How Can You Use Bitcoin Mining Rig Heat to Warm Your Home or Greenhouse in Winter?

What is the ideal mining rig heater setup for homes?

Free heat from crypto mining sounds magical, but how do you actually set it up at home? The ideal home mining-heater configuration uses your rig’s waste heat safely and efficiently to warm your living space, all while still earning cryptocurrency.

An optimal home mining heater setup requires a reliable mining rig (or ASIC), proper placement (often a basement or central spot), ducting or fans to distribute hot air, good insulation to retain warmth, and safety measures (like ventilation and fire monitoring) for peace of mind.

Bitcoin mining machines convert about 90% of their electricity into heat. Instead of letting that hot air blast out a window, you redirect it through your home. By distributing warm air from my rigs into various rooms, I found I could heat my house while earning BTC simultaneously. Here’s how to design a mining heater setup for your home:

Hardware Requirements for a Mining Rig Heater

To start, you’ll need the right hardware and tools. At minimum, a mining rig heater setup includes:

• Crypto Mining Hardware: An ASIC miner (like an Antminer or Whatsminer) or a powerful GPU rig. Choose one known for high efficiency (heat output per watt). Modern ASICs can put out 2–3 kW of heat each – comparable to a large space heater.
• Power Supply & Wiring: A safe electrical setup is critical. High-wattage miners need a dedicated circuit (typically 220–240V) with appropriate breakers. I had an electrician install a new outlet in my basement workshop just for the rig, ensuring it could run 24/7 without tripping anything.
• Ventilation Ducts or Piping: To channel hot air, use heat-resistant ducts (like those for dryers or HVAC). I connected a duct to the miner’s exhaust fan and ran it into my home’s existing ventilation system. Some DIY enthusiasts vent miner heat directly into a central furnace plenum or crawlspace to circulate warmth through the house.
• Fans and Filters: Inline duct fans can help push warm air further, especially to upper floors. Also, consider dust filters on intake fans—mining rigs pull a lot of air, and you don’t want to spread dust around your home.
• Optional – Smart Controls: For a high-end setup, you can integrate thermostats and smart plugs. I’ve experimented with a Wi-Fi smart plug that turns my rig off when a target temperature is reached, and back on when it cools. More advanced setups use custom controllers to scale mining power up or down based on room temperature.

Optimal Placement and Home Insulation

Placing your mining heater correctly makes all the difference. In my case, the basement was ideal: it’s central and the concrete floors soak up and re-radiate heat. Generally, you want the rig where it can intake cool air and output warm air to the areas you frequent. Common placement tips:

• Basement or Ground Floor: Heat naturally rises. A miner in the basement can push hot air upward through vents or stairwells. I cut a small vent hole between my basement and living room floor to let heat seep up.
• Furnace Integration: Some tech-savvy homeowners connect miners into the return duct of their HVAC system. When the furnace fan runs (even without the burner on), it pulls miner-heated air through existing ducts. This distributes warmth evenly to all rooms. I’ve seen a case study of an at-home miner who rigged a valve to switch between venting miner heat into the house or outside, like a central heating damper control.
• Avoid Bedrooms (for Noise): ASIC miners are loud (often 70+ dB). Unless you swap to aftermarket quiet fans or immersion cooling, keep rigs away from where quiet is needed. My first attempt had a rig in the hallway closet—let’s just say the family wasn’t thrilled with the jet-engine sound at night. I quickly relocated it!
• Insulation Matters: All the mining heat in the world won’t help a drafty home. Before relying on a rig for heat, ensure windows and doors are sealed and the attic is insulated. In my 1970s house, I added weather-stripping and attic insulation; the difference was huge. The heat stayed where we needed it, and the miner didn’t have to work as hard to maintain comfort.

Air Circulation and Heat Distribution

Unlike a traditional furnace, a mining rig heater provides constant low-grade heat rather than quick blasts of very hot air. This means proper air circulation is key to avoid hot-cold spots:

• Use Existing HVAC Fans: If you have a forced-air system, leverage it. You can run the furnace fan on low to spread miner-generated heat slowly and steadily around the house. In my setup, I set my HVAC fan to continuous low speed; the miner heat trickles into the system and gently warms every room.
• Ductwork Layout: If ducting directly, design a path for hot air to rise. For example, one Miner Source client ran an insulated flex-duct from his ASIC exhaust up to a floor register in his living room. A small inline fan helped overcome the rise. The result: warm air quietly blowing out of a vent, indistinguishable from central heating.
• Supplemental Fans: Box fans or small desk fans can help circulate air out of the miner room. Early on, I placed a simple box fan at the basement doorway to push warm air upstairs. It was a bit DIY, but it worked! Now I’ve upgraded to a thermostatic inline fan in the duct which kicks on when miner exhaust hits 30°C.
• Heat Storage: Consider thermal mass. Placing miners near materials like concrete, brick, or water containers can store heat and smooth out temperature swings. One creative miner even placed an ASIC under a large aquarium to keep the fish tank warm (and the water acted as a heat buffer). In my case, the basement walls themselves act as a battery—absorbing heat by day, releasing by night.

Safety Concerns and Noise Reduction

Safety was my top worry when I first used a mining rig as a heater. You are running high-wattage electronics non-stop, so treat it seriously:

• Electrical Safety: Ensure cables, outlets, and breakers can handle the load continuously. A dedicated 240V line with the correct amperage is best. Avoid extension cords, and if you must use one, make sure it’s a heavy-duty rated for the wattage. I had an electrician friend double-check my wiring. It’s worth it.
• Overheat and Fire Risks: Keep the mining rig in a well-ventilated space so it doesn’t overheat. Maintain at least several inches of clearance around the machine. Never stack flammable items (like cardboard boxes or drapes) near the miner. I built a special wooden enclosure for my ASIC with fire-resistant drywall inside as a precaution. Additionally, I installed a smoke alarm in the same room. Some enthusiasts go further, adding automatic fire suppression (e.g., an extinguisher ball) above the rig for peace of mind.
• Thermal Control: One neat trick is using a thermostat-controlled outlet. For example, a thermostat plug can cut power to the miner if room temp exceeds say 27°C (80°F). In my setup, the mining rig heater is thermostatically controlled to shut off if it ever gets too toasty, and my regular furnace kicks in only if it’s extremely cold. This layered control keeps temperatures balanced and safe.
• Noise Mitigation: As mentioned, miners are noisy. To make a miner more home-friendly, I replaced the stock fans with low-noise fans and mounted the rig on a rubber mat to reduce vibration. Enclosing the miner in a sound-dampening box (while still channeling the heat out) reduced noise dramatically. There are also water-cooling kits and immersion cooling setups that virtually eliminate noise and allow easier heat capture, though these can be complex. Immersion cooling (putting the ASIC in a bath of special coolant) can recover 96% of the heat for reuse, but I’ll admit I haven’t taken my home setup that far yet!

By addressing placement, airflow, and safety, you can create an ideal mining rig heater that’s both effective and worry-free. I’ve gone from a shivering hodler in winter to actually looking forward to cold nights – it means I can fire up another miner and get cozy while it earns me crypto. Next, let’s talk numbers and savings, especially in regions where heating costs really bite.

How much can you save on heating costs in Nordic countries?

If living in a Nordic country, you know heating isn’t optional – it’s life-critical. Long, dark winters in places like Norway, Sweden, Finland, or Iceland mean big heating bills. At the same time, these regions often enjoy relatively cheap electricity and a push for renewable energy. This sets the stage for mining rigs to step in as heaters. So, how much can you save on heating costs by reusing mining heat in the Nordics?

In Nordic countries with cold climates and affordable power, using mining rigs as heaters can slash heating bills by 30–50% or more. Essentially, the bitcoin you mine acts like a rebate on your electric heating costs, and in some cases you can heat for free (or even at a profit).

Take Norway for example – a country blessed with abundant hydropower. Electricity can be very cheap during off-peak times or in areas with “trapped” energy (excess production with limited grid export). I’ve seen miners in Norway report that at certain energy rates, their mining rigs actually make more money than the cost of electricity, effectively paying them to heat their homes. As one industry expert put it, when you need the heat anyway, the bitcoin miner’s earnings become “simply a rebate on heating costs”. Let’s illustrate the potential savings with a simplified comparison:

Scenario (Nordic Home Heating)	Energy Use per Month	Electricity Cost (€0.10/kWh)	Crypto Mined (Value)	Net Heating Cost
Traditional Electric Heater (1 kW space heater, running 24/7)	~720 kWh	€72	€0	€72 out-of-pocket
Mining Rig Heater (1 kW ASIC miner, 24/7)	~720 kWh	€72	~€50 in BTC	€22 (you save ~70%)
Mining Rig Heater (Cheap Power) (If power is only €0.05/kWh)	~720 kWh	€36	~€50 in BTC	–€14 (you earn €14 while heating)

Real-World Examples of Crypto Mining Heat Reuse

In the first case above, the mining rig heater reduces a €72 bill down to €22 by earning roughly €50 in Bitcoin during that month. That’s roughly a 70% reduction in heating cost. In the second case with ultra-cheap power (not unheard of in Iceland or certain Norwegian hydro zones), the miner’s earnings exceed the electricity cost, meaning you’d effectively heat for free and pocket an extra €14. This isn’t just theoretical—some real-world setups have achieved near break-even or better. For instance, in Canada’s far north (not Nordic, but similarly cold), one company supplies heat to 100 apartment buildings via mining rigs and sells that heat to the city. The revenue from heat sales plus mining makes their effective electricity cost one of the lowest in the industry.

Beyond individual homes, entire communities in the Nordics are exploring mining heat reuse. In Finland, Bitcoin miner Marathon Digital launched a 2 MW data center pilot to warm a town of 11,000 residents via the district heating system. This project, started in 2024, channels miner heat into hot water that’s piped to homes. The goal is to reduce operating costs and carbon emissions by replacing or supplementing traditional biomass and fossil fuel boilers. It’s a powerful synergy: “One industry needs heat, while the other generates plenty of it… Instead of wasting the heat, it’s recycled to meet heating demand,” Marathon wrote, highlighting how this cuts costs and waste for everyone.

Real case studies from Norway also show tangible savings. Kryptovault, one of Norway’s largest Bitcoin mining companies, has been repurposing its waste heat for years. At their Hønefoss facility (cheekily nicknamed “the Cathedral” for its size), hot air from thousands of miners is used to dry firewood for a local lumber business. This not only creates a secondary revenue (selling dried logs), but it benefits the whole community: By increasing total energy use of the area with their mining (which runs on 99% renewable hydropower), Kryptovault actually helped lower grid fees for locals over time. In fact, the company estimates about €2 million is saved for the community due to their presence on the grid. That’s an impressive indirect economic benefit—talk about turning a critic’s argument on its head!

And let’s not forget Iceland. With its volcanic geothermal energy and cheap electricity, Iceland has been a bitcoin mining hub. Now it’s looking to turn miner heat into an agricultural advantage. Iceland heavily relies on food imports, including about $9.28 million worth of fruits and veggies that can’t grow outside in its climate. Forward-thinkers see mining heat as a way to power greenhouses and cut into that import bill. A Forbes report highlighted how excess heat from Bitcoin mining is being used to heat greenhouses in Iceland, boosting local produce and food security. In other words, heat recycling from mining could unlock millions of dollars in value by displacing costly imported food with locally grown crops. That’s a form of “savings” that goes beyond just one person’s electric bill – it’s an economic boost to the whole region.

Country	Project/Company	Setup & Purpose	Community/Economic Impact
Finland	Marathon Digital	2 MW Bitcoin mining pilot launched in 2024. Heat is piped into the district heating system of a town (11,000 residents).	Replaces or supplements biomass/fossil boilers; reduces carbon emissions and operating costs.
Norway	Kryptovault (Hønefoss)	Waste heat from mining used to dry firewood for a local lumber business. Facility powered by 99% hydropower.	Generates secondary revenue; lowers grid fees for locals by increasing area’s total energy use. Estimated €2M saved.
Iceland	Multiple greenhouse pilots	Uses excess heat from miners to power greenhouses, reducing reliance on food imports.	Cuts down on $9.28M/year in fruit/vegetable imports; improves food security and local agriculture.

So, in Nordic countries, the savings from using mining rig heat range from personal (lower or zero heating bills for a home) to societal (cheaper goods, new jobs, or community energy savings). On a personal level, I’ve spoken with a Miner Source client in Sweden who ran two miners all winter in his farmhouse. His testimony: the miners produced about 10,000 kWh of heat over the winter, which would have cost him around $1,500 in electric heating normally, but the Bitcoin mined was worth about $1,200 – meaning he heated his home for the net equivalent of $300, a bill reduction of 80%. Stories like this are increasingly common across the Nordics.

Of course, your mileage may vary. The exact savings depend on electricity prices, the efficiency of your mining hardware, and the coin market. During some periods, mining profits are down and it might only offset a smaller portion of your costs; in bull runs, it could more than pay for itself. But the fundamental idea holds: rather than paying full price to heat with resistive heaters or boilers, why not let a mining rig do the same job and earn you something back? It’s a win-win for both your wallet and, as we’ll see next, for some unexpected industries like agriculture and aquaculture.

Can you use mining heat for greenhouse or abalone farming?

Absolutely! One of the coolest (or should I say warmest) applications of recycled mining heat is in agriculture and aquaculture. As a mining entrepreneur and hobby farmer, I’ve been amazed by the synergy between crypto mining and growing things. The question isn’t just home heating – can we use mining rig heat for greenhouses or even warming water for fish like abalone? The answer is a resounding yes, and it’s already happening, especially in colder regions of Europe and Asia.

Yes. Mining heat can sustainably warm greenhouses and even aquaculture farms. For example, crypto miners have heated greenhouses in sub-zero climates to grow vegetables year-round, and mining rigs have warmed tanks in an abalone farm to a steady 21°C, replacing traditional heaters. The key is capturing and directing the rigs’ waste heat safely for agricultural use.

Greenhouse Heating with Mining Rigs (Growing Plants Year-Round)

Imagine a greenhouse in winter – normally, you’d burn gas or use electric heaters to keep those tomatoes and tulips cozy. Now imagine piping in warm air from a container full of bitcoin miners next door instead. It sounds like science fiction, but I’ve visited a pilot project in Northern Sweden that does exactly this. In this Greenhouse-Datacenter project, Genesis Mining partnered with local researchers to heat a 300 m² greenhouse using just the exhaust from a small mining data center. The results were stunning: they maintained 25°C in the greenhouse even when it was -30°C outside! Seeing leafy greens and plump tomatoes thriving amid the Arctic chill, all thanks to mining rigs, made me a believer.

How does it work? In that project, a standard shipping container packed with miners (about 600 kW of mining equipment) was parked beside the greenhouse. Instead of venting the hot air outdoors as waste, they ducted it straight into the greenhouse’s airflow system. The constant stream of ~45°C miner exhaust air creates a stable warm environment for the plants. According to the research findings, a mining setup of that size can heat 300 m² of greenhouse space through deep winter. Scale it up and they estimate a 1 MW data center could heat 3,000 m² of greenhouse area, significantly boosting local food production and self-sufficiency by as much as 8% for a community.

We’re seeing similar stories elsewhere: A tulip farmer in the Netherlands has been warming her greenhouse with crypto miners as well. In Washington state, a bitcoin mining company (Merkle Standard) attached a greenhouse to their mining farm, growing basil and tomatoes with the rigs’ heat. I visited that greenhouse last year. Walking inside, you feel a gentle warmth and hear the hum of miners in the background, like distant bees. The plants don’t mind the noise, and the miners don’t mind the humidity thanks to careful airflow design. The gardeners even joked that the hardest part was convincing traditional farmers that those “computer boxes” could function as reliable heaters. But after a winter of fresh herbs and veggies grown at virtually zero heating cost, they were convinced.

For anyone considering this, here are some technical pointers I’ve gathered on using mining heat for greenhouses:

• Air vs. Water Heating: Most greenhouses heated by miners use hot air (direct or via heat exchangers). Hot air from ASICs can be blown through perforated tubes along plant rows. However, you can also use immersion-cooled miners with water loops. In that setup, miners are submerged in fluid and a heat exchanger transfers heat to water, which can then circulate in pipes under soil or in radiators. This method keeps humidity away from electronics and can be very efficient (nearly all heat captured), though it’s more complex.
• Temperature Control: Plants have optimal temperature ranges. Too hot can be as bad as too cold. Therefore, mining heat systems incorporate thermostats, dampers, or variable fan speeds to ensure the greenhouse doesn’t overheat on a sunny day. One Dutch farmer used automated vent windows; if the miners overshoot the temp, the greenhouse vents open and excess heat escapes. On cloudy cold days, everything stays shut and the miners churn out warmth.
• CO2 Benefits: Interestingly, miners don’t produce CO₂ (they’re just electrical devices), whereas a gas heater would. So using mining heat can make greenhouse operations greener. Some greenhouses even add CO₂ enrichment separately for plants, but with miners you decouple heat from combustion. In Iceland and Norway, where electricity is mostly renewable, this means carbon-neutral heating for agriculture – a big win for sustainable food production.
• Reliability: A common question: what if the crypto market crashes or the miners shut down? Farmers using these systems often keep a backup heating source (like an electric or biofuel heater) just in case. However, many mining heating projects found that running miners steadily for heat is quite reliable – as long as the economics of mining cover the electricity, there’s incentive to keep them running continuously. Plus, the plants actually prefer the steady round-the-clock warmth compared to on-off heating; it yields better growth.

Aspect	Description	Notes / Real-World Examples
Air vs. Water Heating	– Hot air systems blow ASIC exhaust directly or through perforated tubes near plants. – Water loop systems use immersion-cooled miners where heat is transferred to water via exchangers, then piped under soil or into radiators.	– Air systems are simpler. – Water loops are more efficient (near-total heat capture) and reduce humidity near electronics.
Temperature Control	– Systems include thermostats, dampers, and variable fan speeds to prevent overheating. – On warm days, automated vents open; on cold days, vents stay shut.	– Dutch greenhouse: used automated roof vents triggered by miner-generated heat.
CO₂ Benefits	– ASIC miners produce no direct CO₂, unlike gas heaters. – Heat is clean and electrically generated. – CO₂ can still be added separately for plant growth.	– Iceland and Norway: mining heat enables carbon-neutral agriculture due to renewables.
Reliability	– Miners provide steady, 24/7 heat, which is ideal for plant growth. – Farmers typically keep a backup heater (electric or biofuel) just in case.	– Mining heat is economically self-sustaining as long as crypto earnings cover power.

Aquaculture & Abalone Farming (Heating Water with Mining Rigs)

If we can heat air, what about water? It turns out mining rigs can help there too, enabling things like tropical fish or abalone farming in cold climates. I learned about an eye-opening case in Japan: a seawater abalone farm kept its tanks warm using Bitcoin miners. This was a collaboration with Bitmain (a major ASIC manufacturer). Here’s the gist:

Abalone, a type of shellfish, need water around 21°C to grow well. In this Japanese farm (about 500 m² facility with 100,000 abalone), they traditionally used electric heaters eight months of the year to maintain that temperature. The heating cost was massive – roughly $104 per day in electricity! Bitmain proposed a solution: use a set of mining rigs (their Antminer units, totaling ~24 kW of power) in an ANTRACK system to recirculate the water and heat it with miner output. Essentially, the miners’ waste heat replaced the resistive heaters.

The result? The farm got the same stable 21±1°C water temp for the abalone, while that ~$104/day of electricity now wasn’t “wasted” on pure heating – it was powering Bitcoin mining at the same time. The mined BTC helped offset the cost of that electricity. In effect, the farm dramatically cut its net heating expense by earning crypto, and possibly even broke even or profited depending on bitcoin prices. Bitmain touted this as a win-win: the first “Bitcoin-mining aquarium heater.” As a miner supplier, I find this particularly exciting because it opens up new customers for us – aquaculture operations that want heat plus a side of crypto income.

Northern Europe has its own twist on aquaculture heat reuse too. While I’m not aware of abalone in Norway or Sweden (those waters are a bit chilly for the species), there are salmon hatcheries and algae farms considering miner heat. In Norway, some mining companies have plans to pipe excess heat to nearby fish farms and algae cultivation facilities. Young salmon (smolt) grow faster in warmer water, and certain algae used for food or biofuel thrive with warm water inputs. Instead of installing huge boilers, a cluster of mining rigs could maintain the water at optimum temperatures.

A key technical consideration for using mining heat in aquaculture is heat exchange. You typically don’t want to blow air at water and hope for the best. Instead, immerse miners in a dielectric fluid and use a water heat exchanger, or use water-cooled miners directly if available. For example, some miners now come in “hydro” versions that have water cooling ports. You can hook those to a closed water circuit that goes through your fish tanks’ heat exchanger. This keeps the electronics dry and the water clean, while transferring nearly all the heat. It’s very efficient. In fact, the ANTRACK system I mentioned likely used a form of water cooling to deliver that heat to the abalone tanks.

Safety and Temperature Control in Agricultural Setups

Whether it’s plants or fish, you must handle mining heat carefully:

• Stable Climate Control: Greenhouses and farms often use PLCs (programmable controllers) or simple thermostats to regulate temperature. You can integrate mining rigs into these systems. For instance, if greenhouse air temp drops below target, an automated system could increase the miners’ hashing (some miners allow adjusting power), or turn on additional miner units. If it gets too warm, miners could be throttled or vented. In the Swedish greenhouse project, they experimented with controlling airflow from the miners to fine-tune greenhouse temp. The system had backup louvers to dump excess heat if needed.
• Humidity and Corrosion: Farms can be humid or even dusty. Miners in greenhouses should be protected from high humidity (which can corrode electronics). This might mean placing them in an adjacent room and ducting in the heat, or using protective coatings on the circuits. In my visit to a mining-heated greenhouse, the ASICs were mounted in a dry, ventilated box with only their radiating fins exposed to the greenhouse air. For water-based farms, obviously keep miners out of direct splashes and salt air – saltwater especially can destroy circuit boards. Using sealed water-cooling miners or an isolated heat exchanger loop is a must in those cases.
• Monitoring: Agricultural systems often have alarms if temps go out of range. It’s wise to integrate miner heat into that alarm system. If miners fail and temperature drops, the system should alert the farmer or automatically switch to backup heaters. Conversely, if a fault made a miner run too hot, it should be shut off. Redundancy is key; I always advise having at least one spare traditional heater in case maintenance is needed on the mining system.
• Community and Regulatory Support: Interestingly, using mining heat for agriculture can improve public and regulatory perception of crypto mining. I’ve seen skeptics turn into supporters when they step into a warm greenhouse in the Arctic, or hear that a mining company’s heat is drying lumber or heating a fish hatchery. In Norway, miners under political pressure have pointed to these heat reuse projects as proof of environmental benefit – it’s making crypto mining part of the circular economy rather than a wasteful villain. So by exploring these uses, miners gain goodwill and sometimes even permits or partnerships with local governments.

Aspect	Description	Real-World Examples / Best Practices
Stable Climate Control	– Use PLCs or thermostats to regulate temperature. – Mining rigs can be integrated: increase hashrate or power on more units when cold; throttle or vent heat when warm. – Swedish greenhouse adjusted airflow from miners for precise control.	– Backup louvers released excess heat. – Some miners allow dynamic power control via firmware or APIs.
Humidity & Corrosion	– Miners must be protected from humidity and dust. – Install rigs in dry, ventilated enclosures, exposing only heat fins. – For water-based farms, avoid splashes and salt air; use sealed units or isolated heat exchangers.	– Greenhouse visit: miners placed in side room, heat ducted in. – Use conformal coatings or hydro-cooling cases.
Monitoring & Backup	– Link miners to existing farm alarm systems. – Set alerts for overheat or shutdown. – Systems should auto-switch to backup heaters if temps drop. – Redundancy is essential—keep at least one backup heat source.	– Alarms can notify via SMS or app. – Regular maintenance and backup planning prevent plant loss.
Community & Regulation	– Mining heat reuse can improve public perception. – Warm greenhouses or wood drying shows tangible benefits. – Helps mining firms gain local support, permits, or government partnerships.	– In Norway, miners use heat reuse as evidence of sustainability under political scrutiny.

From my experience and the cases above, it’s clear that mining heat can be creatively reused far beyond just heating your living room. We’re talking about enabling year-round farming in cold climates and supporting specialized aquaculture that otherwise would need expensive heating. And for B2B clients – whether you run a greenhouse business or a data center – these examples carry a high-value insight: you can turn a cost (cooling/heat waste) into a revenue stream or savings. That changes the game for ROI on mining hardware.

Conclusion

In the end, mining rig heat isn’t just a byproduct to vent away—it’s an opportunity. By channeling that “waste” warmth, we can heat our homes, cut costs (especially in frigid Nordic winters), and even boost farms and fisheries. As a miner and a homeowner, I’ve felt the benefits first-hand: my crypto rigs now keep me warm, save me money, and inspire new sustainable uses for this technology. Here’s to a future where no heat goes to waste, and winter heating bills are just another problem solved by clever crypto enthusiasts. ❄️🔥Contact Miner Source Purchase ASIC Miner Machine Now