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Our Work

Here is the glimpse of our various projects made by our JM teams. 

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3D MODEL OF "VENTURE" ACCOMODATION AND WORK BARGE

Scale: 1:100

Size: 970mm X 250mm

Manufacturing time: 30 days.

A venture accommodation and work barge ship is a type of vessel that is designed to provide temporary living and working accommodations for crews working on offshore projects such as oil and gas exploration or wind farm construction. These vessels are essentially floating hotels and office spaces that can accommodate a large number of crew members for extended periods of time.

The venture accommodation and work barge ship typically consists of several levels or decks, with the lower levels dedicated to machinery and storage and the upper levels equipped with living quarters, dining areas, and offices. The vessel is usually equipped with generators, water treatment facilities, and other systems necessary to sustain a large crew for extended periods of time.

In addition to providing accommodations, the venture accommodation and work barge ship can also be used to transport personnel and equipment to and from offshore work sites. The vessel is equipped with cranes and other lifting equipment to facilitate the loading and unloading of cargo, and may also have a helipad for helicopter transport.

One of the key benefits of using a venture accommodation and work barge ship is that it allows crews to work in remote offshore locations without the need for frequent trips back to shore. This can save time and money, and also increase safety by reducing the need for crew members to travel long distances in smaller vessels.

Overall, the venture accommodation and work barge ship is a versatile and essential tool for offshore projects that require a large and sustained presence at sea. These vessels are designed to provide comfortable and functional living and working accommodations for crews, while also serving as a transportation hub and command center for complex offshore operations.

3D MODEL OF KAKINADA GATEWAY PORT

The Kakinada Gateway Port is a major seaport located in the state of Andhra Pradesh, India. A 3D model of the port can be a useful tool for various purposes, such as planning, analysis, and visualization.

To create a 3D model of the Kakinada Gateway Port, several steps need to be followed. First, data about the port's infrastructure, including buildings, docks, cranes, and other facilities, should be collected. This data can be obtained through various sources, such as project's client, google references and ground surveys.

Next, the collected data can be processed and converted into a digital format, such as PDF, CDR and CAD format. The digital data can then be imported into a 3D modeling software, such as SketchUp, 3ds Max, or Blender.

In the 3D modeling software, the digital data can be converted into a 3D model by adding textures, materials, and lighting effects. The model can also be scaled and adjusted to accurately represent the real-world dimensions of the port.

The final 3D model can then be used for various purposes, such as simulating different scenarios, visualizing the port's layout and facilities, and planning for future development and expansion.

Overall, a 3D model of the Kakinada Gateway Port can be a valuable tool for port operators, planners, and stakeholders, providing a detailed and accurate representation of the port's infrastructure and facilities.

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Scale: 1:2000

Size: 11.25 X 7.25 ft

Manufacturing Time: 100 days

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3D HEAT EXCHANGER

Scale:1:40 

Size: 1200mm X 600mm X 900mmht

Manufacturing time: 20days

A 3D heat exchanger model is a computational representation of a physical heat exchanger that is used to simulate the transfer of heat between fluids. Heat exchangers are used in a wide range of industrial applications, including power generation, chemical processing, and HVAC systems.

The 3D heat exchanger model typically consists of a set of interconnected tubes or channels through which fluids flow, separated by a solid boundary that conducts heat between the fluids. The model takes into account various physical parameters such as flow rates, temperatures, pressures, and thermal conductivities to simulate the heat transfer process.

One of the key advantages of using a 3D heat exchanger model is the ability to accurately predict the performance of the heat exchanger under different operating conditions. This can help engineers optimize the design of the heat exchanger and improve its efficiency.

To create a 3D heat exchanger model, engineers typically use specialized software tools that can simulate fluid dynamics and heat transfer. The software allows them to create a virtual model of the heat exchanger and simulate the flow of fluids through it, taking into account various physical parameters such as fluid properties, flow rates, and heat transfer coefficients.

Once the model is created, engineers can analyze the results to determine the heat transfer rate, pressure drop, and other parameters that are important for optimizing the performance of the heat exchanger. They can also use the model to test different design configurations and operating conditions to determine the most efficient and cost-effective solution.

Overall, a 3D heat exchanger model is a powerful tool for engineers to optimize the design and performance of heat exchangers in a wide range of industrial applications. By accurately simulating the heat transfer process, engineers can improve the efficiency and reliability of these critical components, leading to significant cost savings and improved performance.

NIBE DEFENCE AND AEROSPACE LIMIED

Scale: 1:200

Size: 1100mm X 800mm X 200mm ht max

manufacturing time: 15 days

Creating a 3D model of a defence and aerospace plant can be a complex and challenging task, but it is an essential tool for planning, analysis, and visualization. At our 3D modeling company, we specialize in creating high-quality 3D models of defence and aerospace plants that accurately represent the facility's infrastructure and equipment.

To create a 3D model of a defence and aerospace plant, we typically use a combination of techniques, including laser scanning, photogrammetry, and drone mapping. These techniques allow us to collect accurate data on the plant's buildings, machinery, and other infrastructure.

Once we have collected the data, we use advanced 3D modeling software to create a detailed and accurate 3D model. Our team of experienced 3D model makers uses the latest software and tools to create realistic textures, materials, and lighting effects that bring the model to life.

In addition to creating a 3D model of the plant's infrastructure, we can also simulate different scenarios, such as emergency response, equipment failure, and maintenance procedures. This allows plant operators and personnel to plan and prepare for various situations, improving safety and efficiency.

Our 3D models can also be used for training purposes, allowing personnel to familiarize themselves with the plant's layout and equipment before starting work. This can be particularly useful for new employees or for personnel who need to work in different areas of the plant.

At our 3D modeling company, we are committed to delivering high-quality work that meets our clients' needs and exceeds their expectations. We pride ourselves on our attention to detail, timely delivery, and exceptional customer service. If you need a 3D model of a defence and aerospace plant, we have the expertise and resources to deliver the results you need.

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3D MODEL OF DIVIJA OLD AGE HOME

Scale: 1:100

Size: 1000mm X 1000mmX 600mmht

Manufacturing Time: 15 days

This old age home is developed by Swastik foundation in Sindhudurg. Old age home is for the elders whose families have abandoned them.

Creating a 3D model of an old age home can be a great way to visualize the layout and design of the building. Here are some steps that a 3D modeler might take to create a 3D model of an old age home:

1. Gather information: Start by gathering as much information as possible about the old age home you want to model. This might include floor plans, elevation drawings, photographs, and any other relevant information.

2. Choose a software: Select a 3D modeling software that you are comfortable working with. Some popular options include SketchUp, Blender, and AutoCAD.

3. Create the base: Begin by creating the base of the building. This can be done by drawing the floor plan in the software or importing it from another source.

4. Build the structure: Using the floor plan as a guide, begin building the walls, roof, and other structures of the building. Pay attention to details like the height of the ceilings, the placement of doors and windows, and any unique architectural features.

5. Add furniture and fixtures: Once the structure is in place, start adding furniture and fixtures to the model. This might include beds, chairs, tables, and other items that would be found in an old age home.

6. Add textures and colors: To make the model more realistic, add textures and colors to the building and furniture. Use reference images to ensure that the colors and textures are accurate.

7. Add lighting: Lighting is an important element in any 3D model. Add lights to different parts of the building to create a realistic effect.

8. Test the model: Once the model is complete, test it to make sure that everything is working as expected. Make any necessary adjustments to the model.

9. Render and present: Finally, render the model to create a high-quality image or animation. This can be used to present the model to others and to promote the old age home.

Remember, creating a 3D model of an old age home requires attention to detail and accuracy. By following these steps and using reference materials, you can create a realistic and informative model that showcases the design and layout of the building.

3D MODEL OF KAKINADA GATEWAY PORT

The Elimina Palm 3D Ship Model is a detailed representation of a ship's design and construction specifications. The model encompasses various structures, including the main hull made of Fiber Reinforced Plastic (FRP), the main superstructure, small units, crane, Antennas etc made of acrylic.


The main hull of the ship is constructed using Fiber Reinforced Plastic (FRP). FRP is a composite material that provides excellent strength, durability, and corrosion resistance. The construction of the main hull involves the following specifications:
- Dimensions: The hull dimensions will be accurately represented in the model, as per the ship's design.
- FRP Thickness: The FRP thickness will be according to the ship's specifications, ensuring structural integrity and safety.
- Hull Shape: The model will capture the exact shape and contours of the main hull, including any protrusions, curvatures, or design features.
The ship model will incorporate antennas as per the ship's design. The specifications for the antennas include:
- Placement: The antennas will be positioned accurately on the ship model, following the original design.
- Design Details: The model will capture the intricate details of the antennas, representing their shape, size, and orientation.
- Materials: The antennas will be constructed using appropriate materials to ensure durability and visual accuracy.

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Scale: 1:200

Size: 1000mm X 350 mm

Manufacturing Time: 30 Days

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Waste Management - recycle system.

Scale:1:40 

Size: 1900mm x 900 mm x 350 mm

Manufacturing time: 45 Days

A 3D heat exchanger model is a computational representation of a physical heat exchanger that is used to simulate the transfer of heat between fluids. Heat exchangers are used in a wide range of industrial applications, including power generation, chemical processing, and HVAC systems.

The 3D heat exchanger model typically consists of a set of interconnected tubes or channels through which fluids flow, separated by a solid boundary that conducts heat between the fluids. The model takes into account various physical parameters such as flow rates, temperatures, pressures, and thermal conductivities to simulate the heat transfer process.

One of the key advantages of using a 3D heat exchanger model is the ability to accurately predict the performance of the heat exchanger under different operating conditions. This can help engineers optimize the design of the heat exchanger and improve its efficiency.

To create a 3D heat exchanger model, engineers typically use specialized software tools that can simulate fluid dynamics and heat transfer. The software allows them to create a virtual model of the heat exchanger and simulate the flow of fluids through it, taking into account various physical parameters such as fluid properties, flow rates, and heat transfer coefficients.

Once the model is created, engineers can analyze the results to determine the heat transfer rate, pressure drop, and other parameters that are important for optimizing the performance of the heat exchanger. They can also use the model to test different design configurations and operating conditions to determine the most efficient and cost-effective solution.

Overall, a 3D heat exchanger model is a powerful tool for engineers to optimize the design and performance of heat exchangers in a wide range of industrial applications. By accurately simulating the heat transfer process, engineers can improve the efficiency and reliability of these critical components, leading to significant cost savings and improved performance.

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