S.B.G - CIG Cleaners
S.B.G - CIG Cleaners
Residential + Commercial & General
In-House VS External
DAILY - WEEKLY - MONTHLY - QUARTERLY
Like a good rodent run & bowls to trap & monitor with air flow then climate controls safe air & ground then materials required with utilizing partial automated systems
In process.
1. Take items out
2. Use (safely for desired & intended purpose)
3. Clean
4. Put items away
Simple. Organized Point A - B
The NB-OT Labs & expansion Labs like other outside intervening distractions are void & isolated using legal & ethical practices to void safety concerns
Superficial. Efforts for image. Appearance. Health. Environment. Safety
EMERGENCY SAFETY PROCEDURES
The Evil Muster Emergency Meeting Point & Sirens + Codes
https://www.energysafetycanada.com
Advanced medical first aid procedures
EXTERNAL INDUSTRY REFERENCE
Environmental Benefits
Natural cleaning products are biodegradable and come in recyclable packaging, meaning they break down more quickly and don't contribute to long-lasting pollution. This reduces the chemical load on waterways, soil, and air.
Sustainable Ingredients
Most natural cleaning products are made from sustainable resources and don't rely on petrochemicals, making them a more eco-friendly choice regarding raw materials.
Fewer Antimicrobial Substances
• Plant-Based & Eco-Friendly: Their entirely plant-based products are a step towards eliminating plastic from kitchens. They're compostable, biodegradable, and lack the harmful chemicals commonly found in liquid dish soaps, which harm aquatic ecosystems.
We reference a list of 14 toxic ingredients commonly found in cleaning products. In cleaning solutions, we avoid ingredients such as 1-4 dioxane, MEA/DEA/TEA, formaldehyde, benzyl acetate, nonylphenol ethoxylates (NPEs), ammonium sulfate, fragrance/parfum, triclosan, coal tar dyes, phosphates, SLS and SLES, trisodium nitrilotriacetate, and quaternary ammonium compounds (Quats).
Instead, we champion brands that use biodegradable and septic-safe formulations without these harmful elements.
Vegan & Cruelty-Free
It's not just about being eco-friendly but also ethical. We prioritize products that don't contain any animal ingredients or derivatives. Equally, we don't support brands that test on animals. However, we provide information on products that might contain elements like milk, beeswax, or wool, ensuring they are ethically sourced.
Palm Oil-Free
The production of palm oil has significant environmental and ethical implications. Hence, we lean towards brands that sidestep this ingredient.
Ethical Sourcing
Beyond the ingredients, knowing how and where they're sourced is essential. We respect brands that ethically source their ingredients, preferably from nearby locations, and provide transparency about their sourcing practices.
Packaging Matters
The environmental impact of a product doesn't end once it's used up; its packaging has a legacy too. We're passionate about supporting brands that opt for compostable, reusable, or at least recyclable packaging.
We emphasize materials like glass, cardboard, and aluminum over plastics. When plastic is unavoidable, we ensure it's of the type that's most likely to be recycled, like PET, and encourage everyone to recycle it properly.
How to spot toxic ingredients in your cleaning products?
Silica powder — Found in abrasive cleaning powders. A known carcinogen that is harmful when inhaled.
Sodium dichloroisocyanurate dihydrate — Found in toilet bowl cleaners, deodorizers, surface cleaners, and disinfectants. High doses can cause kidney issues, very toxic to aquatic life.
Sodium hydroxide (also known as lye and caustic soda) — Found in oven cleaners, bathroom cleaners, disinfectants, drain openers, and toilet bowl cleaners. Highly corrosive, it can burn the eyes, skin, and lungs, and is a respiratory irritant.
Sodium lauryl sulfate (SLS) and sodium Laureth sulfate (SLES) — Found in dish soap, liquid laundry detergents, cleaning towelettes, and toilet bowl cleaners (as well as sudsy cosmetics). Traces of 1-4 dioxin have been found, a possible human carcinogen.
Triclosan is found in dish soaps, disinfectants, and various other household products. Look for it listed as an "active ingredient" in antibacterial products. Endocrine disrupts and hormone mimickers. Also affects water life and ecosystems.
Trisodium nitrilotriacetate — Found in bathroom cleaners and possibly some laundry detergents (more common in industrial formulations). Possible human carcinogen and linked to metals found in fish and other wildlife.
Fewer Antimicrobial Substances
Overuse of antimicrobial substances in household products can lead to antibiotic-resistant bacteria. Natural cleaners usually avoid these substances, promoting a healthier microbial balance in our homes and the wider environment.
Sustainable Ingredients
Most natural cleaning products are made from sustainable resources and don't rely on petrochemicals, making them a more eco-friendly choice regarding raw materials.
Sustainable Ingredients
Most natural cleaning products are made from sustainable resources and don't rely on petrochemicals, making them a more eco-friendly choice regarding raw materials.
Environmental Benefits
Natural cleaning products are biodegradable and come in recyclable packaging, meaning they break down more quickly and don't contribute to long-lasting pollution. This reduces the chemical load on waterways, soil, and air.
Better Indoor Air Quality
Synthetic cleaners often release volatile organic compounds (VOCs) into the air, leading to indoor air pollution.
Health and Safety
Many conventional cleaning products contain chemicals that can be harmful if inhaled or touched. Natural products are typically free from these toxic substances, reducing risks of allergies, chemical burns, respiratory problems, and other health issues.
Cleaning Products
https://theecohub.com/5-canadian-natural-cleaning-products-for-the-eco-conscious-home/
PERSONAL PROTECTIVE EQUIPMENT
Respiratory
Skin + oral
Audible hearing
Skull - helmet
Eyewear
Physical - wearable for muscle fatigue + strain
STAINLESS STEEL
Zero Emissions & Zero Cycle or close to Steel manufacturing & repurposong is required on a mass scale
Stainless steel production is a multi-step process that begins with melting raw materials, removing carbon, tuning the composition, forming the metal, and finally finishing. This process ensures the steel's strength, corrosion resistance, and desired properties for various applications.
Steel is a dense material, with a typical density of around 7850 kg/m³. This means that one cubic meter of steel weighs approximately 7850 kilograms. The mass of a specific amount of steel can be calculated by multiplying its volume by its density. For example, a steel plate with dimensions 6m x 1.51m x 9.75mm has a mass of approximately 693.43 kg, according to Quora.
Here's a more detailed explanation:
• Density:
Steel's density is a key property that determines its mass for a given volume. The most common density for steel is around 7850 kg/m³.
• Calculating Mass:
To find the mass of a steel object, you need to know its volume and its density. The formula is: Mass = Volume x Density.
• Example:
If you have a steel block with a volume of 0.5 m³, its mass would be 0.5 m³ * 7850 kg/m³ = 3925 kg.
• Factors Affecting Density:
The density of steel can vary slightly depending on the specific type of steel (e.g., mild steel, stainless steel) and its manufacturing process (hot-rolled, cold-rolled), notes Ulma Forged Solutions. However, the variation is usually within a relatively narrow range around the typical 7850 kg/m³.
Here's a more detailed breakdown:
1. Melting and Casting:
• Iron, chromium, nickel, and recycled steel are melted in a furnace at high temperatures (around 2,800°F or 1,538°C) for 8-12 hours, according to Huron Alloys.
• This molten mixture is then cast into various forms like slabs, billets, or blooms.
• Continuous casting is a common method where molten steel is poured into a water-cooled mold, solidifying into the desired shape, explains AZoM.
2. Refining:
• Excess carbon is removed to prevent brittleness and maintain the steel's bendability, says Huron Alloys.
• Argon and oxygen are used to remove impurities and create slag, which is then removed.
• Alloying elements like chromium, nickel, or molybdenum are added to achieve specific grades of stainless steel (e.g., 304, 316).
3. Forming:
• Hot and cold rolling are used to shape the steel into desired forms like sheets, plates, bars, or wires.
• Hot rolling refines the grain structure and improves mechanical properties.
• Cold rolling achieves precise thickness and enhances the surface finish.
4. Finishing:
• Descaling (pickling) removes the oxide scale that forms during heating, according to Unified Alloys.
• Heat treatment (annealing) relieves internal stresses and enhances ductility.
• Various surface finishing techniques (e.g., brushing, polishing) are used to achieve the desired texture and appearance.
https://youtube.com/shorts/m14ngd_ZESE?si=yZhZPRjImD93DBFc
INDUSTRY STANDARDS
Zero Emissions & Zero Cycle or close to Steel manufacturing & repurposong is required on a mass scale
Stainless steel is highly recyclable and is frequently repurposed into new products. This includes everything from kitchenware and appliances to construction materials and even parts for aircraft. Due to its durability and corrosion resistance, it's a valuable material for a circular economy.
How it's repurposed:
• Scrap Collection:
Stainless steel scrap is collected from various sources, including old appliances, industrial equipment, and construction sites.
• Melting and Refining:
The scrap is sorted, cleaned, and melted down in a furnace.
• Alloying:
Essential elements like chromium, nickel, and molybdenum are added to the molten metal to achieve the desired properties.
• Casting and Processing:
The molten stainless steel is then cast into various forms, like slabs or billets, and further processed into new products.
Common uses for recycled stainless steel:
• New stainless steel products: The most common use is to create new stainless steel items, such as kitchenware, appliances, and construction materials.
• Other metals: It can also be used to create carbon steel and other ferrous alloys.
• Castings and forgings: Recycled stainless steel can be used in the creation of castings and forgings for various applications.
Benefits of recycling stainless steel:
• Conserves resources: Recycling reduces the need to mine new materials.
• Reduces energy consumption: Recycling requires less energy than producing virgin stainless steel.
• Minimizes waste: Recycling keeps valuable materials out of landfills.
• Environmentally friendly: It helps reduce greenhouse gas emissions associated with mining.
REGULAR STEELS
Unfortunately elements & oxygen takes a toll after time so wrapping & substances to are required to acheive close to stainless effects & sustainability
CONCRETE ALTERNATIVES
In minimizing Co2 Emissions & Co2 Capture alternatives for reinforced concrete
Concrete, while strong and durable, can have a significant environmental impact. Fortunately, there are many alternatives available, ranging from eco-friendly options to more traditional materials. These include hempcrete, ferrock, recycled plastic concrete, timbercrete, mass timber, and even less traditional materials like gravel or brick.
Here's a more detailed look at some options:
Eco-Friendly Alternatives:
• Hempcrete:
Made from hemp hurds, lime, and water, hempcrete is a lightweight, breathable, and sustainable material.
• Ferrock:
A carbon-negative material, ferrock uses waste steel dust and ground silica glass, potentially offering greater strength than traditional concrete, according to Bricsys.
• Recycled Plastic Concrete:
Incorporates recycled plastic waste, reducing landfill waste and offering a durable construction material.
• Ashcrete:
A mixture of fly ash (a coal combustion byproduct), lime, and water, ashcrete offers a sustainable option while repurposing waste materials.
• Timbercrete:
A concrete alternative that incorporates sawdust, making it lighter and more sustainable than traditional concrete, according to Fox Blocks.
• Mass Timber:
Engineered wood products like cross-laminated timber (CLT) offer a strong, lightweight, and aesthetically pleasing alternative, says Autodesk.
Other Materials:
• Gravel:
A cost-effective and versatile option, especially for driveways and walkways.
• Brick:
Offers a classic look and can be durable with proper maintenance.
• Cobblestone:
A more labor-intensive and expensive option, but provides a unique aesthetic.
• Asphalt:
While not as environmentally friendly as some alternatives, asphalt is a common choice for driveways and can be recycled.
• Fiber Cement:
A durable material that combines Portland cement, water, fly ash, and wood pulp, offering resistance to cracking and warping.
• Rammed Earth:
A traditional building method using compacted layers of earth, offering a sustainable and aesthetically pleasing option.
• Papercrete:
A lightweight material made from paper pulp and cement, suitable for non-structural applications.
When choosing a concrete alternative, consider factors like cost, durability, environmental impact, and aesthetic preferences.
STEEL STRENGTH RATIO
A 10 story building breakdown
Floor one
Cam handle the most weight yet bunker basement foundational floors are the base allowing the most
Floor 8
Weight restrictions as we go upward regardless of structural rights & flexibility in wind or events
Floor 10
The weakest floor separate from the center floor which structurally acts as a waist
Multiple factors dictate what a building can handle like a bridge or vehicle
Swaying design thresholds versus shaking from the base without tipping over
Efforts to void floors from effectively squishing the below depend on multiple factors
Tornado or cyclone events of wind bursts require steel caging & air pressure release from glass to void breaking as it will go around & through the building
Stainless steel flat arched designed reinforce weakened concrete structures
Counter weighting if 1/2 is packed to maximum weight capacity to void strain on structure
Base Isolators. Seismic not Flood or other
https://m.youtube.com/watch?v=j0o5gJUxAnY&pp=ygUmU2FuIGZyYW5jaXNjbyBza3kgc2NyYXBlciBjb25zdHJ1Y3R1b24%3D
Aurora Semi-Autonomous Texas
https://youtu.be/sjrr6UY0SXY?si=q5FNio7-KTn5JHR_
Automating many job tasks is best while skilled & safer alternatives
https://m.youtube.com/watch?v=CQrQrOPmszE
Cable Cars as Public Transport
https://www.cbc.ca/radio/day6/cable-car-gondola-canada-public-transit-1.7603636
Azempic
https://www.ctvnews.ca/montreal/article/weight-loss-drugs-show-promise-for-other-diseases-study-shows/
100 EV bill
https://www.cnet.com/home/energy-and-utilities/how-unplugging-a-few-devices-helped-me-knock-100-off-my-electric-bill/
Data Centers
https://youtu.be/Isr-WK1GEJc?si=0p1qX5uIBKjrw-PS
Superficial. Efforts for image. Appearance. Health. Environment. Safety
Buffet. Image & Value Creating. VS Gold
https://www.financialexpress.com/market/gold-pulse/warren-buffett-has-zero-gold-in-his-140b-fortune-heres-why/3940777/
17 PROFITABLE MACHINES to start a BUSINESS with LITTLE MONEY from HOME
https://youtu.be/jN1Ob5eXz-o?si=RCZ1MXsxELWbrA2W
INDUSTRIAL
In an industry increasingly focused on sustainability and innovation, a remarkable development has emerged from Batavia, Illinois. A company named Savor has created butter made entirely from carbon and hydrogen—without any involvement of animals, plants, or traditional oils. This innovation promises to transform the understanding of dairy fats and their environmental impact.
Backed by billionaire investor and climate advocate Bill Gates, this carbon-based butter offers a solution to some of the food industry’s biggest challenges: reducing greenhouse gas emissions, land use, and reliance on animal agriculture, all while delivering the familiar taste and texture consumers expect.
Bill Gates supports new carbon butter that taste with real dairy taste
Traditional butter is primarily composed of fat molecules made of carbon and hydrogen chains. Savor’s innovative process mimics this natural structure, but without animal or plant sources. As CBS News reported, Savor extracts carbon dioxide (CO₂) directly from the air and hydrogen from water. These basic elements undergo heating and oxidation in a controlled industrial process to produce fat molecules chemically identical to those found in dairy butter. Jordan Beiden-Charles, the company’s food scientist, explains:
"The final product looks like candle wax but is actually made up of fat molecules similar to those in beef, cheese, or vegetable oils."
The butter contains only a few simple ingredients: fat, water, lecithin (used as an emulsifier), and natural flavour and colorings. This clean-label approach appeals to modern consumers seeking transparency and simplicity in their foods.
The environmental cost of traditional butter production is significant. It requires extensive farmland to raise cows, feed crops, and produce greenhouse gases — both methane from cows and carbon emissions from agricultural activities.
Savor’s process stands apart because it produces no greenhouse gases during butter manufacturing, addressing a major environmental concern.
Land use reduced by thousands of times. Traditional dairy farming consumes vast areas of land. In contrast, carbon butter production uses minimal space, reducing the land footprint by nearly 1,000 times compared to conventional agriculture.
Many butter alternatives rely on palm oil, which is linked to deforestation and biodiversity loss. Savor’s product contains no palm oil, making it a more environmentally responsible choice. According to Savor, animal and plant fat production contributes roughly 7% of global greenhouse gas emissions, highlighting the potential climate benefits of switching to lab-made fats.
Carbon butter chocolates set to launch for 2025 holiday season
For any new food product, taste is paramount. Savor’s carbon butter reportedly matches the creamy texture, buttery aroma, and flavor profile of traditional dairy butter closely enough to satisfy chefs and consumers. Without artificial additives or complex chemical ingredients, Savor achieves a pure butter flavor that food experts say is indistinguishable from the real thing.
Savor is already partnering with restaurants, bakeries, and food suppliers to test their product. A notable milestone includes the upcoming launch of chocolates made with carbon butter, scheduled for the 2025 holiday season, demonstrating the product’s versatility. Currently focused on commercial applications, Savor aims to make its butter available to consumers by 2027. This timeline allows for scaling production and building distribution networks.
Kathleen Alexander, co-founder and CEO, shares the company’s vision: "We expect Savor Butter, whether on its own or through partners, to be on store shelves within a few years." Bill Gates’ support further boosts confidence in the product’s market potential and environmental impact.
Bill Gates’ vision highlights carbon butter’s role in sustainable food
Bill Gates, known for championing technologies that tackle climate change, has expressed strong support for lab-grown fats and oils. In his blog, he noted: "Switching to lab-made fats and oils may seem unusual at first, but their potential to reduce our carbon footprint is immense."
This endorsement highlights the broader importance of innovations like carbon butter in addressing global sustainability challenges while ensuring food security.
Carbon Butter
https://timesofindia.indiatimes.com/life-style/food-news/bill-gates-backs-lab-made-carbon-butter-that-tastes-like-real-butter-heres-how-it-is-made-and-what-makes-it-special/amp_articleshow/123243219.cms
Growth + Train your Business in AI
https://www.entrepreneur.com/growing-a-business/how-to-train-ai-to-actually-understand-your-business/494496
CIG
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