Why Choose an Electric Boiler Supplier?
Electric boilers can be powered by renewable energy sources and can easily be integrated with energy storage technology. This reduces a business’s reliance on fossil fuels and makes them less vulnerable to energy price fluctuations.
Manufacturer of standard and high pressure electric steam, hot water and specialty boilers. Serves chemical, breweries, utilities and food processing industries. UL & ASME certified.
Energy Efficiency
With their reliance on electrical power, electric boilers are more energy efficient than gas boilers. Electric heating systems also produce fewer greenhouse gases (GHG) and air pollutants than their fuel-fired counterparts. This combination of efficiency and sustainability is driving many manufacturing facilities to consider switching from traditional fossil-fuel boilers to high-efficiency, low-emission electric steam or hot water boilers.
The energy used to operate an industrial electric boiler supplier comes from the local power grid, which can be powered by fossil fuels or renewable energy sources such as solar, wind, hydroelectric, and biomass. The energy usage of an electric boiler can electric combi boiler suppliers be further reduced through the use of smart thermostats, which adjust settings based on occupancy and weather conditions to ensure the heating system only uses energy when needed.
Industrial facilities are rethinking their energy systems in the wake of rising natural gas prices and a need to accomplish high-priority corporate climate change mitigation goals. Electrifying industrial process heating is a critical strategy for decarbonizing industry, which remains heavily dependent on fossil fuel combustion and accounts for the majority of sector wide GHG emissions. However, gaps in our understanding of the current population of conventional industrial boilers across the United States prevent a full evaluation of the potential for fuel savings and GHG reductions from boiler electrification. This research addresses those gaps by assembling facility-level equipment, fuel use, and emissions data from publicly available yet non-standardized data sources.
Safety
With advanced electrode boiler technology, these units dramatically reduce the risks associated with combustion-fueled systems that can emit toxic vapors and cause explosions or fires. They eliminate the need for field piping and oil tanks and can be much smaller in footprint. They can also save companies money by bypassing the need for costly permits.
Boiler design, manufacturing and installation services provided. Products include once-through steam, water, chemical, fuel and rental boilers. Various features such as electric Incoloy elements, pre-piped feed water pump, front mounted control panel casing, splash proof electrical enclosures and switches are offered. Suitable for industrial processing, laundry/dry cleaning, food/drink, laboratory, research and humidification applications. Meets BSI standards.
EHC specialises in electricity heating, hot water and cooling for homes, offices, hotels, restaurants, schools, hospitals and many other buildings. Products include electric system boilers, ecoSave Wi-Fi ready electric heaters and solar PV ready cylinders.
An electric system boiler is a heating appliance that is supplied by a dedicated circuit. They must not be powered from the ring main, as this can overload the circuit and is a dangerous fire hazard. It should be connected to its own MCB, which is sized to withstand the maximum current draw of the boiler. Ensure that you use a qualified heating engineer or electrician when installing an electric boiler, and never try to connect it to a ring main.
Less Maintenance
Unlike other boiler varieties that depend on the combustion of coal, wood, or oil to produce heat, electric boilers use resistance elements to create steam and hot water. This type of equipment does not produce harmful emissions, making it more environmentally friendly. Compared to fuel-fired boilers, electric heaters require less maintenance and upkeep.
An electric boiler consists of a tank that contains the steam and a heating element. Whenever an electric current passes through the heating element, it produces heat that is transferred to the water in the tank. The water electric tankless boiler is then heated to the saturation temperature, which produces steam for various industrial applications.
Electric boilers are compact and can be placed in a variety of locations within a facility. They do not require field piping or oil tanks and are much easier to install than fuel-fired boilers. They also do not produce carbon monoxide, which eliminates the need for a flue system.
Choosing the right size electric boiler is critical for optimal heating efficiency. A qualified professional should install the equipment according to manufacturer guidelines and local regulations to ensure safety. Additionally, it is important to regularly check and maintain the boiler for any potential problems. This can include ensuring proper water chemistry, keeping the boiler clean, and adjusting the electrical connections.
Less Emissions
Unlike fossil fuel boilers, electric boilers do not emit gases such as carbon dioxide (CO2), methane (CH4), nitrous oxide (NOx), volatile organic compounds (VOCs), sulfur dioxide (SO2), and particulate matter. The electricity used to power electric boilers also does not produce these gases, which is why they are a more eco-friendly alternative.
However, the emissions associated with generating the electricity that powers electric boilers can still be significant. This is because coal, natural gas, and nuclear power plants produce emissions such as CO2 during their production process. This is in addition to other fossil fuels that are burned to produce the energy required for industrial steam generation.
This research aims to fill in key knowledge gaps on the potential fuel and GHG emission savings from the electrification of industrial boilers in the United States. To accomplish this, the study developed an up-to-date industrial boiler population dataset that characterizes boilers by county and manufacturing subsectors. It then models the effects of boiler electrification on emissions using two theoretical electric grid scenarios: one based on current electric grid assumptions, and the other with a high share of renewables. This analysis demonstrates that even with current emissions intensity in the electricity supply mix, there are many counties where boiler electrification would lead to GHG reductions. In these counties, incorporating energy efficiency measures into steam demand could further improve the investment economics of boiler electrification.