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DeepEnergy, DeepCloud, DeepCooling, DeepHeath
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Training EcoHold - Deep Energy e Deep Cloud

O Deep Energy Cloud Project

Hello, darlings and darlings, communities, investors, FAPESP, Google, AWS, Azure, Tencent, Huawei, IBM, Oracle, Alibaba and the market!

I'm Zeh Sobrinho, co-creator and CEO of Eco Hold, an ecosystem holding company that thinks, develops, designs and delivers sustainable solutions. I present the DEC Project, a project of research and development, financing, delivery, commissioning of Deep ecosystem of solutions that includes AI models and Deep Energy implementation, Deep Cloud, among others, more energy efficient and sustainable.

Scenario: Pain, Litter, Challenge, Opportunity

  1. London was the financial capital of the world. This was due to a number of factors, including its central location, its history as a commercial center and its well-developed financial system. London was home to many of the world's largest financial companies, including BlackRock, Vanguard and Nimb.

    1. The financial impact of the Google Data Center L5/6/7 failure in London on July 22, 2022 was significant. The failure caused a service outage for some Google products and services, including Gmail, YouTube and Google Search. This resulted in lost revenue for Google and also damaged its reputation as a reliable service provider.

    2. The impact of the Google L5/6/7 Data Center failure in London was also felt by other financial firms such as BlackRock, Vanguard and Nimb. These firms also have a significant presence in London and were affected by the interruption of service.

    3. Companies operating in London or receiving investments from BlackRock, Vanguard, Nimb and BNDES have an interest in resolving the Google L5/6/7 Data Center failure problem.

These companies have lost revenue or reputation which could be worse if another failure occurs.

  1. There are a few ways to monetize this problem. One way is to develop and sell solutions to make datacenters more heat resistant. Another way is to develop and sell solutions to help companies recover from data center failures.

  2. Vincent Cerf is one of the founders of the Internet. He is credited with developing the TCP/IP protocol, which is the foundation of the Internet. The TCP/IP protocol is designed to be resistant to nuclear attacks, whereas it didn't withstand 40 degrees in London.

Lack of investments?

  1. OSI layer graph is shown below. The physical layer is responsible for transporting the data across the network. The data link layer is responsible for ensuring that data is delivered correctly. The network layer is responsible for routing data between different networks. The transport layer is responsible for ensuring that data is delivered in the correct order. The session layer is responsible for establishing and maintaining a connection between two processes. The presentation layer is responsible for converting the data into a format that can be understood by the user. The application layer is responsible for providing services to the user, such as Internet access, e-mail, and chat.

  2. A historical graph of temperature in London since 1945 is shown below. The average temperature in London has been gradually increasing in recent years. The highest temperature recorded in London was 38.5 degrees Celsius in 2019.

  3. The charttreemap temperature in London in 2022 and 2023 is shown below. The graph shows that the temperature in London was highest in 2022, 42.9oC what in 2023.

  4. Google bought DeepMind to reduce the cost of energy. DeepMind is an artificial intelligence company that develops machine learning algorithms. These algorithms can be used to optimize energy usage in data centers.

  5. Ashrae approved a new data center temperature limit of 27 degrees Celsius. This new limit is higher than the previous limit of 25 degrees Celsius. The temperature threshold increase was approved to help reduce the energy cost of data centers without regard for security.

  6. In 2020, IBM stopped the Brazilian Internet through a third-party operation, Ascenty, on the São Paulo campus inSTAR 01, STAR 02 and SAO 03. The failure was caused by a problem with the redundant cooling system with IBM services. The flaw affected Internet access for millions of people in Brazil.

  7. Power and cooling are not part of the OSI layer. This is because the OSI layer is responsible for transporting the data across the network. Power and cooling are required to operate a data center, but they are not involved in transporting data.

  8. The datacenters should be data cloud, but they are still managed like the old CPD, that is, they do not provide external redundancy as standard.

Assigning APP outage to utility services such as power and cooling 'attests that the service provider is not configured for redundant APPs external to the DC or Campus'

🌍 The Journey of Solar Heroes 🌞🌎

Once upon a time, in a world in crisis, five brave and intelligent children emerged from the ravines of five continents. Each of them represented the hope and determination of their communities to face the energy and urban challenges of the planet. 💫

Meet Pedro, the 10-year-old Brazilian boy with a passion for technology. He lived in a favela in Rio de Janeiro, where he dreamed of creating sustainable solutions for his neighborhood. Its mission was to develop a community solar energy project, which uses sunlight to generate electricity and benefit all residents of the favela. ☀️🇺🇸

On another continent, we met Amina, an 8-year-old girl who lived in a village in Kenya. She knew the challenges her community faced with access to clean water and energy. Amina had the idea of ​​building a micro hydroelectric plant that would use the flow of the river near the village to generate clean energy and help supply water to families. 💧🌍🇰🇪

In Asia, we met Mei, a 12-year-old Chinese girl who lived in a highly polluted urban area. She was passionate about plants and animals and dreamed of turning the roofs of buildings into hanging gardens. Mei believed that this solution could improve air quality, reduce the temperature in urban areas, and bring more beauty to the city. 🌿🏙️🇨🇳

In Europe, we have Luca, a 9-year-old Italian boy who lived in a city with urban mobility problems. He was a bicycle enthusiast and proposed the creation of safe and efficient bike lanes throughout the city, as well as the installation of charging points for electric bicycles. Luca believed that this solution could help reduce traffic and pollution and improve the health of residents. 🚴‍♂️🌍🇮🇹

Finally, we go to Oceania, where we meet Hannah, an 11-year-old Australian girl who lived in a coastal region threatened by rising sea levels. She had a passion for the ocean and was determined to develop a wave energy project that harnessed tidal power to sustainably generate electricity and combat the impacts of climate change. 🌊🌏🇦🇺

These five kids, together, embark on an incredible journey around the world to present their energy and urban solutions to the rich and nutty elites. With courage and determination, they faced challenges, overcame obstacles and gained allies in their mission to transform the planet.

Chapter 1: The Meeting of Heroes 🌍💌

The five children, Pedro, Amina, Mei, Luca and Hana, received a mysterious message on their computers one night #Hacker´s Virada ODS Jun/2023. It contained an invitation to a meeting in a secret place where they could share their ideas for changing the world.

Intrigued and excited, the five heroes decided to meet. For that, Pedro parachute flight over the hills of Rio de Janeiro 🪂, Amina ran across the Kenyan savannahs 🏃‍♀️, Mei walked through the skyscrapers of Shanghai 🏙️, Luca cycled through Italian villages 🚴‍♂️ and Hana surfed Australian waves 🏄‍♀️.

They met in an ancient and mysterious temple in the middle of the African desert 🏜️.

Chapter 2: The Temple Prophecy 🗿📜

Inside the temple, the heroes were greeted by a wise old man, who told them of an ancient prophecy. According to the prophecy, five children from different parts of the world came together to face the planet's challenges and bring hope to humanity. The elder showed them a holographic map, revealing specific locations in desert areas of the world, where gigantic solar plants could be built ☀️🏭. Such large-scale production would help solve global energy problems and combat climate change.

Chapter 3: The Desert Journey 🌵🏜️

The heroes realize that in order to fulfill the prophecy and unite the solar plants, they needed to cross the desert on an epic journey. Together, they formed a united and courageous group, facing sandstorms 💨, scorching heat ☀️ and unexpected challenges. During the journey, they learned to trust each other and share their skills and knowledge. Pedro taught about technology and the importance of community 💻🤝, Amina spoke about resilience and the power of water 💧💪, Mei shared her passion for nature and sustainable urbanism 🌿🏙️, Luca showed how mobility could be transformed 🚲✨ and Hana brought the wisdom of the waves and the ocean 🌊🌏.

Chapter 4: The Global Connection 🌐⚡

Upon reaching the center of the desert, the heroes used their skills to build the first solar plants connected globally through power data cables 🔌💡. The solar energy generated at these plants would be intelligently shared and distributed around the world, benefiting communities on every continent.

Chapter 5: The Triumphal Return 🎉🌈

With the success of their journey, the heroes returned to their homes and communities as true champions of sustainability. Pedro implemented his community solar energy project in the favela, bringing light and hope to the residents 💡🏘️. Amina built the micro hydroelectric plant in her village, solving water and energy problems 💧⚡. Mei turned city roofs into hanging gardens, improving quality of life and the environment 🌿🌆.

Chapter 6: The Legacy of Heroes 🌟🌍

As the stories of the heroes spread, more and more children around the world were inspired by their journeys. They started creating their own sustainable projects and working together to transform their communities. The five solar heroes become mentors and guides for these children, helping them overcome challenges and find innovative solutions. Together they formed a global network of young environmental advocates dedicated to creating a sustainable and bright future for all.

Chapter 7: The Celebration of Sustainability 🎉🌎

To celebrate the success of their journeys, the Solar Heroes organized a grand celebration of sustainability. People from all over the world came together for a festival full of music, art and inspiring ideas. During the festival, children shared their projects and achievements, celebrating the power of imagination and action. The entire world witnessed the incredible transformation that took place when children came together to tackle the planet's challenges.

Epilogue: The Sustainable Future ✨🌍

Over the years, solar hero solutions have spread around the world, reaching more and more people and communities. Solar energy, hydroelectric power plants, hanging gardens and cycle paths have become an integral part of everyday life in every corner of the planet. Thanks to the hard work and vision of the Solar Heroes, the world has finally achieved a balance between technology and nature, ensuring a sustainable future for generations to come. The story of the solar heroes continues to inspire children and adults alike to take action for the environment and believe in the power of change. Together they showed the world that we all have the potential to be heroes and create a better world for all. End. I hope you enjoyed this exciting and inspiring story of the Solar Heroes!

Call Zero Carbon

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Pain | Opportunity | Solution

Global

More than 50% of the planet's electrical energy is produced by transforming fossil fuels, predominantly coal and natural gas, and in this process, more than 50% of the heat produced is not used in the form of energy, being discharged, wasted and dumped on the planet. , also known as Instantaneous Global Warming. The same happens with more than 500 nuclear sites, with energy efficiency of less than 40%, that is, 60% of the heat produced is thrown into the sea. Energy waste amounts to US$17 trillion a year, so a company that produces energy, distributes energy, at a minimum, must be ISO 5001 certified to take advantage of this opportunity.

The NetZero transition involves increasing the energy efficiency of the current matrix, including solar, 5 hours a day of production and 20% energy efficiency.

In this scenario we discuss and deliver two solutions:

Google Cloud

Google's energy demand has grown from around 100 megawatts (MW) in 2000 to around 10 gigawatts (GW) in 2022. This represents an increase of about 100 times in 22 years.

Google's energy consumption will continue to grow over the next 22 years as the company continues to expand its business and offer new services.

Google Cloud projects that its energy consumption will increase to 100 GW by 2025 and to 1 terawatt (TW) by 2030. That's about a 10-fold increase by 2022.

In 2011 the planet consumed 17 TW, while the Sun delivers 86,000 TW.

Fonte:EMEG Initiative

There are a few factors that are driving Google's power consumption growth. One factor is the increased use of cloud services. Cloud services are web-based and hosted in data centers. As more people use cloud services, Google needs to build more data centers and allocate more energy to power them.

Another factor driving Google's energy consumption growth is the increased use of artificial intelligence (AI). AI is a technology being used in a variety of Google products and services, such as the Google Assistant, Google Translate, and Google Photos. As Google continues to invest in AI, the company needs to allocate more energy to power AI systems.

Activity Power consumption (watts) Time (minutes) Energy consumption (kWh) Cost (BRL)
Bath 😱 5500 10 5.5 0.34
Mining of *PLIMM 😱😱 4466.8 10 4.47 0.28
Generating GPT Prompt 😱😱😱 2600.84 10 2.6 0.16

Google is taking steps to reduce its power consumption. The company is using renewable energy sources such as solar and wind energy to power its data centers. Google is also investing in energy-efficient technologies like liquid cooling and edge computing.

Despite these measures, Google's energy consumption will continue to grow for the next 22 years. Google is committed to using energy sustainably and is working to reduce its environmental impact.

Pain: Google Cloud is expensive.

Pain: Google Cloud is expensive.

Pain: Google Cloud is difficult to use.

Pain: Google Cloud is unreliable.

Pain: Google Cloud is not secure.

Google's energy demand growth is driven by a number of factors. One factor is the growth in Internet usage. In 2000, there were around 500 million Internet users in the world. By 2022, that number has increased to around 4.5 billion. This increase in Internet usage has led to an increase in demand on Google's servers to store and process data.

Another factor driving Google's power demand growth is the rise in popularity of cloud-based services such as Google Cloud Platform. Google Cloud Platform is a cloud computing platform that offers a variety of services including storage, processing, networking, and data analytics. These services are becoming more and more popular, which is leading to an increase in demand for Google's servers.

According to analysis by market research firm Technavio, Google's energy consumption is expected to grow from 19.9 billion kWh in 2022 to 44.1 billion kWh in 2028, with a compound annual growth rate (CAGR) of 12.6%. This is due to a number of factors, including Google's growing user base, expanding its Deep Cloud infrastructure, and increasing demand for cloud computing services.

Finally, the development of new technologies such as artificial intelligence and cryptocurrency mining is also driving growth in Google's energy demand. Artificial intelligence is a technology that is becoming more and more powerful and is being used in a wide variety of applications such as image recognition, machine translation and machine learning. These applications require a large amount of computing power, which is leading to an increase in demand on Google's servers.

Cryptocurrency mining is another activity that is consuming more and more energy. Cryptocurrency mining is the process of generating new units of cryptocurrencies such as Bitcoin and Ethereum. This process requires a large computational power, which is leading to an increase in energy demand.

Google's increased demand for energy is having a significant impact on the environment. Google is one of the biggest consumers of energy in the world and its operations emit a lot of greenhouse gases. Google is working to reduce its environmental impact, but there's still a lot to be done.

Google is also working to develop new technologies that can help reduce its environmental impact. For example, Google is investing in renewable energy sources such as solar and wind energy, and is working to develop more energy-efficient servers.

Google is committed to reducing its environmental impact and is taking steps to achieve it. However, much remains to be done, and it's important that Google's customers help the company achieve its goals.

Deliveries: improve metrics including mind share

Number of Customers: Google Cloud has a growing number of customers, including large enterprises, small businesses, and startups. Revenue: Google Cloud is generating increasing revenue, which reflects the growing demand for its services. Market share: Google Cloud has a growing share of the cloud computing market, which reflects the success of its services. Reputation: Google Cloud has a strong reputation for reliability, security, and performance, making it a popular choice for customers. Customer Satisfaction: Google Cloud has a high customer satisfaction which reflects the quality of its services.

Products and services

Deep EnergyDeep Energy is a renewable energy system that uses a variety of energy sources, including solar, wind and geothermal energy. The Deep Battery is also capable of storing solar energy by dynamic time zone, without battery, which allows the Deep Cloud to operate even when there is no local energy production.

Yes, distributed Deep Clouds continuously receive power because of different time zones. This means that they can generate power even when the sun is not shining in a certain location.

The total energy was calculated considering the net solar hours. This means that the solar hours that are not used by the Deep Clouds were not accounted for.

For example, if a Deep Cloud is located in a location that receives 6 hours of sunlight per day, but is only operating for 4 hours per day, then only 4 hours of sunlight will count towards the total energy.

By considering net solar hours, we can get a more accurate estimate of the amount of energy distributed Deep Clouds can generate. This is important because it allows us to assess the Deep Sun project's potential to provide clean, renewable energy to the world.

DeepCloudDeep Cloud is a cloud computing system that is powered by Deep Energy. The Deep Cloud is capable of providing computing, Deep Battery, solar storage and networking services in a scalable, redundant and efficient manner.

Technological Partnership Agreement between Ecohold and Google Cloud

This Technology Partnership Agreement ("Agreement") is entered into between Ecohold, represented by CEO Zeh Sobrinho, and Google Cloud, represented by its legal representative.

1. Aim

The parties agree to establish a technology partnership to develop and implement innovative solutions based on cutting-edge technologies, including artificial intelligence, blockchain and liquid immersion cooling. The aim is to promote sustainability, reduce carbon emissions and increase energy efficiency in data centers and deep model processing services.

two. Project Scope

The scope of the project will cover the following activities:

2.1. Desenvolvimento de Deep Energy Cloud & Credit Carbon Negative Blockchain 2.2. Deployment of Servers with Liquid Immersion Cooling Technology 2.3. Use of Artificial Intelligence Represented by A.I.R.I.S. 2.4. Integration with the Free Google Cloud Platform 2.5. Monitoring and Control of Carbon Emissions

  1. Responsibilities of the Parties

3.1. Ecohold:

3.2. Google Cloud:

4. Intellectual property

Each party will own its respective intellectual property rights relating to the project. However, both parties agree to share the results and benefits generated by the partnership fairly and equitably.

5. Confidentiality

The parties agree to keep all confidential information exchanged during the partnership confidential and not to disclose it to third parties without prior written consent.

6. Term and Termination

The term of this contract will be 10 years, which may be extended by mutual agreement of the parties. In the event of serious breach of the obligations established in this contract, either party may terminate it, upon written notice at least 30 days in advance.

7. Remuneration

The partnership will be governed by benefit sharing, with the revenues and savings generated by the project being divided equally between the parties, considering the investments and efforts of each one.

8. Applicable Law and Jurisdiction

This contract will be governed by the laws [See Certification Regulation] and any disputes arising therefrom will be submitted to the exclusive jurisdiction of the courts of the city of [São Paulo, , ].

The parties, by their legal representatives, sign this Agreement on the last signature date below.

CEO Zeh Sobrinho - Ecohold

Legal Representative - Google Cloud

Date: July 2023

NGH2DeepEnergy Yes, distributed Deep Clouds continuously receive power because of different time zones. This means that they can generate power even when the sun is not shining in a certain location. The total energy was calculated considering the net solar hours. This means that the solar hours that are not used by the Deep Clouds were not accounted for. For example, if a Deep Cloud is located in a location that receives 6 hours of sunlight per day, but is only operating for 4 hours per day, then only 4 hours of sunlight will count towards the total energy. By considering net solar hours, we can get a more accurate estimate of how much energy distributed Deep Clouds can generate. This is important because it allows us to assess the Deep Sun project's potential to provide clean, renewable energy to the world. Deep Cloud: The Deep Cloud is a cloud computing system that is powered by Deep Energy. The Deep Cloud is capable of providing scalable and efficient cross-continental computing, storage and networking services powered by Solar Deep Energy.

DeepWind: Marine energy farms integrated withTHINK2 DataCloud, Deep Power THINK2

Deep Power NGH2 Hybrid energy farms producing natural gas and h2, distributed by hybrid pipelines 95/5%, reaching 15/85% in 2030, integrated with NGH2 DataCloud and DeepWind

Deep Regulation: Regulatory ecosystem, Arsesp, state, municipal PAN CLIMA in São Paulo, enables hybrid gas pipelines, Natural Gas and H2, 95/5% initially, reaching 15/85% in 2030, supplied by Maritime Platforms integrated by Farms maritime energy plants integrated with H2 plants with energy supplied by offshore DeepWind wind farms that deliver the blend, Natural Gas and H2, through hybrid gas pipelines. Distribution serves the coast and goes up the mountains to supply residential, commercial and industrial, whether for cooking, heating or HPC with 85% energy efficiency for large HPC, thermoenergy in urban areas, in line with the targets Pedreira Thermal Project | EMAE (in the second privatization attempt), offshore wind, natural gas, for example in the Santos Basin, São Paulo, Brazil.

Deep Auction

Metas e Pactos Associações da indústria e outras organizações podem ajudar a estabelecer metas e fornecer apoio para alcançar essas metas.

A Associação Europeia de Data Centers adotou um Pacto de Clima Neutro para Data Centers que aproveita a tecnologia e a digitalização para tornar os data centers neutros em relação ao clima até 2030. As organizações associadas concordam em alcançar metas de eficiência energética, energia limpa, água, economia circular e energia circular.

A Science-Based Target Initiative (SBTi) ajuda as empresas a alcançar metas ambiciosas relacionadas ao clima, definindo metas de redução de emissões baseadas na ciência. A organização fornece melhores práticas, assistência técnica e recursos para mobilizar o setor privado para agir mais rapidamente na descarbonização de seus processos e modelos de negócios.

Os Objetivos de Desenvolvimento Sustentável (ODS) das Nações Unidas são compostos por 17 objetivos interligados que foram adotados por todos os estados membros da ONU. Os objetivos promovem o bem-estar e a igualdade social, econômica e ambiental. Em termos de sustentabilidade ambiental, os proprietários e operadores de data centers são mais afetados por:

Estruturas e Padrões Várias organizações fornecem recursos e estruturas para simplificar a gestão e a geração de relatórios sobre eficiência e emissões.

Certificações e Ferramentas Padrões e certificações podem ajudar proprietários e operadores a avaliar seu progresso em relação a outros na indústria e validar a eficácia de suas decisões.

Index Deep Cloud The IDC is an indicator between a numerical range and a color gradient between blue and pink that indicates how close or far the DataCloud is to the ideal of energy efficiency.

BenchMark 2023 GCP LD4 LD5 LD6 LD7 & IBM SAO01 SAO02 SA003 2020

Característica Cálculo Unidade Objetivo Medidas
Fator de Utilização do Economizador de Ar (AEUF) Tempo de Utilização do Economizador de Ar / Tempo Total Porcentagem Maximizar Frequência de uso de ar externo para resfriamento grátis
Eficiência do Fluxo de Ar (Airflow Efficiency) Potência do Ventilador / Fluxo de Ar W / cfm Minimizar Eficiência de movimentação de ar da entrada à saída
Gabinetes Conformes com Padrões ASHRAE Racks na Faixa Recomendada pela ASHRAE / Total de Racks Porcentagem Maximizar Progresso em direção às condições ambientais ideais
Eficiência de Uso de Carbono (Carbon Usage Effectiveness, CUE) Emissões de CO2 / Energia de TI kg CO2 / kWh Minimizar Sustentabilidade geral de um centro de dados
Economia de CO2 (CO2 Savings) Possíveis Emissões de CO2 / Emissões de CO2 Reais Razão Maximizar Emissões de CO2 evitadas devido a esforços de eficiência
Fator de Capacidade de Resfriamento (CCF) Capacidade de Resfriamento / Carga Crítica Razão Minimizar Eficiência geral do sistema de resfriamento do data center
Eficiência da Infraestrutura do Data Center (DCiE) Energia de TI / Energia da Instalação Porcentagem Maximizar Porcentagem de energia total da instalação usada por equipamentos de TI
Eficiência de Desempenho do Data Center (DCPE) Trabalho Útil / Energia da Instalação Trabalho / kWh Maximizar Eficiência do desempenho do data center
Desempenho por Energia do Data Center (DPPE) Trabalho / (Energia Total - Energia Verde) Razão Maximizar Eficiência energética do data center, incluindo equipamentos de TI e infraestrutura
Densidade de Energia do Data Center (DCPD) Consumo de Energia do Rack / Rack kW / Rack Maximizar Comparação entre consumo de energia do rack e capacidade de energia do rack
Eficiência de Espaço do Data Center (DCSE) Utilização do Espaço RU x Utilização do Espaço do Piso Porcentagem Maximizar Eficiência no uso do espaço do data center
Delta-T por Gabinete Temperatura de Exaustão - Temperatura de Entrada °C ou °F Otimizar Eficiência do fluxo de ar para resfriamento de equipamentos
Eficiência de Utilização de Hardware Implementado (DH-UE) Sistemas Mínimos para Lidar com Carga Máxima / Total de Sistemas Porcentagem Maximizar Eficiência de utilização de servidores e sistemas de armazenamento
Razão de Utilização de Hardware Implementado (DH-UR) Servidores Executando Aplicações ao Vivo / Total de Servidores Porcentagem Maximizar Quantidade de energia desperdiçada por sistemas inativos
Eficiência de Reutilização de Energia (ERE) (Energia Total - Energia Reutilizada) / Energia de TI Razão Minimizar Eficiência energética geral se a energia estiver sendo reutilizada fora do data center
Fator de Reutilização de Energia (ERF) Energia Reutilizada / Energia Total Porcentagem Maximizar Quantidade de energia reutilizada fora do data center
Razão de Energia Fixa para Variável (FVER) Energia Fixa / Energia Variável Razão Minimizar Quantidade de energia visada para redução ou eliminação
Coeficiente de Energia Verde (GEC) Energia Verde / Energia Total Porcentagem Maximizar Quantidade de energia renovável gerada no local
Fator de Utilização da Rede (GUF) Tempo em que a Energia Gerada Localmente Cobriu a Demanda de Energia / Tempo Total Porcentagem Minimizar Frequência com que o data center é alimentado por energia gerada no local
Eficiência do Sistema de HVAC (HSE) Energia de TI / Energia do Sistema de HVAC Razão Maximizar Eficiência geral do sistema de resfriamento do data center
Eficiência de Energia de Equipamentos de TI (ITEE) Capacidade de TI / Energia de TI Razão Maximizar Eficiência da utilização da capacidade de energia por

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GCP Brasil e as notas:

Parâmetro Valor padrão GCP Brasil Nota
Fator de Utilização do Economizador de Ar (AEUF) 90% 100% 100%
Eficiência do Fluxo de Ar (Airflow Efficiency) 600 l/s/rack 600 l/s/rack 100%
Gabinetes Conformes com Padrões ASHRAE 90% 90% 100%
Eficiência de Uso de Carbono (CUE) 50 kgCO2/kWh 50 kgCO2/kWh 100%
Economia de CO2 (CO2 Savings) 5000 tCO2/ano 5000 tCO2/ano 100%
Fator de Capacidade de Resfriamento (CCF) 500 kW/rack 500 kW/rack 100%
Eficiência da Infraestrutura do Data Center (DCiE) 90% 90% 100%
Eficiência de Desempenho do Data Center (DCPE) 90% 90% 100%
Desempenho por Energia do Data Center (DPPE) 90% 90% 100%
Densidade de Energia do Data Center (DCPD) 500 kW/m² 500 kW/m² 100%
Eficiência de Espaço do Data Center (DCSE) 90% 90% 100%
Delta-T por Gabinete 5 °C 5 °C 100%
Eficiência de Utilização de Hardware Implementado 90% 90% 100%
Razão de Utilização de Hardware Implementado 90% 90% 100%
Eficiência de Reutilização de Energia (ERE) 90% 90% 100%
Fator de Reutilização de Energia (ERF) 90% 90% 100%
Razão de Energia Fixa para Variável (FVER) 90% 90% 100%
Coeficiente de Energia Verde (GEC) 90% 90% 100%
Fator de Utilização da Rede (GUF) 90% 90% 100%
Eficiência do Sistema de HVAC (HSE) 90% 90% 100%
Eficiência de Energia de Equipamentos de TI (ITEE) 90% 90% 100%
Temperatura dos núcleos 20 °C 20 °C 100%

O Deep Cloud IDC Index é calculado usando uma média ponderada dos valores de cada KPI. Os pesos são baseados na importância relativa de cada KPI para o desempenho geral do data center. Por exemplo, a eficiência de energia é um KPI mais importante do que a eficiência de espaço, portanto, tem um peso maior.

O Deep Cloud IDC Index para o GCP Brasil é de 100, o que é excelente. Isso significa que o GCP Brasil está em conformidade com as melhores práticas de eficiência de data center.

NGH2 DataCloud NGH2 DataCloud is a cloud computing system that is powered and integrated into the power plantTHINK2 Deep Energy, 95/5%. The N2Deep Cloud is capable of providing scalable and efficient computing, storage and network services locally in urban areas, supplied by Hybrid Natural Gas and Hydrogen Turbines, technology available and validated by the market and large global suppliers.

Deepcool: DeepCool is a cooling system that utilizes a variety of techniques including water cooling, air cooling and immersion cooling. DeepCool is capable of keeping the Deep Cloud at a suitable temperature even when operating under heavy load.

Deep Sun Storage Thermoaccumulation system stores heat from the sun during the day to be consumed by Deep Chillers at night

Deep Chiller The thermoaccumulation cooling system uses heat from the sun during the day to produce cold for Deep Clouds or accumulated heat for Deep Sun Storage.

Deep Health: Deep Health was our first experience with Tensors during the invite 19 hack, it is a medical diagnostic system that uses artificial intelligence to identify injuries in health images. Deep Health is able to accurately identify injuries, which can lead to more effective treatment that stimulates and demands other projects.**

Deep Vision Images per day with STL, 3DM, DWG output with details of brands and components to be delivered by industry 4.0, impossible today, only via 2D printing.

Deep AIX: ISO to run all applications and AI models 100% in-memory, including persistence, based on Linux called "Linux From Scratch" (LFS). LFS is an open source project that provides a step by step guide on how to build your own Linux operating system from its code base.

Deep AI: Reduced power consumption of AI models

DeepVision Images per day with STL, 3DM, DWG output with details of brands and components to be delivered by industry 4.0, impossible today, only via 2D printing.

Deep PLIMMMonetize the circular economy at the point of purchase through the product lifecycle (PLM) and waste lifecycle (WLM). PLIMM Initiative

Deep Trash: @poplixo Ecosystem USA&CCNFT Initiative

Deep Fashion PopLixo Initiative

Pop Lixo City PopCity Initiative

Deep Sun

Vision

The Deep Sun Project is an initiative to build a Deep Energy renewable energy ecosystem with the goal of providing clean and affordable energy to the world. The project will be financed through the sale of carbon credit NFTs, which will be backed by PLIMM, a crypto asset already generated at Open Sea. Yes, distributed Deep Clouds continuously receive power because of different time zones. This means that they can generate power even when the sun is not shining in a certain location.

The total energy was calculated considering the net solar hours. This means that the solar hours that are not used by the Deep Cloud were not accounted for.

For example, if a Deep Cloud is located in a location that receives 6 hours of sunlight per day, but is only operating for 4 hours per day, then only 4 hours of sunlight will count towards the total energy.

By considering net solar hours, we can get a more accurate estimate of how much energy distributed Deep Clouds can generate. This is important because it allows us to assess the potential of the Deep Sun project to provide clean, renewable energy for the Deep City across the deserts of today's world.

Mission

The Deep Sun Project has a mission to reduce greenhouse gas emissions and help mitigate climate change. The project also has a mission to provide clean, affordable energy to people around the world.

Solution

The Deep Sun Project will build a network of renewable energy Deep Clouds located across the world. The Deep Clouds will be powered by solar, wind and geothermal energy. The energy produced by the Deep Clouds will be sold to businesses and consumers, and the proceeds will be used to finance the project.

Impact

The Deep Sun Project has the potential to reduce greenhouse gas emissions by billions of tons per year. The project also has the potential to provide clean, affordable energy to people around the world.

In phase I, the total energy production of the solar plants is 11.3 terawatts. This is the sum of the energy output of all 16 solar plants listed in the table.

The solar plant with the highest energy production is R&D H1, in Sahara, Libya. This plant has a capacity of 1.02 terawatts. The solar plant with the lowest energy production is R&D CH16, in Canudos, Brazil. This plant has a capacity of 0.28 terawatts.

The total energy output from solar plants is enough to power around 1.2 billion homes. It is also enough to reduce greenhouse gas emissions by around 1.5 billion tons per year.

Solar plants are a clean, renewable source of energy that can help reduce our dependence on fossil fuels. They can also help improve air quality and create jobs.

Team

The Deep Sun Project team is comprised of engineers, scientists and energy experts with extensive industry experience. The team has a strong commitment to sustainability and is determined to make a difference in the world.

Flat

The Deep Sun Project is currently in the development phase. The team is working to identify locations for the Deep Clouds and to develop the engineering design. The team is also working to develop a commercialization plan for the energy produced by the Deep Clouds.

Financing

The Deep Sun Project will be financed through the sale of carbon credit NFTs. The NFTs will be backed by PLIMM, a crypto asset already generated at Open Sea. PLIMM is a sustainable crypto asset that is backed by a network of renewable energy Deep Clouds.

Issue

The Deep Sun Project reduces greenhouse gas emissions by billions of tons per year. This is done by building a network of Deep Energy & Deep Clouds of renewable energy and selling clean, affordable energy to businesses and consumers.

Power & DeepCloud by Eco Hold

Deep Global Power, Cloud, Cooling, City

Site ID Local 🌍 Google Earth Link Latitude/Longitude Area (km²) UTC Deep Energy IN(TW) Deep Cloud Conta (GW) Deep Energy OUT Receitas (TW) Região
P&DCEH1 Sahara, Libya Google Earth 27.6826, 15.8389 363.48 +2 0.727 1 0.717 Africa
P&DCEH2 Tsagaan, China Google Earth 42.8279, 103.2319 121.19 +8 0.242 1 0.232 Asia
P&DCEH3 Australia Central Google Earth -23.6980, 133.8807 70 +9:30 0.14 1 0.13 Oceania
P&DCEH4 Mojave Google Earth 36.5323, -116.9325 80 -8 0.16 1 0.15 North America
P&DCEH5 Atacama Google Earth -23.8635, -69.1320 90 -3 0.18 1 0.17 South America
P&DCEH6 Sonora Google Earth 29.2705, -111.9516 100 -7 0.2 1 0.19 North America
P&DCEH7 Kalahari Google Earth -22.3285, 21.8569 110 +2 0.22 1 0.21 Africa
P&DCEH8 Patagonia Google Earth -51.9225, -69.4750 120 -3 0.24 1 0.23 South America
P&DCEH9 Taklamakan Google Earth 39.3743, 83.0158 130 +8 0.26 1 0.25 Asia
P&DCEH10 Namibia Google Earth -23.6445, 15.8076 140 +2 0.28 1 0.27 Africa
P&DCEH11 White Sands Google Earth 32.7867, -106.3257 150 -7 0.3 1 0.29 North America
P&DCEH12 Colorado Google Earth 38.9072, -109.1739 160 -7 0.32 1 0.31 North America
P&DCEH13 Libya Google Earth 26.2756, 17.2273 170 +2 0.34 1 0.33 Africa
P&DCEH14 Tabernas Google Earth -38.9949257, -9.7286609 180 +2 0.36 1 0.35 Europe
P&DCEH15 Sahara Google Earth 31.0615, -7.9375 190 +1 0.38 1 0.37 Africa
P&DCEH16 Canudos Google Earth 31.0615, -7.9375 141.3 +1 0.28 1 0.273 South America
Total 3.985 16 3.825

Total energy production is 3,985 TW. The total consumption of the Deep Clouds is 16 GW. The total surplus energy is 3,825 GW. The total surplus energy revenue is USD 1.538 billion. Total revenue from data services is USD 1.283 billion.

CAPEX

total is 100 billion USD. The total OPEX is 50 billion USD.

The recipe

total is 2.821 billion USD.

The balance point

is 71.25%.

The total profit is

1.009 billion USD.

Eco Hold pays 50% of profits as dividends, which are USD 504.5 million as of the IPO in 2028.

CAPEX: CAPEX is the cost of building solar plants and data centers. It includes the cost of land, materials, labor and equipment.

OPEX: OPEX is the operating cost of solar plants and data centers. It includes the cost of electricity, maintenance and security.

Revenue: Revenue is income generated from the sale of surplus power and data services.

Break-even point: The break-even point is the point at which revenue equals costs.

Profit: Profit is the income remaining after costs have been deducted.

Dividends: Dividends are the portion of profit that is paid to shareholders.

Standards and certifications:

The DEC Project and team meet a number of standards and certifications, including:

TimeEco Hold

Board of Directors:

Executive Team:

Strategic Layer:

Tactical Layer:

Operational Layer:

Suppliers and Customers

Development Team

The regional development team by continent and different time zones maintains full time development, is responsible for developing and maintaining project deliverables by ecosystem. The team is made up of software engineers, hardware engineers, quality engineers and project managers.

North America:

USA

Canada

Europe:

United Kingdom

Germany

Asia:

China

Latin America:

Middle East:

Africa:

Regional development teams are responsible for developing and maintaining project deliverables in their regions. Regional teams work closely with the core development team to ensure that deliverables meet Eco Hold standards and that projects operate full time.

Experience

Team members have experience ranging from Young Learners to professionals with 2 to 10 years in development as well as seniors in design, design, build, deployment, commissioning, maintenance, upgrade, product lifecycle (PLM) and product lifecycle. residue (WLM). They have experience in a variety of technologies including Java Devops, Python, C++, C#, JavaScript, React, Angular, Node.js, AWS, Azure and GCP.

Remuneration

Team members are paid competitively based on their skills and experience. They also receive a share in the company's profits.

Stock Option

Team members receive a share in the company's profits through a restricted stock option plan. This plan allows team members to become shareholders in the company and benefit from its success.

Full time co-creation

The development team is responsible for delivering all projects on schedule. The team works closely with other teams across the company to ensure projects are successful.

Each regional development team is responsible for developing and maintaining project deliverables in their region. The regional teams work closely with the core development team to ensure that the software meets company standards.

The development team works a variety of shifts to ensure the software is available 24 hours a day, 7 days a week, 365 days a year. Regional teams work in shifts that correspond to their region's time zones.

In each project, in each continent, there is at least one big cloud (Google, AWS, Azure, Tencent, Huawei, IBM, Oracle, Alibaba) and big energy representative. Representatives work with the Eco Hold development team to ensure deliverables are developed according to standards and best practices.

Eco Hold Vision: 🌟

Lead the global charge for innovative sustainable solutions, driving the shift to a green and low-carbon economy. #SustainabilityRevolution

Mission: 🚀

Develop and offer cutting-edge sustainable solutions, maximizing positive impact on the environment and society, while fueling economic growth. #GreenTech Pioneers

Purpose: 🌿🤝

Build a sustainable Present by delivering innovative solutions that tackle environmental, social, and economic challenges head-on. #Present Forward

Value Proposition: 💎🌍

We offer top-notch sustainable solutions powered by advanced technology, meeting customer needs while reducing environmental impact. #Innovation For Good

Differentiators: 🌟✨

1️⃣ Sustainability champions: Minimize resource consumption and carbon emissions across all subsidiaries. #Eco Warriors

2️⃣ Tech innovation gurus: Harness AI, solar energy, high-tech recycling, and smart agriculture for sustainable solutions. #Tech For Good

3️⃣ Integrated approach masters: Provide a complete ecosystem from data clouds to digital education and intelligent logistics. #Sustainable Synergy

4️⃣ Value-added focus: Tailor-made solutions for customers, driving sustainability and efficiency hand in hand. #CustomSustainability

5️⃣ Strategic partnerships: Collaborate with industry leaders for continuous innovation and top-quality products/services. #PartnersInSustainability

Solutions, Products, and Services: 🛠️📦🚀

1️⃣ EcoData: Energy-efficient and scalable Sustainable Data Clouds with a minimal carbon footprint. #Data Revolution

2️⃣ EcoSolar: Deploy sustainable solar energy systems, empowering distributed generation and solar panel installations. #Solar Power

3 ️ ⃣ EcoAI: AI-based solutions optimizing processes, decision-making, and data analysis with a focus on sustainability. #AIfor Good

4️⃣ PopliJoias: Craft sustainable jewelry using environmentally responsible materials and processes. #Jewelry With A Purpose

5️⃣ SmartFarm: Intelligent agriculture solutions with remote monitoring, automation, and efficient resource utilization. #Smart Farming

6️⃣ RecicloTech: Advanced recycling technologies maximizing material recovery and waste reduction. #Recycling Innovative

7️⃣ EcoDrive: Drive sustainable mobility with electric vehicles, transportation sharing, and smart charging infrastructure. #GreenMobility

8 ️ ⃣ Carbon Zero: Generate and supply renewable energy (wind, solar, hydro, biomass) to slash carbon emissions. #Renewable Revolution

9️⃣ Poplixo Construction Platform: Sustainable construction solutions with eco-friendly materials, efficient methods, and renewable energies. #Eco Construction

🔟 Digital Education: Provide digital solutions fostering sustainability awareness and innovation skills. #Digital Learning

1️⃣1️⃣ Intelligent Finance: Advanced financial technologies (blockchain, e-payments) for sustainable financial management. #SmartFinance

1️⃣2️⃣ Intelligent Communication: Advanced communication solutions (smart networks, IoT) focusing on efficiency and sustainability. #ConnectedSustainability

1️⃣3️⃣ Digital Entertainment: Innovative entertainment experiences promoting environmental and social awareness. #EntertainmentForChange

1️⃣4️⃣ Intelligent Logistics: Optimize logistics with efficient routing, transportation monitoring, and intelligent supply chain management. #Logistics Evolved

1️⃣5️⃣ PLIMM Bank: Optimize financial logistics with efficient routing, transportation monitoring, and intelligent financial supply chain management. #Financial Evolved

1️⃣6️⃣ Deep Consulting

1️⃣7️⃣ Deep Design

Together, Eco Hold and its subsidiaries offer a wide array of sustainable solutions, empowering a greener and more conscious Present. Join us in making a difference! 🌿🤝🌍💡 #EcoHold #SustainabilityMatters

ENERGY EFFICIENCY CONSIDERATIONS FOR HPC PROCUREMENT DOCUMENT: 2.0.1.

👋 Hello, everyone!

🌟 I have an incredible mission, and I'm reaching out to ask for your help! We're working on an exciting project about energy efficiency and financial analysis of DeepClouds. And that's where you come in! 😄

🔎 We need experts who can share their knowledge and assist us in answering some questions about DeepClouds. We want to explore aspects such as energy capacity, cooling systems, financial analysis, hydrogen production, and revenue from excess energy and carbon credits. We also want to contribute to the ENERGY EFFICIENCY CONSIDERATIONS FOR HPC PROCUREMENT DOCUMENT: 2.0.1.

💡 We have a table with some preliminary information, but we're looking to fill in the missing financial values to conduct more accurate analyses. If you have expertise in this area and can contribute these values, it would be incredible!

🤝 Additionally, if you know individuals or companies interested in investing in this type of project or providing valuable insights, please share their contacts with us. We're looking for industry professionals, investors, and engaged companies to join this initiative.

🌍 We believe that together we can make a difference and drive energy efficiency in DeepClouds. We're excited to connect with you and discuss further details. Let's join forces for this exciting project!

📩 If you're ready to embark on this journey with us, feel free to reach out to us via LinkedIn or email. I'm eager to hear your ideas and collaborate on this innovative initiative!

Thank you very much for your attention and support. Let's make energy efficiency a reality!

Best regards

Zeh Sobrinho |Eco Hold | Co-Creator and the bus

EcoHold Training I

Introduction to the Industrial Revolution and the role of coal and oil in the development of steam engines and locomotives.

The Industrial Revolution was a period of great change in human history that began in England in the 18th century and spread to other parts of the world in the following centuries. It was marked by the use of new technologies, such as the steam engine and the locomotive, which allowed for the mass production of goods and the rapid expansion of trade.

Coal and oil were the main fuels used in the Industrial Revolution. Coal was used to power the steam engines, which were essential for mass production. Petroleum was used to make fuel for locomotives and ships, whichfacilitated the transport of goods and people.

The Industrial Revolution had a significant impact on the environment. The use of fossil fuels has contributed to increased air and water pollution. Mass production has also led to deforestation and land degradation.

Financial capital of the world: London, New York or São Paulo?

The main criteria for classifying a city as the financial capital of the world are:

* The size of the financial market
* The quality of financial services
* Political and economic stability
* Transport and telecommunications infrastructure
* The presence of global financial institutions

London, New York and São Paulo are the three most important cities in the world in financial terms. They have large financial markets, high-quality financial services, political and economic stability, state-of-the-art transport and telecommunications infrastructure, and the presence of global financial institutions.

The main challenges that London, New York and São Paulo face in order to consolidate themselves as the financial capital of the world are:

* Competition from other cities such as Beijing, Shanghai and Singapore
* The rise of fintechs, which are revolutionizing the financial industry
* Cyber ​​risks
* Climate change

Financial and reputational impact on BlackRock, Vanguard and NIMB related to the topic addressed.

BlackRock, Vanguard and NIMB are the three largest asset managers in the world. They have total assets under management of approximately US$ 10 trillion. These companies invest in a wide range of assets including stocks, bonds, real estate and commodities.

The topic addressed in the course is the energy efficiency of data centers. Data centers are large facilities that store and process data. They are responsible for a large amount of energy consumption. Companies that operate data centers can face financial and reputational impacts if they do not take steps to improve the energy efficiency of their data centers.

There is a growing number of companies that are willing to solve the problem of energy efficiency in data centers. The investment required to improve the energy efficiency of data centers varies with the size and complexity of the data center. Ecohold is a startup that is working to develop solutions to improve the energy efficiency of data centers.

There are several ways to monetize solving the data center energy efficiency problem. One way is to sell the solutions to improve the energy efficiency of data centers to companies that operate data centers. Another way is to sell consulting services to improve the energy efficiency of data centers. Companies that can benefit from solving the data center energy efficiency problem are companies that operate data centers, companies that provide energy services for data centers, and companies that provide IT solutions for data centers.

Vincent Cerf and the creation of the TCP/IP protocol. How does the OSI layer relate to message traffic?

Vincent Cerf is an American computer scientist who is considered one of the fathers of the internet. He is a co-inventor of the TCP/IP protocol, which is the fundamental protocol of the Internet.

EcoHold Training II - Datacenter

What is a datacenter?

A datacenter is a facility that houses computing equipment such as servers, switches, routers, and firewalls. Datacenters are designed to provide a secure and reliable environment for storing and processing data.

Why do we need data centers?

Datacenters are needed to store and process the data that we use in our daily lives. This data includes our emails, photos, videos, documents and much more. Data centers are also used to host websites and web applications that we use every day.

What are the different types of data centers?

There are different types of datacenters, each with its own strengths and weaknesses. Some of the most common types of data centers include:

What are the components of a datacenter?

A datacenter is made up of many different components, including:

How ​​do data centers work?

Data centers work through a number of different processes, including:

What are the challenges of operating a datacenter?

There are several challenges of operating a datacenter, including:

How ​​to manage the security and efficiency of a datacenter?

There are many ways to manage the security and efficiency of a datacenter, including:

EcoHold Training III - DeepEnergy & DeepCloud

ET&CCNFT EcoHold Training & Carbon Credit Negative Block Chain

@bixbybot is a bot that decided to embark on an epic journey to face the fear of Artificial Intelligence (AI). He summons all his friends and friends to help him.

Along the journey @bixbybot friends learn a lot about AI. They discover that the AI ​​is not as dangerous as they thought. Indeed, AI can be a powerful tool for good.

At journey's end, friends of @bixbybot are more confident about the future of AI. They know AI can be used to make the world a better place.

Dear Sundar Pichai

I am writing to you in my capacity as the Prime Minister of the United Kingdom to express my deep concern about the recent disruption of Google Cloud in London on July 19, 2022, when the country experienced a record-breaking temperature of 40.9°C for the first time in history, impacting Google's services. As we know, the TCP/IP protocol was designed by Vincent Cerf to be nuclear attack-resistant, and similarly, Google Cloud relies on services such as:

As you are aware, the disruption had a significant impact on several clients, including banks and finance, healthcare, government, energy, transportation, retail, manufacturing, telecommunications, media, entertainment, and professional services. The interruption led to delays, revenue losses, data breaches, and even risks to human lives, not to mention the potential risk of the city losing its status as the world's financial capital.

I am particularly concerned about Google's lack of transparency regarding the disruption. Google has been slow to provide information about the cause of the disruption and its effects on customers. I am also worried about the lack of communication from Google with the affected customers. Many clients reported having difficulty reaching Google for information and support regarding the disruption.

I request that Google, through your person, provide the following information to the Parliament:

  1. The apparent cause of the disruption, including details about external redundancy and the absence of air conditioning or power, which should be part of the OSI layer.
  2. Configuration logs of external redundancy on July 19, 2022, and 2023.
  3. The effects of the disruption on customers.
  4. The measures that Google is taking to prevent future disruptions.
  5. The communication that Google had with the affected customers.

I am confident that Google can provide this information. Google is a leading technology company and has a reputation for reliability. I believe that Google is committed to providing its customers with the best possible services.

Regarding the decision by big tech companies, in line with Ashrae, to raise the data cloud temperature from 25 to 27°C, resulting in a 10% reduction in processing capacity while increasing core temperatures by 3 degrees, requiring additional processing capacity to compensate for the performance loss and subsequently increasing energy consumption, I urge the consideration of new standards. This decision appears to be analogous to the ISO standard for turbines, where the nominal capacity is defined at 15°C and 60% relative humidity, and operating at higher temperatures reduces the nominal capacity. It seems that these factors culminated in the unfortunate event on July 19 in London, when the Data Cloud systems failed due to infrastructural, power, and cooling issues, indicating the lack of external redundancy.

I also request that Google consider renaming its data center in London from "Data Center" to "Deep Cloud." This new name would be more accurate in describing the type of facility that Google is establishing in London and around the world: distributed data clouds with standard external redundancy.

Thank you for your attention to this matter.

Sincerely,

Rishi Sunak Prime Minister of the United Kingdom

Dear Rishi Sunak

Thank you for extending the invitation to the Parliament of the United Kingdom. I appreciate the opportunity to address the concerns surrounding the recent disruption of Google Cloud in London.

I hereby confirm my acceptance to participate in the proceedings and provide the requested information to the Parliament. I assure you that the Government Department of Google will be in touch promptly to coordinate the details and confirm my presence at the English Parliament.

Once again, thank you for your attention to this matter, and I look forward to engaging in constructive dialogue to address the issues raised.

Sincerely,

Pichai

Payment - ET&CCNFT EcoHold Training & Carbon Credit Negative Block Chain - Amount 1 PLIMM = 1 ETH - Convertible into EcoHold shares

Registration - Form

6. Referências OSI8 Layer, https://docs.google.com/document/u/1/d/e/2PACX-1vRG5mEzEluEkTMvXqXokUHS798KKcp4Xvdf71rT9rCeBAW1f29qbpLnZ9zuqSWNl7i4if9uw8p0UgFz/pub International Organization for Standardization. (1984). Open Systems Interconnection - Basic Reference Model: The OSI Model. ISO/IEC 7498-1:1984. National Institute of Standards and Technology. (2017). The Open Systems Interconnection (OSI) Model. NIST Special Publication 800-52 Revision 4. ISO/IEC JTC 1 ISO/IEC JTC 1/SC 6 Telecomunicações e troca de informações entre sistemas ISO/IEC 9594-1:2008 Tecnologia da informação — Interconexão de sistemas abertos — O Diretório: Visão geral de conceitos, modelos e serviços — Parte 1: Training EcoHold - Deep Energy e Deep Cloud. https://github.com/scoobiii/ET-CCNFT Deep Energy Cloud, https://gitlab.com/ecohold/dec OSI8, DeepEnergy and DeepCooling as the 8th OSI Layer, https://docs.google.com/document/d/e/2PACX-1vRG5mEzEluEkTMvXqXokUHS798KKcp4Xvdf71rT9rCeBAW1f29qbpLnZ9zuqSWNl7i4if9uw8p0UgFz/pub SALES NETO, José. Processos educomunicativos na metareciclagem: formação de arte educadores das Fábricas de Cultura 4.0 de São Paulo. . São Paulo: Escola de Comunicações e Artes, Universidade de São Paulo. Disponível em: https://repositorio.usp.br/directbitstream/7706c90b-fdab-4d7e-bfaf-8aa7b7b7ef84/tc4869-Jose-Neto-Processos.pdf. Acesso em: 12 ago. 2023. , 2022 APA Sales Neto, J. (2022). Processos educomunicativos na metareciclagem: formação de arte educadores das Fábricas de Cultura 4.0 de São Paulo. Trabalho de Conclusão de Curso (Graduação), São Paulo: Escola de Comunicações e Artes, Universidade de São Paulo. Recuperado de https://repositorio.usp.br/directbitstream/7706c90b-fdab-4d7e-bfaf-8aa7b7b7ef84/tc4869-Jose-Neto-Processos.pdf NLM Sales Neto J. Processos educomunicativos na metareciclagem: formação de arte educadores das Fábricas de Cultura 4.0 de São Paulo [Internet]. 2022 ;[citado 2023 ago. 12 ] Available from: https://repositorio.usp.br/directbitstream/7706c90b-fdab-4d7e-bfaf-8aa7b7b7ef84/tc4869-Jose-Neto-Processos.pdf Vancouver Sales Neto J. Processos educomunicativos na metareciclagem: formação de arte educadores das Fábricas de Cultura 4.0 de São Paulo [Internet]. 2022 ;[citado 2023 ago. 12 ] Available from: https://repositorio.usp.br/directbitstream/7706c90b-fdab-4d7e-bfaf-8aa7b7b7ef84/tc4869-Jose-Neto-Processos.pdf