Our Services

40-YEAR RECERTIFICATION
What is a 40 year recertification inspection?
When a building is 40 years old, it must undergo an obligatory inspection to make sure it still complies with safety requirements and current building rules, as well as to spot any sections that need to be updated to bring the electrical and structure up to code. You will need to have another inspection performed for the same reason every ten (10) years after that in order to monitor structures and electrical components as they age and are more prone to exhibit indications of degradation.
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ELECTRICAL:
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Condition of electrical equipment
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Electrical violations
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Life-safety
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Photography
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STRUCTURE:
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Condition of structural elements
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Structural damage identification.
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Repair estimate
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Photography

INFRARED THERMOGRAPHY
Need Thermography Inspection Services? We can help you avoid potential breakdowns.
Infrared Thermography can actually see heat and detect potential faults. By using heat-sensing scanners and equipment, Level II infrared thermographer will detect any abnormal temperatures or heat buildup in your operating systems.
Serving MIAMI -DADE COUNTY , BROWARD COUNTY , MONROE COUNTY our thermographic analysis will quickly spot overly high operating temperatures that are the principal cause of failures. This testing is a powerful tool for early problem identification and avoids potential breakdowns. A full report will be supported by high-resolution infrared images, fault locations, temperature information, electrical parameters as well as specific recommendations for correcting any detected problems.
Infrared Thermography has proven to be effective in detecting potentially serious problems including:
Building Roof Leaks
Temperature Fluctuation
Load Current Imbalance
System Overloads
Corroded or Loose Electrical Connections
Bearing Misalignment and Degradation
Deteriorating Wire Insulation
For prompt, reliable infrared maintenance services
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STARTING PRICE $850.

Power and Lighting Construction Design Drawings
Power and lighting construction design drawings, also known as electrical design drawings, are technical documents that provide detailed information about the electrical systems and equipment used in buildings or infrastructure projects. These drawings are typically created by consulting engineers or electrical designers and serve as a guide for contractors and electricians during the construction and installation of electrical systems.
Power and lighting construction design drawings typically include the following elements:
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Electrical Layout
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Power Distribution
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Lighting Design
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Electrical Details
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Schematics
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Load Calculations
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Code Compliance
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Both power and lighting design drawings are essential for ensuring that the electrical systems in a building are properly designed and installed to meet the required codes, standards, and specifications. These drawings provide guidance to contractors for installing electrical systems accurately and efficiently during construction, and serve as a reference for maintenance and operation of the systems after construction is completed. They also help ensure that the electrical systems are safe, reliable, and energy-efficient, and meet the specific needs and requirements of the building or infrastructure project.

Mechanical Design (Air Conditioning)
Mechanical design in the context of air conditioning refers to the process of creating and optimizing the mechanical systems and components that are used in air conditioning and HVAC (Heating, Ventilation, and Air Conditioning) systems. It involves designing and integrating various mechanical elements such as compressors, fans, heat exchangers, ductwork, and controls to create efficient and effective air conditioning systems for a wide range of applications, including residential, commercial, and industrial settings. Mechanical design in air conditioning considers factors such as system performance, energy efficiency, environmental impact, safety, and cost-effectiveness, while adhering to industry standards and regulations. It may involve using computer-aided design (CAD) software, conducting simulations, analyzing performance data, and collaborating with other professionals such as architects, engineers, and technicians to create reliable and optimized air conditioning systems.

Plumbing & Gas Designs
Plumbing & Gas Designs is a specialized service that focuses on the design, installation, and maintenance of plumbing and gas systems in residential, commercial, and industrial settings. This includes the design and installation of pipes, fixtures, and appliances that are used for water supply, drainage, and gas distribution. Plumbing & Gas Designs may also involve the installation and maintenance of heating systems, such as boilers, radiators, and water heaters, as well as gas lines for stoves, ovens, and other gas-powered appliances. The service may also include troubleshooting, repair, and replacement of plumbing and gas systems to ensure their efficient and safe operation. Plumbing & Gas Designs is an essential aspect of construction, renovation, and maintenance projects, ensuring that buildings have reliable and functional plumbing and gas systems for everyday use.

Grease Trap Desing and Calculations
Grease trap design and calculations refer to the process of determining the appropriate size and configuration of a grease trap system for a commercial kitchen or other food service establishment. Grease traps are plumbing devices designed to capture grease, fats, and oils from wastewater generated during cooking and dishwashing activities to prevent their discharge into the sewer system, where they can cause blockages and environmental pollution.
The design of a grease trap involves considering factors such as the flow rate of wastewater, the types and quantities of grease-producing equipment in the establishment, and local regulations and codes. Calculations typically involve determining the grease trap's capacity, retention time, and efficiency based on these factors. Properly designed and sized grease traps can effectively capture grease and prevent it from entering the sewer system, reducing the risk of blockages and environmental harm.
Grease trap design and calculations may be carried out by plumbing engineers, wastewater consultants, or other qualified professionals, and typically follow established guidelines and standards. It is essential to consider local regulations and codes related to grease trap sizing and installation to ensure compliance and proper functioning of the system.

Fire Protection & Fire Alarm Construction Drawings
Fire Protection & Fire Alarm Construction Drawings are detailed graphical representations of fire protection and fire alarm systems that are used by architects, engineers, and contractors to design, install, and maintain fire safety systems in buildings. These drawings typically include information such as the location of fire sprinklers, fire alarms, fire pumps, fire extinguishers, smoke detectors, emergency lighting, and other fire protection equipment. They may also depict the layout of fire-rated walls, doors, and dampers, as well as the routing of fire protection piping, conduit, and wiring. Fire Protection & Fire Alarm Construction Drawings are essential for ensuring compliance with building codes and regulations, coordinating with other trades, and providing a comprehensive plan for fire safety in a building or structure.

Energy & Heat Load Calculations
Energy and heat load calculations refer to the process of determining the amount of energy required to heat or cool a space or a system. It involves mathematical calculations to estimate the amount of energy needed to maintain a desired temperature or condition in a given area or equipment.
Energy load calculations typically take into account various factors such as the size of the space, insulation levels, ventilation rates, outdoor temperature, and desired indoor temperature. These calculations are essential for designing efficient heating, ventilation, and air conditioning (HVAC) systems for buildings, industrial processes, or other applications.
Heat load calculations are used to determine the amount of heat generated within a system or space that needs to be removed to maintain a specified temperature. This can include factors such as heat generated by equipment, lighting, people, and other sources. Heat load calculations are important for designing cooling systems, such as air conditioning or refrigeration, to properly manage heat levels and ensure optimal performance.
Accurate energy and heat load calculations are critical for designing energy-efficient systems, optimizing equipment sizing, and estimating energy consumption and costs. These calculations are typically performed by qualified engineers or HVAC professionals using established standards and software tools to ensure accurate results.

Septic Tank Desing and Calculations
Septic tank design and calculations involve the planning and engineering of a wastewater treatment system that uses a septic tank as a primary treatment component. A septic tank is an underground, watertight container that receives and treats wastewater from a building or facility that is not connected to a public sewer system. It typically consists of two or more chambers with inlet and outlet pipes, and is designed to allow solids to settle and form sludge at the bottom, while allowing clarified liquid to flow out and be further treated in a drainfield or leach field.
Septic tank design and calculations take into consideration various factors such as the size and type of building, the number of occupants, the daily wastewater flow, soil characteristics, and local regulations. The size and configuration of the septic tank, as well as the inlet and outlet pipe sizes, are determined based on the hydraulic retention time required for proper treatment of the wastewater, which includes the settling and decomposition of solids, and the removal of pathogens and harmful substances.
Calculations for septic tank design may include determining the septic tank volume, based on the estimated wastewater flow and retention time, and the pipe sizes required for proper inlet and outlet flow rates. Soil percolation tests may also be conducted to determine the suitability of the site for a drainfield or leach field, and to calculate the size and configuration of the drainfield required for proper dispersal of treated effluent into the ground.
Overall, septic tank design and calculations are crucial for ensuring a safe and effective wastewater treatment system that meets local regulations and protects public health and the environment. It requires careful consideration of various factors and compliance with relevant design standards and guidelines. Consulting with a qualified engineer or wastewater professional is recommended for proper septic tank design and calculations.

Photometric Desing and/or Photometric Reading
Photometric design and photometric reading are related to the measurement and analysis of light.
Photometric design involves the intentional arrangement and specification of light sources in order to achieve desired lighting effects, while considering factors such as illuminance (light intensity), color temperature, color rendering, and distribution of light. It involves selecting and positioning light fixtures, determining appropriate light levels for different areas, and creating lighting plans for indoor and outdoor spaces, taking into account aesthetics, functionality, and energy efficiency.
Photometric reading, on the other hand, involves the interpretation and analysis of photometric data, which is typically represented in photometric files or reports. Photometric data provides detailed information about the performance of a light source, such as its luminous intensity, distribution, and color characteristics. Photometric readings are used to evaluate the quality and effectiveness of lighting systems, assess compliance with lighting standards and regulations, and optimize lighting designs for specific applications or requirements.
Both photometric design and photometric reading are important in the field of lighting design and engineering, as they help ensure that lighting systems are designed, installed, and operated to provide appropriate and optimal lighting solutions for various environments and applications.

Value Engineering
Value Engineering (VE) is a systematic approach used to identify and analyze opportunities to improve the value of a product, process, or system. It involves a multidisciplinary team that examines the functions, components, materials, processes, and costs associated with the subject being evaluated. The goal of Value Engineering is to optimize performance and quality while minimizing costs, ultimately maximizing the value delivered to customers or stakeholders. VE typically involves brainstorming, analysis, and creative problem-solving techniques to identify innovative ideas and solutions that can result in improved performance, increased efficiency, reduced waste, and cost savings. It is commonly used in engineering, construction, manufacturing, and other industries to enhance the value proposition of products or projects by balancing performance, quality, and cost considerations.

Emergency Backup Generator Design
Emergency backup generator design refers to the process of creating a system that provides electrical power during times of power outages or emergencies. This design typically involves selecting an appropriate generator, determining its capacity based on the power needs of the facility or area, designing the fuel storage and delivery system, integrating the generator with the existing electrical system, and ensuring compliance with relevant codes and regulations. The goal of emergency backup generator design is to create a reliable and efficient system that can provide uninterrupted power supply during emergencies, ensuring critical operations can continue without disruption.

Permitting
Permitting in consulting engineering refers to the process of obtaining the necessary approvals, permits, and licenses from relevant authorities for construction, renovation, or other engineering projects. Consulting engineers work closely with clients, architects, and regulatory agencies to ensure that projects comply with local, regional, and national regulations, codes, and standards.
The permitting process typically involves preparing and submitting detailed engineering plans, environmental impact assessments, and other documentation to obtain permits for various aspects of the project, such as building permits, environmental permits, zoning permits, and utility permits. Consulting engineers may also need to conduct site visits, coordinate with stakeholders, and address any concerns or issues raised by regulatory agencies during the permitting process.
Permitting is a critical step in the consulting engineering process as it ensures that projects are legally compliant, environmentally responsible, and safe for construction and operation. Consulting engineers play a key role in navigating the complex landscape of permits and approvals, helping clients achieve their project goals while adhering to all relevant regulations and requirements.

Private Provider
A Private Provider in Consulting Engineering refers to an individual or a firm that offers specialized engineering consulting services to private clients. These services typically involve providing expert advice, analysis, and solutions for engineering projects in various sectors, such as civil, structural, mechanical, electrical, environmental, and others. Private Providers in Consulting Engineering work directly with private clients, which may include individuals, corporations, non-profit organizations, or government agencies, to understand their unique engineering needs and develop customized solutions to meet their requirements. They may offer a wide range of services, including feasibility studies, design and planning, construction management, project coordination, and quality assurance. Private Providers in Consulting Engineering operate independently and are not affiliated with any governmental or regulatory body. They are hired by private clients to provide technical expertise, innovation, and strategic guidance for engineering projects, ensuring that they are executed efficiently, effectively, and in compliance with relevant laws and regulations.