Services

Specialty Services


Demolition Work with Advanced Machinery and Disposal:

Specialty Services includes Demolition work by most sophisticated machine and disposal, Waterproofing, Cracks, Seepages, Water Management, advice on existing Services Placement on roof.

We provide safe, efficient, and precise demolition services using the most sophisticated machinery. Our specialized equipment ensures that structures are carefully dismantled, minimizing risks to surrounding areas and ensuring that debris is properly managed. Whether it's a partial or full demolition, our team handles the entire process—from planning to disposal—ensuring compliance with environmental and safety standards.

Design-Build Services


Design-build services are an integrated approach to construction that combines both the design and construction phases of a project under a single contract. This method streamlines project delivery by creating a single point of responsibility, which can lead to improved efficiency, cost savings, and faster project completion. The service basically includes new building construction with interiors fitout works.

Key Elements of Design-Build Services:

  1. Single Point of Responsibility:
    • In a design-build contract, the design and construction services are contracted by a single entity known as the design-builder or design-build contractor. This creates a unified workflow from initial concept through completion.
    • The design-builder is responsible for all aspects of the project, including design, permits, construction, and any necessary adjustments or changes during the project lifecycle.
  2. Integrated Project Delivery:
    • The design-build method fosters collaboration between designers, engineers, and builders from the project's inception. This integrated team approach allows for real-time communication, reducing the likelihood of miscommunication and discrepancies.
    • Early collaboration helps identify potential issues or design conflicts before construction begins, allowing for more informed decision-making and streamlined problem-solving.
  3. Cost and Time Efficiency:
    • The design-build approach often leads to faster project completion compared to traditional methods, where design and construction are contracted separately (design-bid-build). Overlapping design and construction phases can expedite project timelines.
    • Cost savings can be achieved through value engineering and better alignment of design and construction goals. The integrated team can optimize materials, methods, and systems to meet both aesthetic and functional requirements while staying within budget.
  4. Risk Management:
    • By consolidating design and construction under one contract, the design-builder assumes the risk for both phases. This reduces the client's exposure to claims and disputes that typically arise when design and construction are contracted separately.
    • The design-build entity is motivated to deliver quality work efficiently since any delays or errors can directly impact their profitability.
  5. Enhanced Communication and Collaboration:
    • Continuous communication between the client, design team, and construction team ensures that all parties are aligned on project goals, timelines, and expectations. This collaborative environment helps avoid misunderstandings and keeps the project on track.
    • Clients are typically more involved throughout the process, receiving updates and having the opportunity to make informed decisions based on the evolving project.

Steps in the Design-Build Process:

  1. Pre-Design Phase:
    • Needs Assessment: Work with the client to understand their requirements, goals, budget, and timeline.
    • Feasibility Studies: Conduct studies to determine project viability, site conditions, and any potential regulatory issues.
  2. Design Phase:
    • Conceptual Design: Develop initial design concepts based on the client's needs and site conditions. This includes preliminary drawings, sketches, and models.
    • Design Development: Refine the design concept into detailed plans and specifications. This phase includes structural, mechanical, electrical, and plumbing design considerations.
    • Client Review and Approval: Present the design to the client for review, feedback, and approval.
  3. Pre-Construction Phase:
    • Permitting and Approvals: Obtain necessary permits and approvals from local authorities and regulatory bodies.
    • Final Cost Estimation: Provide a detailed cost estimate and project timeline, including all materials, labor, and contingencies.
  4. Construction Phase:
    • Project Mobilization: Prepare the site for construction, including setting up equipment, temporary facilities, and safety measures.
    • Construction Execution: Carry out construction activities according to the approved design and schedule. This phase involves ongoing quality control and safety management.
    • Client Coordination: Maintain regular communication with the client, providing progress updates and addressing any concerns or changes.
  5. Post-Construction Phase:
    • Final Inspections and Testing: Conduct final inspections to ensure the project meets all design specifications and regulatory requirements.
    • Project Handover: Deliver the completed project to the client, including all documentation, warranties, and maintenance information.
    • Post-Occupancy Support: Provide support and address any issues that may arise after project completion, ensuring client satisfaction.

Benefits of Design-Build Services:

  • Streamlined Project Delivery: Faster project completion by overlapping design and construction phases.
  • Cost Control: Potential cost savings through value engineering and efficient project management.
  • Improved Quality: Enhanced collaboration and accountability lead to higher-quality outcomes.
  • Reduced Risk: Minimizes disputes and legal risks by consolidating responsibility under a single contract.

Renovations and Restorations - Facade Works


Renovations and Restorations involving facade works are essential for both maintaining the structural integrity of buildings and enhancing their aesthetic appeal. Facade renovation can range from minor repairs and updates to comprehensive restorations that preserve historical significance or modernize the building's appearance.

Key Aspects of Renovations and Restorations - Facade Works

  1. Assessment and Planning:
    • Initial Inspection: Begin with a thorough inspection of the existing facade to assess its condition. Identify issues such as cracks, spalling, water damage, weathering, or structural weaknesses.
    • Historic Review: If the building is of historical significance, research original materials, techniques, and design to ensure any restoration work preserves the building's character and complies with heritage guidelines.
    • Planning and Design: Develop a detailed plan that outlines the scope of work, materials needed, timeline, and budget. This plan should consider both structural and aesthetic aspects, as well as any regulatory requirements.
  2. Types of Facade Renovations and Restorations:
    • Cleaning: Removing dirt, grime, pollution, and biological growth (such as moss or algae) from the facade to restore its original appearance. Methods may include pressure washing, chemical cleaning, or more delicate techniques like micro-abrasion for historic facades.
    • Repair and Patching: Addressing localized damage such as cracks, spalling, or broken masonry. This may involve filling cracks with suitable materials, replacing damaged bricks or stones, or patching concrete.
    • Repointing: Replacing deteriorated mortar in masonry joints with new mortar that matches the original in composition, color, and texture. Repointing helps prevent water ingress and improves structural stability.
    • Replacement of Facade Elements: Replacing deteriorated facade elements like bricks, stones, tiles, or panels with new or reclaimed materials that match the original in appearance and durability.
    • Structural Reinforcement: Installing additional support or reinforcing elements to enhance the structural integrity of the facade. This could involve adding ties, anchors, or frames that help distribute loads and prevent further damage.
    • Restoration of Decorative Features: Preserving or restoring architectural details such as cornices, moldings, carvings, or ornamental ironwork that contribute to the building's character.
    • Modernization: Updating the facade with new materials or designs to improve energy efficiency, aesthetics, or functionality. This could include installing new cladding, glazing, insulation, or external shading devices.
  3. Materials and Techniques:
    • Material Matching: Use materials that match the original in appearance, durability, and composition to maintain the building's aesthetic and structural integrity. For historic restorations, this often involves sourcing traditional materials or using modern equivalents that replicate historical characteristics.
    • Advanced Techniques: Employ modern techniques like 3D laser scanning for accurate documentation, or non-destructive testing to assess underlying conditions without causing further damage. Advanced coatings or sealants may also be used to protect the facade from future damage.
  4. Sustainability Considerations:
    • Energy Efficiency: Incorporate energy-efficient elements such as improved insulation, reflective coatings, or energy-efficient glazing to reduce heating and cooling costs and enhance comfort.
    • Sustainable Materials: Use environmentally friendly materials and processes where possible, such as low-VOC paints, recycled materials, or sustainable wood.
    • Preservation: Restoring rather than replacing materials not only preserves the building's character but also reduces waste and the environmental impact of new material production.
  5. Regulatory Compliance:
    • Building Codes and Standards: Ensure all renovation and restoration work complies with local building codes and standards, including safety regulations and accessibility requirements.
    • Heritage and Preservation Guidelines: For historically significant buildings, follow specific guidelines and obtain necessary permits from heritage conservation authorities to ensure any work maintains the building's historical integrity.
  6. Project Execution:
    • Staging and Access: Set up scaffolding, hoists, and other access equipment to allow safe and efficient work on the facade.
    • Sequencing: Plan work sequences to minimize disruptions and ensure all activities are performed efficiently and safely.
    • Quality Control: Implement a quality control process to monitor the work's progress and ensure that all repairs and restorations meet the required standards.
  7. Post-Renovation Maintenance:
    • Ongoing Maintenance: Develop a maintenance plan to keep the renovated facade in good condition. This may include regular cleaning, inspections, and minor repairs as needed.
    • Monitoring: Use sensors or other monitoring tools to detect issues early, such as moisture ingress or structural movement, to prevent major problems in the future.

Specialized Flooring and Finishes


Specialized flooring and finishes refer to various flooring options tailored for specific needs like durability, aesthetics, and functionality. These include materials like marble, vitrified tiles, granite, and SPC (Stone Plastic Composite) flooring.

Specialized flooring and finishes use advanced materials and treatments used in environments requiring more than standard flooring and wall finishes. These products are selected for their durability, chemical resistance, ease of maintenance, aesthetic appeal, or suitability for specific types of traffic or usage.

  • Marble Flooring: Marble Flooring is known for its luxurious appearance and durability, commonly used in homes due to its cooling properties, especially in warmer regions.
  • Vitrified Tiles: Vitrified Tiles are affordable and come in many designs, making them popular for modern homes due to their low maintenance and stylish look.
  • Granite Flooring: Granite Flooring is highly durable and is often used in areas with high foot traffic due to its strength and resistance to wear.
  • SPC Flooring: SPC Flooring is a relatively new, eco-friendly option gaining popularity in commercial and residential spaces. It offers benefits like water and stain resistance, durability, and ease of installation.

These options are widely used depending on the specific requirements, whether it be for homes, offices, gyms, or showrooms. Each material provides different benefits, from aesthetic appeal to sustainability and cost-effectiveness.

Acoustic Design and Soundproofing


Acoustic Design and Soundproofing are essential components in creating comfortable and functional environments. Acoustic design optimizes the auditory experience within a space, enhancing clarity and minimizing unwanted echoes or reverberations. Soundproofing, on the other hand, focuses on preventing external noise from intruding and stopping internal sounds from escaping, ensuring privacy and reducing distractions. Together, these services help create spaces that balance sound quality and control, fostering comfort, productivity, and privacy in any environment. We have proposed verily of product as per site condition and requirements of client.

Sustainable Construction Practices (Structural and Earthquake Retrofitting)


Structural Retrofitting

Structural retrofitting involves strengthening or modifying existing structures to improve their performance, durability, and safety. This process is often undertaken to meet current codes and standards, repair damage, or adapt a structure for new uses. Retrofitting addresses deficiencies related to seismic activity, wind resistance, load-bearing capacity, or corrosion, ensuring that buildings and infrastructure remain safe and functional.

Earthquake Retrofitting

Earthquake retrofitting enhances the resilience of buildings or structures against seismic activity, ground motion, or soil failure caused by earthquakes. The primary objective is to improve safety and structural integrity, reducing the risk of damage or collapse during an earthquake.

Sealant Work

Sealant work involves applying sealant materials to joints, gaps, or surfaces to block the passage of air, water, or other substances. Commonly used in construction and maintenance, sealants are selected based on factors like flexibility, durability, and environmental resistance, ensuring proper adhesion and functionality. Sealants are typically made from materials like silicone, polyurethane, acrylic, or latex. The application process usually involves cleaning the surface, applying the sealant using a caulking gun or similar tool, and then smoothing or tooling the sealant to ensure proper adhesion and appearance.

Roofing Systems


Roofing Systems are an integral part of any building, consisting of multiple components and layers that provide protection, insulation, and aesthetic appeal. A well-designed roofing system ensures long-term durability and energy efficiency, while safeguarding the structure from environmental factors such as rain, wind, heat, and snow.

Key elements of a roofing system include:

  1. Roof Deck: The foundation of the roof, the deck is the structural base that supports all other roofing materials. It is typically made of plywood, metal, or concrete, depending on the building's design and load requirements.
  2. Underlayment: The underlayment is a water-resistant or waterproof barrier placed directly on the roof deck. It provides an extra layer of protection against water infiltration, especially in areas where shingles or tiles might be compromised. Materials for underlayment can include synthetic, rubberized asphalt, or felt-based membranes.
  3. Insulation: Roofing insulation is essential for regulating a building's internal temperature. By reducing heat transfer, it improves energy efficiency and comfort while lowering heating and cooling costs. Insulation materials vary, including foam boards, spray foam, or rigid panels.
  4. Roof Covering: This is the outermost layer that is visible and provides the primary protection from the elements. Roof coverings can vary widely depending on the climate, building type, and design preferences. Common roof covering materials include:
    • Shingles: Asphalt, wood, slate, or metal shingles are popular choices for residential roofs due to their versatility and durability.
    • Tiles: Clay, concrete, or ceramic tiles are common in regions with hot climates or where aesthetics are a priority.
    • Metal Sheets: Metal roofing, often made from steel, aluminum, or copper, is valued for its strength, longevity, and energy efficiency.
    • Single-Ply Membranes: Popular in commercial buildings, materials like TPO (thermoplastic polyolefin) or EPDM (ethylene propylene diene terpolymer) offer flexibility, UV resistance, and ease of installation.
  5. Flashing: Flashing is installed around roof penetrations (such as chimneys, vents, or skylights) and along roof edges to direct water away from vulnerable areas and prevent leaks. Typically made of metal or rubber, flashing is critical for maintaining the integrity of the roofing system.
  6. Gutters and Drainage: A well-functioning drainage system, including gutters and downspouts, is essential for directing water away from the roof and building foundation, preventing water damage, pooling, and erosion.
  7. Ventilation: Proper roof ventilation is necessary to allow air circulation, reduce moisture buildup, and maintain temperature control in the attic or roofing cavity. Ventilation systems often include ridge vents, soffit vents, or mechanical fans.

Types of Roofing Systems:

  1. Flat Roofing Systems: Commonly used in commercial and industrial buildings, flat roofs require efficient drainage solutions to prevent water accumulation. Materials such as single-ply membranes, built-up roofing (BUR), or modified bitumen are often used for these types of systems due to their waterproofing and durability properties.
  2. Pitched Roofing Systems: More common in residential buildings, pitched roofs are designed to shed water easily. Asphalt shingles, metal roofing, and tiles are popular choices for pitched roofs, offering a balance of aesthetics, durability, and weather resistance.
  3. Green Roofing Systems: These are eco-friendly roofs that incorporate vegetation, creating a sustainable solution that reduces heat absorption, manages rainwater runoff, and enhances insulation. Green roofs are gaining popularity in urban areas as a way to combat the heat island effect and promote biodiversity.

Choosing the Right Roofing System:

Selecting the right roofing system depends on various factors, such as the building's location, climate, design requirements, and budget. A roofing system should be:

  1. Weather-resistant: Able to withstand environmental factors like heavy rain, snow, or high winds.
  2. Energy-efficient: Offering good insulation to maintain temperature control and reduce energy costs.
  3. Aesthetically appealing: Complementing the building's overall design and appearance.
  4. Durable and low maintenance: Designed to last and require minimal repairs over its lifetime.

Fire Protection and Plumbing Systems


Fire Protection Systems:

Fire protection systems are essential for safeguarding buildings, occupants, and assets from the dangers of fire. These systems can be divided into active and passive fire protection measures.

  1. Active Fire Protection Systems: These systems actively detect, suppress, or control fires. They include:
    • Fire Detection Systems: These systems identify the presence of smoke, heat, or flames at the earliest stages. Common detection devices include smoke detectors, heat detectors, and fire alarms. Early detection is crucial for enabling timely evacuation and alerting emergency services.
    • Fire Suppression Systems: These are designed to control or extinguish fires automatically, reducing the need for human intervention. Key suppression systems include:
      • Sprinkler Systems: Automatically activated in response to heat or smoke, sprinklers release water to control or extinguish fires before they spread.
      • Fire Extinguishers: Portable devices containing water, foam, or chemical agents used to combat small fires.
      • Gas Suppression Systems: Often used in areas with sensitive equipment, such as server rooms, gas suppression systems (e.g., CO2 or FM200 systems) extinguish fires without water, reducing the risk of water damage.
    • Fire Alarm Systems: Fire alarms alert building occupants and emergency services to the presence of fire, enabling timely evacuation and response. These systems can be integrated with other fire protection equipment for enhanced safety.
  2. Passive Fire Protection Systems: These measures are designed to contain fires and prevent them from spreading. They are integrated into the structure of the building:
    • Fire-Resistant Materials: Walls, floors, and doors made from fire-resistant materials can contain the fire within a specific area, slowing its spread and providing more time for evacuation and firefighting.
    • Fire Doors and Fire Walls: These create physical barriers that compartmentalize different areas of a building to control the spread of fire and smoke.
    • Smoke Control Systems: These systems include fire dampers and smoke curtains that prevent the movement of smoke through air ducts and other openings, preserving escape routes and minimizing smoke damage.
  3. Fire Safety Planning: In addition to equipment, proper fire safety planning is essential. This includes creating evacuation plans, conducting regular fire drills, and maintaining fire protection systems through periodic inspections and testing.

Plumbing Systems:

Plumbing systems are responsible for the safe and efficient distribution of water and the removal of waste from a building. A well-designed plumbing system enhances the functionality of a building while ensuring public health and safety.

  1. Water Supply Systems: The water supply system ensures clean and potable water is delivered to various parts of the building, including bathrooms, kitchens, and mechanical equipment. Key components include:
    • Cold Water Supply: A network of pipes that distributes cold water from the main supply or storage tanks to taps, showers, toilets, and appliances.
    • Hot Water Systems: These systems provide hot water to fixtures by using water heaters or boilers. The design of the hot water system must account for usage demands and energy efficiency.
    • Pressure Regulation: Pressure-reducing valves are often installed to ensure that the water pressure is maintained within safe levels, preventing damage to pipes and fixtures.
  2. Wastewater and Sewage Systems: The drainage or sanitary system is responsible for the safe removal of wastewater and sewage from the building, preventing contamination and ensuring hygiene:
    • Drainage Pipes: These pipes carry wastewater from sinks, toilets, and other fixtures to the municipal sewer system or a septic tank.
    • Vent Pipes: Ventilation pipes help to regulate the air pressure in the drainage system, preventing sewage gases from entering the building and ensuring smooth water flow.
    • Traps and Seals: Installed under sinks and toilets, traps and seals are designed to prevent sewer gases from entering occupied spaces while allowing water to pass through.
  3. Stormwater and Rainwater Disposal: Effective rainwater management is critical in preventing water damage to the structure and surrounding property:
    • Terrace and Balcony Drainage: Properly designed rainwater outlets and downpipes are essential for removing rainwater from terraces, roofs, and balconies. These systems prevent water pooling, which can lead to leaks, seepage, and structural damage.
    • Stormwater Systems: Stormwater systems manage the flow of rainwater and ensure it is directed away from the building, often to a retention basin, rainwater harvesting system, or drainage network. Stormwater systems are critical in avoiding flooding and waterlogging.
  4. Specialized Plumbing for HVAC Systems: Plumbing systems also include piping for heating, ventilation, and air conditioning (HVAC) systems. This includes chilled water pipes for air conditioning systems and steam or hot water lines for heating.
  5. Maintenance and Regular Inspections: Regular maintenance of plumbing systems is vital to prevent leaks, blockages, and damage. Routine inspections ensure the smooth operation of water supply and drainage systems while preventing costly repairs in the future.

Waterproofing Systems


Waterproofing is a critical aspect of construction that involves applying protective measures to prevent water ingress in buildings and structures. It ensures that structures remain safe, durable, and resistant to water damage.

Site-Specific Product Selection: At SCL Contracts, we understand that the success of any project hinges not only on the quality of application but also on the careful selection of products tailored to site-specific requirements. Our experienced team evaluates each project individually, selecting the most suitable products based on the unique environmental conditions, structural demands, and intended use of the space. This ensures that our solutions are both effective and durable, providing long-term value to our clients.

The Importance of Skilled Application: While many waterproofing manufacturers provide similar materials, the true difference lies in the application process. Our team of experienced applicators ensures that every product is applied with precision and expertise, maximizing the effectiveness and longevity of your waterproofing solutions.

Types of Waterproofing Systems:

  1. Liquid Waterproofing Membranes: This involves applying a liquid coating that cures to form a seamless and flexible waterproof barrier. Commonly used on roofs, balconies, and terraces.
  2. Sheet Membrane Waterproofing: Prefabricated membranes (usually made from bitumen, rubber, or PVC) are applied to the surface to create a waterproof barrier. These membranes are ideal for larger areas, such as foundation walls and basements, as they provide uniform thickness and robust protection.
  3. Cementitious Waterproofing: Cementitious waterproofing involves the use of cement-based materials mixed with waterproofing compounds. This is a common method used in internal wet areas like bathrooms and kitchens as well as in water-retaining structures like tanks, pools, and basements.
  4. Bituminous Waterproofing: Bituminous materials, commonly known as asphalt or coal-tar pitch, are widely used for waterproofing flat roofs, basements, and foundations. Bituminous waterproofing comes in two forms:
  5. Polyurethane Waterproofing: Polyurethane is a highly flexible waterproofing material that offers excellent resistance to moisture and chemicals. It is widely used on roofs, balconies, and terraces due to its ability to form a seamless, durable membrane.

Areas Requiring Waterproofing:

  1. Roofs and Terraces: Roof and terrace waterproofing is critical since these areas are constantly exposed to the elements, such as rain, snow, and extreme heat. Techniques used here include liquid membrane systems, bituminous membranes, and sheet membranes.
  2. Basements and Foundations: Basements are especially prone to water ingress due to their below-ground position. Waterproofing in these areas often involves applying cementitious or sheet membrane waterproofing systems.
  3. Wet Areas (Bathrooms, Kitchens, and Laundry Areas): In internal spaces like bathrooms, kitchens, and laundry areas, waterproofing is essential to prevent moisture from penetrating walls and floors, leading to water damage in adjacent rooms.
  4. Balconies and Decks: Balconies and decks are often subject to water pooling and exposure to rain. Applying liquid membrane or polyurethane waterproofing systems helps prevent water seepage that can cause cracks, leaks, or damage to underlying structures.
  5. Water Retaining Structures (Tanks and Swimming Pools): Waterproofing systems for tanks and pools must withstand continuous exposure to water. Cementitious waterproofing or flexible membranes are used to ensure these structures remain watertight and free from leaks.

Key Waterproofing Challenges:

  1. Expansion and Contraction: Changes in temperature cause materials to expand and contract, which can lead to cracks in waterproofing layers if they are not designed to accommodate such movement. Liquid membranes and flexible coatings are ideal solutions for this issue.
  2. UV Exposure: Sunlight, particularly ultraviolet (UV) rays, can degrade certain waterproofing materials over time. Systems designed for roof applications often include UV-resistant coatings to prolong their lifespan.
  3. Poor Drainage: Even the best waterproofing systems can fail if water drainage is inadequate. Roofs, balconies, and terraces must be designed with proper slopes and drains to prevent water pooling, which can compromise the waterproofing membrane.
  4. Seepage Through Cracks: Small cracks and gaps in concrete can allow water to penetrate the structure. Waterproofing systems must be applied meticulously to ensure that all potential entry points for water are sealed.

Waterproofing Maintenance and Durability

Regular inspections and maintenance are crucial to ensuring the effectiveness of waterproofing systems. Over time, membranes can degrade or become damaged, especially in high-traffic areas or regions with extreme weather conditions. Timely repair and reapplication of waterproofing layers can extend the life of a building and prevent costly repairs due to water damage.

Construction Management of Projects


Construction management is the discipline of overseeing and directing a construction project from start to finish. It ensures that the project is completed on time, within budget, and meets quality standards. The key aspects of construction management include:

  1. Project Planning: Defining the project scope, setting goals, estimating costs, and creating a detailed schedule to guide the project from start to finish.
  2. Resource Management: Efficiently managing labor, materials, and equipment to ensure all resources are available and used effectively throughout the project.
  3. Risk Management: Identifying potential risks that could impact the project, such as delays, cost overruns, and safety issues, and developing strategies to mitigate these risks.
  4. Quality Control: Implementing processes to ensure all construction work meets the required standards and specifications.
  5. Communication: Coordinating among stakeholders, including clients, contractors, suppliers, and regulatory bodies, to ensure clear communication and collaboration.
  6. Safety Management: Ensuring that all safety regulations and best practices are followed to protect workers and the public.

Effective construction management is crucial for the successful completion of construction projects, balancing time, cost, quality, and safety.