Road, highway and resindetial constructions

When we’re managing a construction job there are certain objectives you should consider. You reach them in stages. Just like in any project, you accomplish it by breaking it down. The following are four steps you can take to organize a successful construction project management project.

Design

There are four parts to designing a construction project. It’s the responsibility of the project manager to make sure your design meets with building codes and other regulations.

1. The concept. What are the needs, goals and objectives of the project? You’ll be making decisions based on the size of the project, the site allocated for the build and the actual design of what your building. This is comprised of a list for each room or space under consideration, including all critical data.
2. The schematic design. This is a sketch that identifies all the various parts, materials, sizes, colors, textures, etc. It includes the floorplan, elevations, etc., even a site plan.
3. Develop the design. This requires research. What are the materials to use? What equipment will be needed? How much are the materials? You’ll be refining the original drawings from the previous stage now to reflect these decisions. Knowing local building codes and adhering to them will be important at this stage.
4. Get the contract documents together. These are the final drawing and construction specs. These will be used by outside contractors to bid on the job.

Waste Power plant

In a world with a growing population and consumption there is a pressing need to use our resources in the best possible way. This involves reducing the generation of waste, ensuring high-quality recycling and using residual waste for efficient and clean energy generation. 

Pars commerce and consult (PCC) is globally renowned consultant within waste management in general and Energy from Waste in particular. This position has been obtained through a long list of successfully completed projects where PCC has been responsible for the planning, consulting and engineering, procurement and contract management of waste management facilities. 

• Waste strategy development
• Technology assessments (including gasification, pyrolysis etc.)
• Feasibility studies, business case  preparation
• Technical due diligence of projects and technologies
  
• Design and layout
• Risk and opportunity assessment
• Project structuring and procurement planning
• Value engineering
• Preparation of technical specifications and tender documents
• Evaluation of proposals, negotiations and contract closure
• Contract management
• Supervision and inspection during design, construction and commissioning
• Site management

BENEFITS

• Reduction of carbon emissions.
• Reduction of the use of fossil fuels.
• Electricity and heat can be generated from waste which provide an alternative and more environment-friendly source of energy.

Trash To Treasure: The Benefits of Waste-To-Energies Technology

Using landfill waste to produce energy generates less greenhouse gases than simply letting the waste decompose. The study highlights the benefits of food waste as a potential source of energy.

Solar Power plants

Solar radiation may be converted directly into electricity by solar cells (photovoltaic cells). In such cells, a small electric voltage is generated when light strikes the junction between a metal and a semiconductor (such as silicon) or the junction between two different semiconductors. (See photovoltaic effect.) The power generated by a single photovoltaic cell is typically only about two watts. By connecting large numbers of individual cells together, however, as in solar-panel arrays, hundreds or even thousands of kilowatts of electric power can be generated in a solar electric plant or in a large household array. The energy efficiency of most present-day photovoltaic cells is only about 15 to 20 percent, and, since the intensity of solar radiation is low to begin with, large and costly assemblies of such cells are required to produce even moderate amounts of power.

Small photovoltaic cells that operate on sunlight or artificial light have found major use in low-power applications—as power sources for calculators and watches, for example. Larger units have been used to provide power for water pumps and communications systems in remote areas and for weather and communications satellites. Classic crystalline silicon panels and emerging technologies using thin-film solar cells, including building-integrated photovoltaics, can be installed by homeowners and businesses on their rooftops to replace or augment the conventional electric supply.

Our partner in Solar Power

We are happy to introduce our cooperative partner in solar power energy SSDA in Spain.

When it comes to climate protection and sustainable energy saving, we can help not only for large-scale systems on industrial roofs, open spaces (commercial and industrial), but also for private households.

We offer you proven quality "Made in Germany" in the field of photovoltaics (open space systems, roof systems, carports, terrace structures, corresponding frames, modules, inverters, cables, battery storage systems, electric car charging stations, etc.) with guarantees and performance guarantees of up to 30 years.

With our experienced international partners from various trades, we plan your energy system according to your wishes or give you recommendations for implementation.

Reduce your electricity consumption with your own natural power plant. Fast amortization times through consistent cost reduction with very good product quality.

We take advantage of the many years of expertise and technical competence of the photovoltaic professionals around the world for solving your energy issues.

About us

      SSDA has been concerned with energy saving and energy efficiency since 1995. At that time nobody spoke about climate protection, climate change, increasing storm phenomena and natural disasters in our latitudes. Our entrepreneurial orientation was right back then. In the beginning, we subordinated the areas of energy efficiency and nature conservation to property construction. The focus was on avoiding unnecessary costs through improved building insulation and the use of the latest heating technology. We installed the first photovoltaic system in 2001.

Working in the photovoltaic sector did not only increase awareness of the energy transition in Germany in the following years, but also in other European countries, where we have transferred our knowledge and skills.

Competences

     SSDA has been building photovoltaic systems since 2001. We are trained photovoltaic expert (TÜV) and has been building a network of experts and specialists. Together with our colleagues, we also created damage reports and documentation of the extent of damage for new and existing photovoltaic systems, acceptance tests, yield forecasts, mobile power measurements of photovoltaic systems in operation, thermography of solar modules, generator junction boxes and other electrical components.

    Thanks to this homogeneous network that has grown over the years, we have the necessary "men power" to meet individual customer requirements in the field of photovoltaics, stationary battery storage systems and charging infrastructure.

Services

    Our team and the partner companies support you in the following tasks:

- Planning support and advice on funding programs and funding.

- Delivery and installation of complete photovoltaic systems with connection to feed-in meters.

- Construction supervision during the construction of photovoltaic systems of all kinds.

- Creation of damage reports and damage documentation.

- Acceptance tests, preparation of yield forecasts.

- Mobile power measurement of photovoltaic systems in operation or new systems.

- Thermography of solar modules, device connection boxes and other electrical components.