Renew Magazine

Water loss was temporarily fixed by connecting a downpipe diverter to send rainwater to the pool. A 5000 litre water tank was installed so we could keep the garden alive despite water restrictions.

Other small retrofits, such as fixing the dilapidated ceiling insulation and adding reflective foil in the ceiling to deflect the summer sun, helped a little with thermal comfort and efficiency, as did dismantling one of the two hot water systems (the old electric one in favour of the newer gas model).

The tanks filled slowly as there was little rainfall. The pool stayed unused and the summers were still hot and the winters cold. Removing the old electric hot water system halved our electricity usage, but most of that was taken up by gas usage.

Our efforts had been ad-hoc; to really make a difference we needed to invest more wisely.

Thoroughly tested

Before launching into renovations we tested the house from high to low to find its thermal weak points.

We estimated the R-value of all the external surfaces of the house such as ceiling, walls, windows, floor, and the area of each, to work out how much energy, in kilowatt-hours, was flowing out of the house per degree of temperature per hour, day or year. We also estimated how much energy was captured from the sun through windows. We studied passive heating and cooling and were particularly interested in the Passivhaus standard from Europe and the concept of thermal comfort.

Our measurements, using the concept of ‘heating degree days’ and ‘cooling degree days’, showed that more energy was going into keeping the house warm in winter. A heating degree day measures how much heating (in kWh) is needed to maintain a desired temperature, in Melbourne say 20°C.

On the topic of windows and glazed doors, the workshop covered design considerations that can have a big impact on the passive thermal performance and energy efficiency of the house, including size, orientation, frame and glazing type and shading. It also addressed the extra issues that need to be considered when building in a bushfire prone area and looked at some windows, frames and shutters rated for use in the higher Bushfire Attack Level (BAL) zones.

Here’s an overview of the workshop’s main points on glazing in high BAL zones below. Listen to the full, highly informative presentations on the ATA website at www.ata.org.au/bushfire.

BAL zones
A home site’s Bushfire Attack Level (BAL) is determined by a number of factors including the area’s Fire Danger Index (a measure of the probability of a fire starting), the type of vegetation and its distance from the house, and the slope of the land. The recently introduced new building regulations impose more stringent requirements on design and materials as the site’s BAL increases; for the top two levels, BAL-40 and BAL-FZ (Flame Zone), these are aimed at protecting the house from ember attack, a fairly to very high likelihood of direct flame contact and radiant heat up to 40 kilowatts per square metre (for BAL-40) or even hotter.

Requirements for windows in high BAL zones
The requirements for lower BAL zones specify various combinations of frame material, toughened glass or double glazing, and steel or bronze mesh screens to openable windows to prevent ember attack. In BAL-40 and BAL-FZ zones, however, the requirements are stricter.

We wash our clothes at night when the rate’s at 20c per kilowatt-hour, we don’t have a dryer so use the clothes line or, if it’s wet, the clothes horse in front of the fire. We turn everything off at the power point (including microwave) except the fridge and freezer. We don’t usually have the TV on until after 6pm, unless babysitting, but usually have the radio on.

We also power whatever we can using 12 volts from the stand-alone system. This includes 12 volt hand drills (converted cordless drills), fluoros over workbenches, charging cordless phones, charging cordless headphones, charging our Coleman camping lamp, running the CD/tuner, two 12 volt LED downlights and the media player and hard drive (they have voltage regulators built in and will operate from 11.8 to 14.5 volts). We also have a 12 volt to USB adaptor, with various leads to charge ipods and mobile phones.

I have also run a 12 volt feed from the batteries to our patio which powers our patio lights (I’ve removed the transformer) and a CD/tuner, which was a freebie from a mate. We also have a 12 volt pump for watering the garden.

My wife has finally sorted out all the paperwork with our supplier, after they buggered up the last couple of bills, so soon we will be able to see how much we are really saving.
Lee Saville

Panel orientation makes a difference!

I suspect a lot of people overestimate solar PV output for east and west facing panels. I recently recorded some figures when I stayed with friends near Coonabarabran in NSW (latitude 31°S).
On the property are two systems. Both have the same monocrystalline panels, with six panels in each system and no shading from buildings or trees. One system faces north with a 30° panel tilt and the other faces east with the same tilt. Both were connected to the grid in July 2011.

In 72 days, the north-facing panels produced 427kWh while the east-facing panels produced 310kWh, so the output from the east-facing panels was around 27% less.

I plan to compare the figures after they have been feeding into the grid for one year.
Ashley Campbell

Getting the units right

As a subscriber of a few years now, I’d like to congratulate you on the continuing excellence of the magazine. I look forward to its arrival every quarter.

As an engineer, I am continually irritated by people’s misuse of and misunderstanding of symbols and terminology related to energy—but not in your publication I hasten to add. I don’t think I have ever seen such misuse in ReNew except perhaps in readers’ letters.

Things like watts/hr instead of Watt-hours and the like are plentiful in the media, and especially so on the internet. Battery capacity is a particularly badly understood area. While it’s irritating, it is also understandable given that only people who followed the maths/science stream in high school are likely to have been formally taught such things. Unless you really understand the relationships between force, work, power and time it’s difficult to fully engage in discussions about energy.

My suggestion therefore is for an article or perhaps a series of articles explaining the basics of force, pressure, work and power in physical and electrical terms. I think there’s a real need for some basic knowledge to be disseminated. After all, knowledge is power (pun intended).

Anyhow, that’s my ten cents’ worth.
Neil Biggar

Thanks for the suggestion Neil, if other readers would like to see articles like this email us at renew@ata.org.au
Ed

High cost abatement PVs

I read with interest Alan Pears’ report on the concept of high cost abatement PVs (ReNew 116). I have to agree with everything he said.

What he did not cover was the fiscal side of the matter—money for greenPower is a finite resource so should be spent wisely.

Why should we as consumers pay 60c/kWh for domestic PV-generated electricity when we can get the same energy from (for example) large-scale wind for 9c/kWh? Put another way, we can pay a fixed amount per time frame (say $10 a week) and get 17kWh from PVs or 111kWh from wind. Which would you choose?

Productivity commission findings are that the abatement cost for domestic PV systems ranges from $400 to $1000 per tonne, which is very high on a global scale.

From a broad perspective, if as a society we put the same amount of dollars that have been put into domestic PV into large-scale wind, the green energy sent to the grid would have been seven-fold what we have, to say nothing of the night and winter time generation.

I am all for people having their own domestic PV systems, but why should the rest of us pay for this most expensive form of green energy?

Disclosure: I have grid-connected PV systems, for the generous feed-in tariff which all consumers are paying for.
Bruce Jeffery

Renewables better than underground cables

During the 2010 state election campaign in Victoria, the now-Baillieu government promised to implement all 67 Bushfire Royal Commission recommendations. The article in The Age on 12/09/11, Call for underground wires to cut fire risk, identifies issues being considered in relation to Recommendation 27. Instead of 20 tonne excavators digging through the bush and severely impacting fragile environments, a far better approach is to install alternate systems on properties, rather than incredibly expensive underground cabling. The cost of alternate systems could be borne by the government and the electrical transmission companies creating the rarest of outcomes: a win-win-win-win for the government, households, the electrical transmission companies and the environment.

Properties should be supplied with the appropriate systems, such as stand-alone photovoltaic (PV) systems, while others might need hybrid systems of PVs and wind, depending on the geographic location and the needs of each individual property. Residents should be fully supported to learn and manage these systems and not be lumped with a system they can’t manage. These systems should be maintained by an appropriate body for five years before becoming the responsibility of the property owner.

This approach is a far more sensible option, especially in rural/remote areas where the thousands of kilometres of underground cabling to only a few properties seems an outrageous undertaking.
Leon Trembath

We could not agree more. The ATA has been a contributing member of the Bushfire Powerline Safety Taskforce over the last 12 months, which has been considering bushfire mitigation approaches in fringe of electricity grid locations. The ATA has made the case that it will often be far cheaper for households to be provided with a stand-alone power system, under a properly managed service contract, than to pay for undergrounding or insulating of powerlines lines at hundreds of thousands or even millions of dollars per kilometre.
Damien Moyse
ATA Energy Policy Manager

Reducing fridge startup current

I recently converted a freezer to a fridge; the conversion was successful, with at least a 60% reduction in energy consumed, although I would expect this to be less during summer months. When I measured the starting current it was a whopping 180 amps from my 12 volt system and at times would drop the battery voltage too low for the inverter to cope. Upon measuring the phase angle between the starting and running currents, they were only displaced by about 15°. I expect this is standard for most small fridge compressor motors, as manufacturers do not consider correcting the phase angle as most of these units are plugged into a 10 amp grid powered outlet.

After doing a bit of research and reading I found that the best angle of displacement to provide maximum torque for the motor to start is 90°. I placed a 500 volt, 6uF capacitor bank in series with the starting winding. This required breaking into the three-pin starting relay attached to the motor, breaking the circuit and drilling a hole in the mechanism to bring out a wire to connect to the capacitor bank. The other end of the capacitor I was able to attach to an external terminal on the starting unit.

This modification reduced the starting current down to 60 amps and gave a far smoother startup in less time. At the moment of starting, my 600 watt inverter did not have any trouble starting the fridge, as the shorter starting time and lower current allowed the battery voltage to remain steady.

I believe this conversion will allow people with small to medium solar energy systems and inverters to be able to use standard off-the-shelf fridges. I would be happy to forward a schematic diagram to any ReNew readers who may need to reduce the starting current and increase the torque of any induction motor which has a start-run winding.

Out of interest, my system is a 720 watt capacity photovoltaic system with a 12 volt, 800Ah (C/10) battery bank and 600 watt continuous, 1200 watt surge capacity inverter.

Peter Rusanow, electenergy@yahoo.com.au

Peter’s modification is a good example of adapting off-the-shelf equipment to be a bit more efficient and much easier to run on smaller renewable energy systems. Unfortunately, most manufacturers don’t consider the use of their equipment on renewable energy systems when they design it, preferring to keep designs simple to keep costs down (which is fair enough, as most devices will never be used on small renewable energy systems).

We should state here though that this sort of modification can be dangerous if done incorrectly and that you absolutely must have a good understanding of electrical theory and practical applications before attempting any such modifications. These modifications will, of course, void any warranty on your fridge and should such modifications cause a fire, don’t expect your insurance company to pay up!

Lance Turner

Fortuitously my system has battery backup and is easily configured so that I will always get at least the current rate that the energy retailer charges for the electricity generated, irrespective of what they do with the feed-in tariff.

Further explanation

Without government rebates my costing for a nominal 2kW system is around $12,000. This is broken down into $6000 for panels (ten 200W panels), $2800 for an inverter/charger at Jaycar, $1500 for 10kWh capacity ex-Telstra gel battery pack, $400 for two 60 amp solar regulators and $1300 for installation. Such a system will generate 3285 kWh per year in the Sydney area. My nominal 3kW system produced 5091 kWh in the last 12 months so I have tried not to give over-optimistic figures.

The beauty of having a battery backup system is the flexibility of either selling the generated power to the grid or else storing it and using it yourself. This means that if you missed out on some of the generous feed-in tariffs offered in different states, you will at least be always guaranteed the current peak rate charged for electricity. From July 2011 it was 25c/ kWh or 35c/kWh if measured on a time of use meter, according to NSW figures.

Assuming that $12,000 was paid for the system (unlikely as the Federal Government Solar Credits Scheme would bring down the price) the return could be as much as 6.8% pa. This calculation uses the 25c rate: 3285kWh x 0.25c = $821.25.

A more serious investor would put in a system with double the number of solar panels and use a larger capacity inverter/charger such as one from Xantrex or Selectronics, resulting in an outlay of $22,000 and a return on investment of 7.5%. These returns, with their guarantees (the return will only increase over the next 10 years as electricity prices increase) make PV solar systems, particularly ones with battery backup, a very sound investment. Take into account the current Solar Credits Scheme then $3000 can be deducted from the capital outlay for the 2kW system lifting the return to 9.1% pa. The return on a 4kW system jumps to 10.3%.

Solar credits

Note that there is no tax on returns from these investments so, depending on your tax level, a normal investment return in the order of 15% could obtain the same monetary return. On the other hand, if you are a part-aged pensioner, as my wife and I are, and own your own house, then your part-aged pension could increase because the investment becomes part of the family home, which is a non-assessable asset. This will increase the effective return by a couple of percentage points, making a possible return on investment of over 10%.

The range of all-electric quad bikes from Urban ATV eliminates these problems. The bikes range from little 800 watt units more suited to the kids, right through to a 3kW full-sized quad.

The 3kW model has twin brushless 1.5kW motors powered by a 48 volt battery bank, a high tensile steel frame, top speed of 60km/h, range of up to 70km, can climb 40 degree slopes, front hub and rear hydraulic brakes and double spring front and single spring rear suspension. It weighs 285kg and measures 1980 x 1080 x 1160mm.

RRP: $510 for the 800 watt models through to $3200 for the 3kW unit.

For more information and to buy, contact Urban ATV, ph:(07) 5493 0808, urbanatv@iprimus.com.au, www.urbanatv.com.au

The Perfect Flow Ultimate showerhead takes water saving even further, using just 5.5 litres per minute and has a 3-star WELS rating. Unlike many ‘low flow’ showerheads, the Ultimate is not simply a restricted higher flow unit, meaning the user cannot tamper with the flow rate by removing a restrictor.

The showerhead comes complete with articulated arm, or can be installed to an existing compatible shower arm.

RRP: $30

For more information and to purchase, contact Todae, ph:1300 138 483, www.todae.com.au

The sockITz range of power points combine an Australian Standard dual 240 volt power point with twin USB powered charging outlets for charging mobile devices. The inbuilt USB sockets are completely powered off until you slide the socket cover to the side. They then power up and a LED comes on inside the socket so you know it’s working. The USB sockets can provide up to 2 amps, which is enough for any portable device on the market that is designed for USB charging.

RRP: $37.95 but currently available on pre order for $24.95. An illuminated Apple or micro USB cable is available for $19. The aluminium finish wallplate model is $2 more.

For more information or to buy, go to www.sockitz.com.au

Photovoltaic panels produce electricity directly from sunlight in a solid-state process—there’s no moving parts to wear out, just large inert panels that have very long lifespans. The most popular use of PVs nowadays is to supplement mains grid power and reduce electricity bills. However, solar PVs have many other uses including to power off-grid houses, water pumping systems and remote communications systems, as well as in large commercial solar power installations.

The different technologies
There are three common types of solar cells: monocrystalline, polycrystalline and thin film.

Both mono and polycrystalline cells are made from wafers cut from blocks of silicon. Monocrystalline cells start life as a single large crystal known as a boule, which is ‘grown’ in a slow and energy intensive process. An example can be seen at right. Polycrystalline cells are cut from large cast blocks of silicon rather than single large crystals.

The cells are then modified by a process known as ‘doping’. This involves heating the cells in the presence of boron and phosphorus, which changes the structure of the silicon in such a way as to make it a semiconductor. This is the same method which is used to make integrated circuits.

Once the wafers have been doped, they then have a fine array of electrically conductive current-collecting wires applied to each side of them.

Thin film technology uses a different technique and involves the deposition of layers of different materials directly onto metal, glass or even plastic. The most common thin-film panels are the amorphous silicon type, which are found everywhere from watches and calculators right through to large grid-connected PV arrays.

In recent years, other types of thin film materials have started to appear. These include CIGS (Copper Indium Gallium (di)Selenide) and CdTe (Cadmium Telluride). They tend to have higher efficiencies than amorphous silicon, with CIGS cells rivalling crystalline cells for efficiency.