The House in Mukteshwar, Uttarakhand

The House in Mukteshwar, Uttarakhand

Sruthin Vijay

Optimizing heating and cooling in buildings is essential for creating comfortable, energy-efficient, and sustainable spaces. It involves designing systems and strategies that regulate indoor temperatures effectively across different seasons. By minimizing reliance on mechanical systems, this approach reduces energy consumption, operational costs, and environmental impact. The House in Mukteshwar, Uttarakhand, in collaboration with Habitat Tectonics Architecture & Urbanism (HTAU), focused on optimizing heating and cooling requirements.

The project began with a detailed climate analysis and base modelling using Rhino and Grasshopper. It enabled an understanding of thermal behaviour and identify key design interventions. Given the predominantly cold climate of Mukteshwar, a balance of passive and active strategies was essential. The passive strategies involved enhanced insulation for walls and windows. This reduced heat loss during winters. Shading devices were designed to block summer heat. They also permitted beneficial winter sunlight. Ventilation pathways were optimized to promote cross-ventilation. Thermal mass materials were incorporated to naturally stabilize indoor temperatures.

The design process began with an in-depth analysis of the site’s cold climatic patterns and solar exposure. Window design played a crucial role in the overall thermal performance. Windows with perforated panels were considered for the living room to reduce direct heat gain. In the studio, additional windows were installed to enhance ventilation. The switch from double-glazed units (DGUs) to single-glass windows during winter was discussed, highlighting potential thermal performance concerns. For winter, the optimized design allowed the house to rely on a single mechanical heating system. This eliminated the need for separate cooling and heating systems, reducing both installation and operational costs.

Active strategies rely on mechanical systems like heating, ventilation, and air conditioning (HVAC) to control indoor climates. These systems offer flexibility in managing temperature variations. However, they can be energy-intensive and expensive to operate. For this project, a hybrid HVAC system was adopted. It utilized a heat pump combined with a Yunca wood-powered heater. This approach provided backup heating in case of power outages. Passive strategies, combined with the HVAC system and solar power, reduced the net-Energy Performance Index (EPI).

The HTAU House project exemplifies how balancing active and passive strategies can create sustainable, adaptable buildings. By addressing the specific needs of each season, the design achieved year-round comfort with minimal energy input. This approach not only enhances energy efficiency but also reduces the environmental impact of buildings.

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Building Retrofit for Deki Electronics at Noida

Cooling Requirement of a Factory Building in Noida

Building Retrofit for Deki Electronics at Noida

Sruthin Vijay

Monk Spaces conducted a building retrofit project for the Deki Electronics factory in Noida in collaboration with Ant Studio. This project focused on identifying improvement opportunities through a data-driven analysis of cooling loads and surface temperatures. This comprehensive approach aimed to reduce energy consumption and improve indoor environmental quality.

The process began with documenting the existing building, including plans, sections, location of openings, and building materials used. The building was modelled using Rhino. Iterative building energy simulations were performed using Ladybug and Honeybee tools to match the actual scenario. The potential benefits of a double skin on the factory were explored. Additionally, the solar generation potential of the rooftop was quantified.

The recommendations stemmed from the comprehensive analysis focused on improving the building’s performance. They aim to increase ventilation rates through a dedicated outdoor air system (DOAS) to ensure better indoor air quality. The analysis also recommended replacing windows with Fixed Double-Glazed Units (DGUs) to enhance thermal insulation. Additionally, it suggested installing insulated partitions with enhanced thermal insulation to help maintain consistent indoor temperatures.

The project effectively showcased that retrofit projects offer a sustainable alternative to demolition and rebuilding for modernization. The suggested measures would reduce the quantity of materials needed, further reducing the embodied carbon footprint. The factory’s thermal comfort and energy efficiency would be enhanced. This improvement also reduces the operational carbon footprint and running costs for the factory.

Weekly Cooling Requirements
Weekly External Surface Temperatures

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JSW Hospital Design

Passive Design Optimisation for a Hospital in Angul, Odisha

Sruthin Vijay

Monk Spaces undertook passive design optimisation for the JSW Hospital proposed in Angul, Odisha, in collaboration with Space Matters. The goal of the project was to achieve high performance and sustainability. The project emphasised passive design optimisation to maximise sustainability, reduce energy consumption, and enhance comfort. The feasibility of getting the Indian Green Building Council (IGBC) Green Hospital certification was also evaluated.

The project commenced with a detailed climate analysis for the hospital. The aim was to understand local conditions and thoroughly inform subsequent design strategies. This analysis laid the groundwork for several critical tasks, including simulations using Ladybug and Honeybee tools. Thereby, two massing options developed by Space Matters were evaluated. These simulations were crucial in assessing hourly indoor temperatures and heat gain on each facade. They provided essential data necessary to guide design decisions effectively. Subsequently, further analyses concentrated on developing shading options, recommending window-to-wall ratios (WWR), and insulation strategies.

The recommendations involved mandatory horizontal and vertical shading. They aimed to reduce solar heat gain and enhance indoor comfort on the southern and western facades. Additionally, proper insulation was advised to maintain thermal comfort and reduce energy consumption. Double-glazed units were suggested to improve both thermal and acoustic insulation. The optimal WWR was recommended to balance natural lighting with thermal performance.

The design interventions were critical to achieving a high-performance, sustainable hospital facility that adhered to rigorous environmental standards. After implementing the interventions, an evaluation was conducted to assess the project’s feasibility for IGBC rating. In conclusion, the project ensured informed, sustainable design decisions, maximising hospital comfort and efficiency. The project emphasised passive design optimisation by prioritising high performance and sustainability. The thorough climate analysis and implementation of crucial design interventions could significantly enhance contemporary sustainability benchmarks. The IGBC certification possibilities were explored as a bonus study in the project. Thus, the project showcases the importance of passive design optimisation in the building sector.

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Evaluation Of A Double Skin Facade in terms of Energy, Carbon and Costs

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Monk Spaces evaluated a mixed-use building in Raipur in collaboration with Ant Studio. This study focused on quantifying the benefits of implementing a double-skin facade system. The performance evaluation encompassed several key metrics, including the capital cost of the HVAC system (Heating, ventilation, and air conditioning), building Energy Performance Index (EPI), carbon payback, economic payback, and the required air conditioning hours. The aim was to determine the comprehensive impact of the double-skin facade on its performance in terms of economic and environmental costs.

The study considered variations in the façade’s design to evaluate multiple options. These variations were defined in terms of some parameters. These parameters included the following:

  • Distance between the primary facade and the double-skin
  • Possibility of opening windows in the facade
  • Provision of water flow
  • Temperature of the water flow

These parameters were varied to understand how they could optimize the building’s energy performance and cost efficiency. Adjusting the distance between the facade and double skin was seen to impact insulation and airflow, while window openings affect natural ventilation. Water flow provisions enable passive cooling or heating, and controlling water temperature influences thermal comfort.

The isolated benefit study highlighted the double skin facade’s potential for operational cost savings and capital cost reductions. It also led to an understanding of incremental embodied carbon due to constructing the façade for operational carbon savings. By carefully considering the impact of the variable parameters on performance, the study provides a comprehensive understanding of how to optimize the design and implementation of double-skin facades for enhanced building performance and sustainability.

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Balacing heating and cooling requirements

Optimizing Heating and Cooling Requirements

Mili Jain

Project: Residential
Location: Mukteshwar, Uttarakhand

Most of the North Indian plains experience hot summers and cold winters. In such situations, passive strategies that are beneficial in one weather can create problems in the other. It becomes imperative to ensure that this is balanced, even for residential buildings.

For the example shared here, the passive strategies are optimized to minimize the number of hours that the house needs cooling. This makes it possible for the house to only need one mechanical system for heating. This helped in managing incremental costs.

Balacing heating and cooling requirements

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With a need to have a strong colour rendition, retail stores have high lighting loads. Bringing this down requires maximising daylight wherever possible. It also requires a spatial change in terms of putting the circulation next to the windows.

 

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