putting that together.

Our institute in Vancouver is as well trying to think of fuel cells in an integrated fashion. For example, there are some fuel cells used in Japan as part of the energy system for a house. The company in Vancouver is selling that in Japan.

It is starting to show up. The institute will look at how you can integrate that particular source, along with other energy systems, so that it comes with controls to connect to the grid, area controls, and instrumentation areas.

No, it's not done at NRC. The research at NRC is really on transportation.

Electricity generation and transport work is done at our Institute for National Measurement Standards. They actually work on measurements and on how to measure these losses. In the exchange of electricity for electrons going south, north, east, and west, how do you really measure it accurately to be able to get the right charges? This is work that is being done at NRC at our National Metrology Institute.

I know the work on losses and transportation, DC and AC, is done quite extensively at hydro, whether it's Manitoba, B.C., or Quebec, but it's not done at NRC.