For decades, gas has been the go-to energy source for heating and cooking in homes across the world. Many homeowners appreciate the reliability and immediate heat gas provides. However, recent studies are shedding light on the hidden dangers of gas heating and gas cooking—both to human health and the environment. As the world shifts toward cleaner, safer energy solutions, it’s important to understand why transitioning away from gas may be one of the smartest decisions you can make for your household. 1. Health Risks of Indoor Air Pollution
While gas appliances seem convenient, they can significantly impact the air quality inside your home. Gas heating and cooking systems emit harmful pollutants, including nitrogen dioxide (NO₂), carbon monoxide (CO), and particulate matter. These gases and particulates are released directly into the air and can accumulate indoors, leading to poor air quality. Poor ventilation, especially in homes with sealed windows for energy efficiency, compounds the problem.
2. Fire Hazards and Explosions Gas appliances pose a direct fire hazard, as leaks can go undetected until it's too late. Gas leaks from faulty appliances, aging pipes, or improper installation can lead to deadly explosions. Even a small leak can fill an enclosed space with highly flammable gas, turning a simple spark—such as flipping a light switch—into a dangerous situation. According to the US National Fire Protection Association, cooking is the leading cause of home fires, and gas stoves are a significant contributor to these statistics. 3. Environmental Impact of Gas Gas is often touted as a cleaner fossil fuel compared to coal or oil. While it may burn more cleanly, the environmental impact is far from benign. Methane, the main component of gas, is a potent greenhouse gas, trapping heat in the atmosphere 25 times more effectively than carbon dioxide. Leaks from gas infrastructure—both during production and transportation—release vast amounts of methane, contributing significantly to global warming. In fact, the International Energy Agency estimates that methane emissions from the gas supply chain are responsible for nearly 30% of the rise in global temperatures. By continuing to use gas in homes for heating and cooking, we are perpetuating the demand for fossil fuels, delaying the transition to cleaner, renewable energy sources. 4. A Costly and Outdated Infrastructure Many gas pipelines in older homes are reaching the end of their lifespans, leading to more frequent leaks and repairs. Maintaining and upgrading gas infrastructure is costly, and those costs are often passed on to consumers. In some cases, municipalities are facing mounting bills to replace aging pipelines. Transitioning to electric alternatives, such as heat pumps and induction stoves, not only eliminates the need for ongoing gas infrastructure maintenance but also supports a cleaner energy grid that can be powered by renewables. 5. Cleaner, Safer Alternatives: Time to Go Electric Switching to electric appliances for heating and cooking offers numerous advantages. Today’s electric heat pumps are more energy-efficient than gas heaters, providing both heating and cooling from a single unit. Induction cooktops offer faster, more precise cooking while eliminating the risk of indoor air pollution from combustion. These modern alternatives also reduce your household's carbon footprint and improve overall safety. Many countries and states are recognising the dangers of gas and have begun introducing policies to phase out gas appliances in new construction. In some places, there are even incentives available to help homeowners make the switch to all-electric homes, including rebates for heat pumps and induction cooktops. Conclusion While gas heating and cooking have long been considered reliable, the risks associated with using gas in the home are becoming harder to ignore. From the health impacts of indoor air pollution to the environmental toll of methane emissions, gas appliances are no longer the best choice for modern, health-conscious, and environmentally aware households. Fortunately, electric alternatives offer a safer, more sustainable way forward, helping you protect your family's health while doing your part to address climate change. Making the switch to electric is not just an investment in your home’s future—it's an investment in a healthier, more sustainable world. Understanding the Duck Curve: The New Challenge for Renewable Energy As renewable energy sources like solar power become more prevalent, the energy grid faces new challenges. One of the most prominent is known as the "duck curve"—a term that describes the unique way energy demand fluctuates when a significant portion of electricity comes from solar energy. In this blog post, we’ll break down what the duck curve is, why it matters, and what can be done to address it. What is the Duck Curve? The duck curve illustrates the daily pattern of electricity demand on a power grid that incorporates a lot of solar power. The term comes from the shape of the graph, which, when charting electricity demand over the course of a day, looks like the silhouette of a duck. Here’s how it works:
The price of electricity on the wholesale markets closely follows the Duck Curve as can be seen from the below image. Why the Duck Curve is a Problem At first glance, the duck curve might not seem like a big deal. However, it presents a few key challenges for grid operators:
Cleaner power is cheaper power Like price, the carbon intensity of the grid closely follows the Duck Curve. The cheapest times of the day to procure electricity from the grid also correlate to when the grid has the lowest carbon intensity. Solutions to the Duck Curve Problem Addressing the challenges posed by the duck curve is crucial for maximising the potential of renewable energy. Here are a few strategies that can help:
The Path Forward
The duck curve is a natural consequence of our transition to cleaner energy, and it highlights the importance of creating a more flexible and resilient energy grid. By investing in energy storage, modernising infrastructure, and diversifying energy sources, we can overcome the challenges posed by the duck curve and accelerate the shift toward a more sustainable future. As more regions adopt renewable energy on a larger scale, managing the duck curve will become increasingly vital to ensuring that our energy systems remain reliable, affordable, and green.
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My Energy Guide is proud to launch our Home Batteries 101 Guide. This comprehensive guide is packed with valuable information to help you save money and reduce your carbon footprint.
âWhether you're looking to become more energy-independent, lower your carbon footprint, or simply save on utility costs, this guide will help you understand the basics of Home Battery storage. Six months ago we completed the final steps in our Home Electrification project.
Below is a summary of our Household data since then. Similar results may be achievable for more households than many might expect, and I hope that by sharing our experience, others will be inspired to begin their own electrification journey
My Energy Guide is excited to announce the launch of our Hot Water 101 Guide. This comprehensive guide is packed with valuable information to help you save energy and money at home. Download your free copy today and unlock a more sustainable future!
We are nearing the 24-month mark since we purchased our Tesla Model Y, during which we have driven 26,137 kilometres. Below is a direct cost and CO2 comparison between the Model Y and my previous vehicle, a Kia, over the first 24 months of ownership. Most of the driving consists of short town trips in hilly terrain, along with some road trips primarily for leisure. The main cost difference arises from fuel expenses: covering 26,137 km in the Kia cost $9,775, whereas the same distance in the Model Y cost only $297. The Model Y is mainly charged at home using excess solar power. During road trips, charging is often free at the final destination using a standard 240v plug socket. The Model Y requires no servicing, sparing the annual cost that comes with an ICE vehicle. $940 was spent on servicing in the first 24 months for the Kia. However, tyres can wear quicker in an EV than an ICE vehicle. This is due to the instant torque delivered by the electric motor and the slightly heavier weight of the vehicle. Recently, at 25,900 km, we replaced all four tyres on the Model Y for $1,744, which constitutes the majority of the costs for the first 24 months of ownership. In contrast, we replaced two tyres on the Kia during the first two years at a cost of $520, with post-COVID inflation possibly contributing to some of the price difference. The CO2 savings from EV ownership are substantial, even exceeding the cost savings. Our Kia would have emitted 13.8 tons of CO2 over 26,137 km, whereas the Model Y, primarily charged using excess solar power or during midday when the grid is 50-70% renewable, has significantly lower emissions at only 0.15 tons. We look forward to the coming years of EV ownership where the price and CO2 savings will grow even further.
The Innes family From Sydney transitioned to an EV a year ago. Their vehicle of choice was a Hyundai Ioniq 5. It's their go-to car for local errands, but they've also used it for several road trips, even carrying four bikes! They have covered 9,180 kilometres so far. They have a 15-kw solar system and also a retail plan that offers free access to the grid during the middle of the day on weekends. Mr. Innes is keeping close track of all their charging costs to see how much money they're saving with the EV. Source of power The below chart details the sources of all power used to charge the vehicle. The vast majority, over 80%, has come from charging at home. Cost of power However, while charging at home accounts for 80% of the power used it only accounts for 30% of the total costs spent. This is primarily due to taking advantage of excess solar energy and free grid charging on weekends. Supercharging, while only accounting for 12% of power consumed, accounts for 70% of the total costs incurred! Comparison to ICE vehicle So how does this compare to the Innes family’s previous Internal Combustion Engine (ICE) vehicle? The ICE vehicle would have cost over $2,000 in fuel compared to the $192 for the EV, a staggering 12.1x uplift. However, when the cost and kilometres associated with supercharging are excluded, this difference between the EV and the ICE vehicle increases to a 42.2x difference! The above analysis does not take into account maintenance and servicing costs which would increase the cost gap between the EV and ICE vehicle even further. EV’s have around 20 moving parts compared to over 2,000 for a petrol vehicle resulting in far lower service and maintenance costs. Final word The average passenger vehicle in Australia travels just 33.2 km per day meaning the vast majority of charging could conveniently happen at home. So the experience of the Innes family is likely to be one that could replicated by many households around the country, even those without solar who can now take advantage of retail plans offering free access to the grid for charging during certain times of the day. ICE vehicle calculation based on the average unleaded fuel price in Sydney as per the NRMA website on 18 June 2024 and a fuel efficiency of 12L per 100km. The fuel efficiency is based on the vast majority of kilometres being driven on short runs in a hilly area which is where the person subject to this analysis resides. Australian households 🏠 are paying an average of approx. 35 cents per kWh for their electricity, a record high and it continues to rise 💸 10-15 cents of this cost relates solely to the use of the "poles & wires" to transport the electricity from where it is generated to your home; that's the cost a homeowner has to pay BEFORE factoring the cost of the electricity. Now what is someone told you that you could lock in a price of just 5 cents per kWh for the next 20 years?! Well you can do just that with a solar and battery system 😎 🔋 Solar and battery cost is based on actual data from My Energy Guide Founder’s household and assuming a 20 year life with $1,500 p.a. income from exporting excess energy. It excludes any financing costs. The solar and battery cost is for illustrative purposes only and it could materially differ depending on the household’s hardware, location and energy and travel demands. When you use power matters.
If you use power from the grid in NSW outside of 9am to 3pm then, no matter what claims your retailer may make about carbon neutrality, it is predominantly power generated from coal which has a high carbon footprint. If you have a solar system without battery storage then chances are you still use a significant amount of power from the grid outside of the hours of 9am to 3pm, and therefore you are generating a significant amount of CO2 emissions. You may generate excess solar over and above what your home uses that you claim as an “offset” against power drawn from the grid. However, this may not always be the case as there are instances where rooftop solar is displacing large scale solar and wind as opposed to fossil fuels. The QLD, VIC and WA grids largely mimic NSW, while SA and TAS have a cleaner profile with higher amounts of renewable energy through the daily cycle. Enter the home battery Home battery storage lets you capture excess energy from your solar system, or charge from the grid when the grid is clean and cheap. This green, cheap energy is then used to power your home through the evening peak when the grid has it’s highest CO2 emissions and highest prices. If you have excess energy in your home battery then some retailers also let you export this to the grid to the evening peak to maximise your income or minimise your power bill. The NSW Government has launched a new rebate program to make installing a home battery even more affordable. This is a fantastic opportunity to boost your energy independence, save on bills, and contribute to a cleaner energy future. Here's the rundown on the NSW Home Battery Rebate:
Why should you consider a home battery? Home batteries allow you to store excess solar energy generated during the day and use it at night or during peak demand periods. This can significantly reduce your reliance on the grid and bring down your electricity bills. Additionally, batteries provide backup power in case of outages, keeping your lights and essential appliances on. Taking advantage of the rebate The rebate will be accessible through approved suppliers who will be accredited in the coming months. Keep an eye out on the NSW Government website for updates on accredited suppliers. Word of caution While the NSW Government's home battery rebate starts in November, there's an opportunity to get a good deal right now. Due to the five-month delay between the policy announcement and implementation, demand for batteries is currently low, meaning steeper discounts might be available. However, with a surge in demand expected come November, there's a chance of installation delays and price increases due to limited workers and materials. This could mean the full rebate amount might not translate directly to savings for you. So, if you're considering a home battery don't wait. You could potentially save more by shopping around now and enjoying immediate energy bill savings for the next six months.
Charged up and ready to role. So how do you fuel your EV dream financially? Read our guide to explore the different financing options to get you on your journey to low cost, low emission motoring.
One of the biggest myths surrounding EVs is that their battery packs will need frequent replacement. This is simply not true!! At the recent Everything Electric expo in Sydney, Robert Llewellyn caught up with Nigel Raynard of Byron Bay Luxury Tesla. Nigel has driven over 700,000 kilometres in his 2017 Tesla Model S.
The average Australian motorist covers 12,000 km per annum, which at this rate would give them a whopping 55 years’ worth of battery life!! The much-anticipated Tesla Powerwall 3 has just been released in the US. The Powerwall 3 is the latest version of Tesla’s home battery system.
This sleek, powerful battery system lets you store solar energy, gain independence from the power grid, and even provide power to your home during outages. What are the key similarities and differences to the Powerwall 2? Power storage and power output Both the Powerwall 2 and Powerwall 3 have 13.5 kWh of storage capacity. However, the power output of the Powerwall 3 is improved significantly increasing from 5 kW to 11.5 kW. While big loads will soon drain the battery, this does however mean you will avoid hitting the grid if you run multiple appliances concurrently e.g. the kettle, toaster and oven. Charging of the Powerwall 3 is limited to 5 kW like the Powerwall 2. In-built solar inverter Perhaps the biggest game changer with the Powerwall 3 is the integrated solar inverter allowing solar to be connected directly for high efficiency. The in-built inverter is rated at 11 kW meaning it can convert up to 11.5 kW of solar energy from your panels into usable electricity for your home. As the battery can also charge at 5 kW, the system has a total capacity of 16.5 kW. Under the Clean Energy Council rules in Australia, which state that panel capacity cannot exceed inverter capacity by more than 33%, the Powerwall 3 could potentially support up to 20 kW of solar panel capacity without the need to purchase a separate inverter. Price The Powerwall 3 is not yet available in Australia, however in the US it is priced similar to the Powerwall 2. This in effect represents a significant value add for the consumer given the built in inverter which could save thousands of dollars on the cost of an overall system. Compatibility Be aware, Tesla Powerwall 3 is not compatible with the Powerwall 2. As at the date of this article, Tesla has made no announcement to phase out the Powerwall 2. But if you are a Powerwall 2 owner and want to add more capacity then you should monitor any such announcements closely. Imagine going on a road trip and before your return journey you stop to fill up with petrol. Now instead of paying $2 per litre someone pays you for the petrol you put in your car, and this petrol burns clean emitting no carbon dioxide or carcinogenic compounds.
That’s the power of an EV combined with solar and Amber Electric. After arriving at a hotel I plugged my car in to charge at an Exploren charger, costing $0.33 per kWh. At the same time my solar and battery system is exporting power at an average rate of $0.46 per kWh. I set my car to charge at the same rate that my solar/battery exports; so green electrons are going into the grid at the same rate and same time that I am taking them out. So I’m in effect being paid to charge my car and the energy being used for driving is still 100% renewable. Even on a road trip you can still achieve no cost and 100% renewable driving 🙌 🚘 Congratulations on joining the EV Revolution! Here are some top tips to help you smoothly transition to your new vehicle:
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