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awesomesakshi1992 · 4 years

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Technological Advances to Assist Better Global 3D Concrete Printing Market Growth; Gain Deeper Insights through MRFR’s Study Report

3D concrete printing, an innovative construction method is used to fabricate building and construction components. It is basically, a robotic system used for fabricating various building components such as walls, roofs, lintels, and several others. 3D concrete printing technology promises greater advantages in the construction field, such as faster construction process, lower labor costs, and efficient use of raw materials with less wastage.

3D concrete printing allows architects to design and build complex concrete architectural and structural elements, deliver personalized & customized solutions, while, controlling the cost & time required to market, freeing them from the restrictions of standardized framework. Additional advantages of 3D concrete printing include savings on cement usages and construction close to where it is needed and in inaccessible areas, less arduous, and less dangerous worksites.

3D concrete printers are capable of fabricating objects that are challenging/ difficult or impossible to be manufactured through conventional construction processes. 3D concrete printers are convenient for achieving faster, safer, and environment-friendly construction buildings. 3D Concrete printing method is based on a digital model and hence, allows the implementation of various complex designs in the construction applications.

Over the past few years, the 3D concrete printing market is growing rapidly, mainly due to the increasing uptake of the technology in the burgeoning construction industry. The rapid growth in the construction sector across the globe is increasing market demand. According to Market Research Future (MRFR), gains of the global 3D concrete printing market would reach to USD 69.9 MN by 2023, registering a CAGR of 14.05% throughout the forecast period (2018-2023).

The primary factor propelling the market growth is the high precision and efficiency of 3D concrete printing process over traditional construction method. Moreover, advantages that the 3D concrete printing technology provides a construction project to increase its popularity among the construction companies and fuel the demand in the market.

On the other hand, lack of awareness towards the benefits of 3D concrete printing technology may hamper the growth of the market. Using 3D printing in construction can reduce the material wastages, significantly, thereby reducing the overall project cost. These superior advantages over traditional construction process would support the growth of the 3D concrete printing market over the review period.

Global 3D Concrete Printing Market – Segmentation

The report segments the market into four key dynamics to widen the scope of understanding,

By Concrete Type : Precast Concrete, Shotcrete, Ready Mix Concrete, and High-density Concrete, among others.

By Application : Residential, Industrial, and Agricultural, among others.

By End-use : Walls, Roofs, Floor, and Staircase, among others.

By Regions : Asia Pacific, North America, Europe, and the Rest-of-the-World.

3D Concrete Printing Market Regional Analysis

North America dominates the global 3D concrete printing market. In the year 2016, the market was valued at USD 10.0 MN and accounted for the largest as in 35.63% of the market share. The 3D concrete printing market in North America is projected to grow at a CAGR of 14.20% throughout the forecast period (2018-2023).

Growing consumer preference for green buildings and constant investments in commercial real estate are some of the major factors acting as a tailwind for the growth of the regional market. The US is the largest market for 3D concrete printing in the North American region.

The 3D concrete printing market in the European region stands second in the global space. In 2016, the share of the region in the global 3D concrete printing market reached to 29.4%, while its market value reached USD 82 MN. The European 3D concrete printing market is projected to grow at a CAGR of 13.20% during the forecast period.

The Asia Pacific 3D concrete printing market is rapidly emerging as a profitable market, globally. In 2016, the value of the regional 3D concrete printing market had reached over USD 6 MN, which is further expected to grow at a CAGR of 14.51%. Rapid urbanization and industrialization alongside, the increasing purchasing power of consumers in the region drive the growth of the APAC market.

Moreover, spreading awareness towards the advantages of 3D printing technology, increasing environmental concern, and the augmenting demand and activities in the construction sector foster the 3D concrete printing market in the region. The APAC region is expected to grow briskly over the forecast period.

Global 3D Concrete Printing Market _ Competitive Analysis

Highly competitive, the 3D concrete printing market appears to be fragmented due to the presence of several big and small-scale players. These players focus on optimizing situational awareness to ensure their mission success. They adopt various strategic initiatives such as M&A activities, collaboration, and innovations, seeking market expansion constantly.

These players possess state-of-the-art facilities to develop software and strong sales and distribution network, which can help them to gain a leading position in the market. Focused on inbound lead generation increasingly, marketers operating in the market look for ROI-oriented strategies that can pay off quickly.

Major Players:

Key players leading the global 3D concrete printing market include Winsun Global (China), Dus Architects (the Netherlands), Skanska AB (Sweden), Foster + Partners (London), Cybe Construction (the Netherlands), Sika AG (Switzerland), LafargeHolcim Ltd (Switzerland), HeidelbergCement AG (Germany), Apis Cor (Russian Federation), and Balfour Beatty (US), among others.

Industry/ Innovation /Related News:

June 18, 2019 --- VINCI Construction (France), a leading global Construction engineering company, launched its new subsidiary named Concreative focused on the 3D printing of high-performance concrete. Concreative is a subsidiary set up to develop 3D printing solutions for high-performance concrete. The firm also announced the inauguration of the first 3D concrete printing factory in Dubai to serve a fast-growing construction market in the middle east.

VINCI offers a fully integrated service, from design to on-site installation. Concreative is originated from the Leonard intrapreneur program, VINCI's forward-looking innovation laboratory. The new entity uses a technology patented by VINCI's technology partner, XtreeE, a start-up in which VINCI Construction is also a shareholder. The technology consists of extruding concrete layer by layer, with each layer printed via a digitally controlled nozzle.

#3D Concrete Printing Market

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limelightcreativeservices · 6 years

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Architectural Designer Dubai, UAE.

Architectural Designer Dubai

visit website: http://limelight.ae/

The techniques of architecture in the sense that they will be considered here are simply the methods by which structures are formed from particular materials. These methods are influenced not only by the availability and character of materials but also by the total technological development of society, for architecture depends on an organized labour force and upon the existence of the tools and skills necessary to secure, manufacture, transport, and work durable materials.

The evolution of techniques is conditioned by two forces. One is economic — the search for a maximum of stability and durability in building with a minimum of materials and labour. The other is expressive — the desire to produce meaningful form. Techniques evolve rapidly when economic requirements suggest new expressive forms or when the conception of new forms demands new procedures. But they remain static when architects avoid the risk of pioneering with untried and possibly unsuccessful methods and depend instead on proved procedures or when the need for the observance of tradition, for the communication of ideas, or for elegance and display is best fulfilled by familiar forms.

The ultimate purpose of building techniques is to create a stable structure. In mechanical terms, structures are stable when all their parts are in a state of equilibrium, or rest. Walls and roofs can buckle, crack, or collapse if they are not properly designed. These movements are caused by forces that tend to push or pull bodies in a given direction. Forces acting on any member (part) of a building are, first, its own weight and, second, the loads it carries, principally from other members but also from persons, furnishings, wind, etc. Their action encounters a reaction in opposing forces that hold the member in place by resisting at its joints. These forces may be active in all directions, and they must be balanced for stability. They tend to crush, pull apart, and bend the member — in other words, to change its size and shape.

Within the member itself there are forces, too, that tend to resist any deformation. They are called stresses, and they vary according to the strength of materials and the form of the member. The kinds of stress under consideration are compression, which resists crushing; tension, which resists pulling apart; and bending, which occurs when one part of a member is in compression and the other is in tension. A column is put into compression by the loads it carries; in a trussed roof the piece that forms the base of the triangle is put into tension by the outward-pushing forces in the sides; and a lintel or beam (the member that spans a space) is put into bending by loads and forces that push down on its top and encounter a reacting force at its ends. Some materials are strong only in compression (e.g., stone, brick, cast iron, concrete) and others in tension as well (e.g., wood, steel, reinforced concrete), so the latter are more efficient in resisting bending forces.

Finally, the stability of the total structure whose single members are all in equilibrium is achieved by diverting the loads from all of them downward so that they may be resisted by the upward-supporting forces of the ground.

Techniques will be discussed in terms of the characteristics of building materials and the methods by which they are used in architecture.Visit website: http://limelight.ae/.

Materials Stone In most areas where stone is available, it has been favoured over other materials for the construction of monumental architecture. Its advantages are durability, adaptability to sculptural treatment, and the fact that it can be used in modest structures in its natural state. But it is difficult to quarry, transport, and cut, and its weakness in tension limits its use for beams, lintels, and floor supports.

The simplest and cheapest stonework is rubble; i.e., roughly broken stones of any shape bounded in mortar. The strongest and most suitable stonework for monumental architecture is ashlar masonry, which consists of regularly cut blocks (usually rectangular). Because of its weight and the precision with which it can be shaped, stone masonry (in contrast with brick) does not depend on strong bonding for stability where it supports only direct downward loads. The entablatures (the upper sections of a classical order that rest on the capital of a column) of an ancient Greek temple, for example, were bonded by small bronze dowels. But the weight creates problems of stability when loads push at an angle; stone vaults and arches require more support and buttressing than equivalent forms in other materials.

The best stone (and brick) bonding is that in which blocks are placed so that the vertical joints in one course are not above the joints in the courses above and below, since the stone resists deformation better than any bonding material. Many stones are strong enough to provide monolithic supports (columns and piers) and beams (lintels), and in some styles stone slabs are employed even for roofing (ancient Egyptian temples, early Christian basilicas in Syria), but this roofing requires so many columns that unvaulted masonry buildings are almost always combined with floors and covering in wood. Stone has been consistently used for building since the Stone Age, as exemplified by Stonehenge, in England. Although it has generally been replaced as a structural material by cheaper and more efficient manufactured products, it is still widely used as a surface veneer for its practical and expressive qualities.

Brick

Brick compares favourably with stone as a structural material for its fire- and weather-resisting qualities and for the ease of production, transportation, and laying. The size of bricks is limited by the need for efficient drying, firing, and handling, but shapes, along with the techniques of bricklaying, have varied widely throughout history. Special shapes can be produced by molding to meet particular structural or expressive requirements (for example, wedge-shaped bricks are sometimes employed in arch construction and bricks with rounded faces in columns). Bricks may be used in construction only in conjunction with mortar, since the unit is too small, too light, and too irregular to be stabilized by weight. Each course (or layer) must be laid on an ample mortar bed with mortar filling the vertical joints. The commonest ancient Roman bricks were cut into triangles and laid with the base out and the apex set into a concrete filling that provided additional strength. Rectangular bricks are bonded either as headers (short side out) or stretchers (long side out). Standard modern types provide a ratio of width to length of slightly less than 1:2 to permit a wide variety of bonding patterns within a consistent module, or standard of measurement. Brick, which has been used since the 4th millennium BCE, was the chief building material in the ancient Near East. The versatility of the medium was expanded in ancient Rome by improvements in the manufacture of both bricks and mortar and by new techniques of laying and bonding. Employed throughout the Middle Ages, brick gained greater popularity from the 16th century on, particularly in northern Europe. It was widely used in the 20th century, often for nonbearing walls in steel frame construction.

Wood

Wood is easier to acquire, transport, and work than other natural materials. All parts of a building can be efficiently constructed of wood except foundations; its disadvantage is susceptibility to fire, mold, and termites. The strength of wood in both tension and compression arises from its organic nature, which gives it an internal structure of longitudinal and radial fibres that is not impaired by cutting or long exposure. But like all organisms it contains moisture and is not uniformly strong, so it must be carefully selected and seasoned to prevent warping, splitting, and failure under loads. Wood is used in building both solid and skeletal structures. The principal solid system, called log construction, is employed when only primitive cutting tools are available. Four walls must be built up together in horizontal layers of single hewn or uncut logs and jointed at the corners. The stability of the log building depends entirely on the mutual support of the walls, and the method is suitable only for simple structures of limited size. The skeletal system requires precise cutting and shaping of lumber. It provides a rigid framework of jointed or nailed members independent of the walls, which are attached to the exterior and interior surfaces after completion.

Almost all masonry buildings of the past had wood floors and coverings, since wood is the lightest, the most practical, and the most inexpensive material for spanning spaces.

The monumental architecture of the West has typically employed materials rarer than wood for expressive purposes, but the history of wood construction can be traced consistently in China, Korea, and Japan and in the domestic architecture of northern Europe and North America. Wood continues to be used in a growing number of techniques and products: heavy framing systems with compound beams and girders, interior and exterior facing with plywood and other composite panels, and arch and truss systems with laminated members that can be designed to meet particular structural demands.

Learn more visit website: http://limelight.ae/

#architecture #desig #homedecor #interiors #design #love #art #creative #homedesign #decoration

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chemicalresearch · 6 years

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3D Concrete Printing Market - Global Industry Insights, Trends, Outlook and Opportunity Analysis, 2017-2025

3D printing allows construction of 3D printed structures, houses, and bridges. It allows construction of designs with flexibility, construction time optimization, cost, environmental factors and error reduction. Structural components are built layer-by-layer from the high-performance concrete that is emitted from the nozzle with no framework or any vibrations. This technology is bringing new and innovative architectural ideas and completely varies to the present architectural structures.

Furthermore, 3D concrete printing technology paves ways for limitless rich décor with new shapes and elements and minimizes waste, compared to current technology that makes new constructions more expensive and difficult. Constructions printed in 3D provides immense speed for construction making complex structures easy with high performance concrete.

Ask for detailed Sample of the Research Report @ https://www.coherentmarketinsights.com/insight/request-sample/821

Increasing construction activities in emerging economies is driving growth of the market. However, high initial cost associated with process and lack of awareness regarding this technology is restraining growth of 3D Concrete Printing market.

Global 3D Concrete Printing Market Taxonomy

On the basis of product type, the global 3D concrete printing market is segmented into:

Walls

Floors

Roofs

Panels

Lintels

Staircase

Paving Slabs

Others

On the basis of concrete type, the global 3D concrete printing market is segmented into:

Ready-Mix Concrete

Shotcrete

High-Density Concrete

Precast Concrete

Lightweight Concrete

Limecrete

Stamped Concrete

Others

On the basis of software, the global 3D concrete printing market is segmented into:

Design Software

Inspection Software

Printing Software

On the basis of end-use industry the global 3D printing market is segmented into:

Residential

Commercial

Architectural

Industrial Construction

Sports

Education

Healthcare

Others

Walls segment is projected to have the highest market share in 3D concrete printing over the forecast period, as this technology offers wall construction with detail. Moreover, it is convenient to use and saves time. Similarly, ready-mix concrete segment has a largest market share in the 3D concrete printing market, as it provides less labor cost, consumes less space on the site and has good quality. Residential segment is projected to be the largest market in the 3D concrete printing market, owing to rise in residential construction.

Global 3D Concrete Printing Market Outlook

Asia Pacific is projected to be the fastest growing market in the 3D concrete printing, owing to increasing green construction activities, industrialization, advancement in construction technology, especially in the emerging economies such as India and china, which is driving growth of 3D concrete printing market in this region. China is the largest market for 3D concrete printing, owing to increasing awareness regarding technology, which is contributing to the growth of market in this region. Government of India is looking forward for scheme, ‘Houses for all’ by 2022, providing sustainable and affordable houses for citizens.

North America is projected to be the dominant market in the 3D concrete printing, owing to advancements in construction technology. The U.S. and Canada are leading the market allowing huge change in manufacturing goods all over the world.

Europe is projected to witness burgeoning growth in the 3D concrete printing market, owing to technological advancement in the economies such as Netherlands, Spain, and numerous other regions. World’s largest printed construction was designed in Europe and also commenced the first 3D printing building full filling the government regulations. The Dutch companies are focusing on Dubai, Netherland, and China for their growth, which is fueling growth of 3D concrete printing market.

Get More Information @ https://www.coherentmarketinsights.com/ongoing-insight/3d-concrete-printing-market-821

In 2016, the pedestrian bridge was built for the first time in the world printed in 3D developed by ACCIONA. The bridge was 12 meters long and 1.75 meter in width. The world’s largest printed construction was designed by Universal Architecture, a Dutch company, which used sand to create stone-like material. The WinSun, a Chinese company, recently constructed 10 houses in 24 hours using 3D concrete printing with per house costing US$ 5000.

The major players operating in 3D concrete printing market include WinSun Global, Universe Architecture, Sika, Carilliom Plc., Fosters + Partners, Skanska, DUS Architecture, and LafargeHolcim.

About Coherent Market Insights:

Coherent Market Insights is a prominent market research and consulting firm offering action-ready syndicated research reports, custom market analysis, consulting services, and competitive analysis through various recommendations related to emerging market trends, technologies, and potential absolute dollar opportunity.

Mr. Shah

Coherent Market Insights

1001 4th Ave,

#3200

Seattle, WA 98154

Tel: +1-206-701-6702

Email: [email protected]

#3D Concrete Printing Market

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