Construction Of Building Materials Malaysia -Myassignmenthelp.Com

Question: Discuss About The Construction Of Building Materials Malaysia? Answer: Introducation The project considers the building of a nursery. This nursery will be built using a green building concept. This building is located in Shah Alam in Malaysia. A green building is made by considering the nature and the surrounding of the site which will make up the nursery. This will also help in preserving the nature and the surroundings of the building. The construction of such project will also not cause any environmental impacts (Kibert, 2016). A green building is defined by any such buildings or infrastructure which helps in preserving the energy around. This involves preserving the energy in case of the constructional process as well as the setting up process. As a result, for the entire life cycle of the project, a green building does not have any impact on its surrounding. The construction industry is a massive industry which involves the constant collection of raw materials which will help in meeting the demands of the people in an efficient manner. The procurement of raw material is usually a process which is defined the collection of mass materials for helping in building and development (Zuo Zhao, 2014). The construction activities on a worldwide level are assumed to be 3 billion tonnes for every year of development. The most important part of a green building is the nature of the material that is used for constructing it. Although, there is a variable controversy regarding the nature of the material, there materials are always considered to be renewable in nature. This is mainly done to reduce the environmental impact as renewable materials can be decomposed and does not pose a threat to the environment (Huang et al., 2015). In addition, the materials used are also considered to reduce the need for any maintenance and overhead charges. This helps in conserving the status and the impact of the building that is supposed to be built. Moreover, this also helps tending to the life and health of the people who will be occupying the building. This also helps in reducing the need for constant replacement of these materials which in turn will add to the economic profitability of the building. The major features of the green building is the reduced harmful gaseous emissions, reusable and reducible content s, less amount of toxic discharges, renewable materials and longevity or durability in life cycle. There are various types of green building materials whose selection is based on the type of building to be developed. The first material is the clay brick which is defined by their uses in cobwork. They can be extensively used for building walls with reduced load bearing capacities. It can also help in constructing lumber-frames (Alias et al., 2015). Another constructing material is the hemp block. These blocks are made from the fibers of the hemp plant which are then mixed with lime and sand. This is also considered to be a green building material. There are many other building block materials like aerated clay blocks, cob block and extruded earth block. After selecting the proper building block, the selection of green finishes is required. The green finishing materials are considered to be lime-based. The stuccos and the lime-based are considered to be a greener consideration than gypsum based or cement based finishes. This is mainly because the carbon dioxide emissions from these materials are then absorbed by the lime mortars. In addition, lime is considered to be biodegradable and recyclable. There are two different types of lime finishes. They are the non-hydraulic lime and the hydraulic lime. The non-hydraulic lime does not harden underwater and is made by heating pure limestone to a very high temperature so that quicklime is produced (Wei, Ramalho Mandin, 2015). This is then mixed with rain water which results in the formation of lime putty. This lime putty is then allowed to mature for a number of months after which, it is then mixed with sand for creating mortars. Similarly, the hydraulic lime is made by heating up a less p ure form of limestone which usually consists of impurities like clay. Another material to be considered is the building boards. The eco-friendly material is made from biodegradable products. These products decompose and do not lead to any impacts in the environment. Contrary to drywalls which have greater disposal problems, the eco-friendly products does not cause any amount of pollutions (Ye et al., 2015). The first board material is the clay board whose primary component is clay. This is made by bounding hessian and reed together. The next type of board material is the straw board which can be used for effective flooring. The construction of a green building is usually made by considering the reusing of the products such that economic scalability is achieved and environmental impacts are reduced. The construction of the buildings is also made in this way such that the demolition of any surfaces can be done in inert manner (Council, 2014). The deconstruction of any green building releases a lot of principal waste like woods or clay. These materials are recycled and also a portion of the building is considered for deconstructing. There are various advantages and disadvantages of using green buildings which is the reason for its use in a global manner. Advantages The first advantage is in the cost of the materials and the building. The green buildings are usually made from renewable resources. The construction of green buildings costs the same as compared to traditional buildings (King, 2017). However, the materials used for construction are much more durable. As a result, the need for spending in case of maintenance of the building is reduced. Although, there is a need for maintaining the green buildings is considered similar to the conventional buildings. But, in case of the green buildings, the need for maintain it is reduced for a long time and hence, it is termed profitable for owning a green building. The next advantage is the efficiency in resources. As the green buildings are made by considering the energy on the surroundings, the efficiency is increased a lot. These buildings have efficiency in water usages. The rainwater is collected and is reused so that the wastage of water is reduced. Efficiency in energy is another point which adds as the advantage to the concept of green buildings. These buildings have developed energy conversion devices which help in storing the natural energy (Preller et al., 2017). This natural energy is obtained from the sun and wind. The solar energy and the wind energy are efficient in meeting the energy demands of the buildings. It also reduces the cost of energy consumption as compared to traditional buildings. Moreover, the materials used in case of the green buildings also trap the sun and wind that is available freely in the atmosphere. This helps in improving the air quality of the indoor atmosphere which in turn reduces the energy consumption s needed for doing so. Disadvantages There are various disadvantages to green buildings as well. The first location of the building is termed as the first disadvantage to it. As a green building always require the need for sunlight, it cannot be made in places where the suns rays are scarce (Zuo et al., 2017). Moreover, in cloudy areas, it cannot be built as they are mainly dependent on sunlight for energy requirements. Ventilation is the next disadvantage of the green buildings. Due to this, the buildings cannot be located in any hot areas. Moreover, the availability of materials is another concern which is considered before construction. Thus, it can be concluded that green buildings are an effective choice for addressing the economy and scalability parameters. These buildings are effective in utilizing the natural energy and the resources available which is always reused and recycled. This helps in reducing the environmental impacts and also helps in making the environment a clean place. However, there are various disadvantages which are to be considered before the construction of a green building. The construction industry is a massive production industry which is taking the space in the market economy. Due to this, there are various technologies that are being used for the construction of buildings. The first building technology is the unbreakable material uses. This is mainly done by using polymer nanotrusses. These materials are made by considering two-photon lithography. These technological materials were then coated in any kind of ceramics or metals which form a nanotruss comprised of nanotrusses. This constructional material couples the structural characteristics by including the flaw-tolerance features in their structures (Jamaludin et al., 2017). The technology involving this construction is trying to scale the size of the material in increasing from millimeters to letter sizes. This type of materials has high tensile strength which is used in making a great constructional material. The next technological material is the self-cleaning material. For tending to the application of glass type coatings, a new technology is made which resists moisture even after being exposed to scratches. This technology is termed as the self-cleaning finishes which are also used in cases of repellent coatings (Cevallos et al., 2017). This type of technology is achieved by making substances from titanium dioxide nanoparticles. This helps in reflecting water and oil from the surfaces and in turn reduces the dirt from the structures. As a result, the finished product becomes more durable. This coating is applied in cases of 2- centimeters square surface areas. Wave benders are another type of technology which is used in a global scale. This type of technology helps in the development of elastic wave guides. In this technology, the mechanical waves that travel through the structures are always subjected to any events or shock. This is the main reason for the underlying structures to break in cases of seismic events. In case of the wave bender technology, these mechanical waves do not cause any types of alterations to the structures. This increases the durability in case of the seismic events (Esa, Halog Rigamonti, 2017). By causing a redirection of the mechanical waves which carries massive energy around very important structures or buildings through a passage of meta-material cloaks, a lot of civilian lives can be saved long with common properties from various disastrous events. Durable concrete is the last material which is applied in the construction industry. This is mainly achieved by adding cellulose nanocrystals to concrete. These nanocrystals are mainly obtained from wood fibers. These concrete materials are much more effective in comparison than the traditional concrete materials in terms of impact, strength, flexibility and resistance. When the nanocrystals are applied to construction materials like concrete, the reduction of the environmental footprint of a structure is achieved. This is done by requiring less material for achieving a similar kind of effect (Mohammad, Ani Rakmat, 2017). The nanocrystal additive can be extracted as a byproduct of industrial agriculture, paper production and bio energy. This type of technological advancement also helps in acquiring water to it which does not impact its density or weight in any way. The building materials are the key elements which are considered in case of any types of building related practices. The building materials are mainly used for the construction of an effective technological advancement in the construction sector. The technological method that has been discussed in this question can be applied in a global basis. The technology of unbreakable materials involving nanotrusses cannot be made in Malaysia. However, this technology can be achieved by using various other materials which are now under process in Malaysia. However, there are greater uses of this type of materials. They are mainly used to increase the durability and strength of the material considered. In addition, this also helps in addressing to the tensile strength of the structure to be performed. The technology of self-cleaning materials is also another innovation that is applied in a global scale. In Malaysia, this type of technology is being used effectively which is leading to the formation of an efficient building (Esa, Halog Rigamonti, 2017). This type of technology is used for removing the pollutions from the buildings. As customer reviews are effective for making a brand in the market, the need for using self-cleaning materials are thus adopted in buildings. This type of technology helps in removing dirt and water from the building surface. This in turn helps in increase g the durability of the building. This also helps in getting more customer satisfaction and is thus being used in many cloudy areas. Wave bending materials are the third innovative technology which is also being used in cases of the high-rise buildings in Malaysia. This helps in adding to the durability of the structures and to the life cycle of it (Isnin et al., 2018). In addition, as the mechanical waves do not find a straight path in this type of technology, the probability of crumbling down of the structure in case of any kind of seismic events are reduced. This is the main reason for the increasing customer satisfaction and also is the main reason for the acceptance of this type of technology. The durable concrete material technology is another feature which is also adopted in Malaysia. As the structures are mainly comprised of long and high rise buildings, the need for making them stronger is applied. This is applied in the structures of Malaysia. In addition, this is also used for making secondary structures as well (Mohammad, Ani Rakmat, 2017). The physical structures are sometimes comprised of changes due to addition of extra featured structures on top of the physical structures. These are termed as secondary structures which are mainly comprised of new types of materials that make up the structure. The durability and the high tensile strength from the addition of effective concrete materials are the main reason for these innovations. Thus, it can be concluded that the use of effective construction materials helps in addressing to the strength of any types of buildings. This also helps in making the structures more effective in meeting the expectations of the brand concerned. Due to the innovations of these types of technologies in the market, various construction companies will be interested in this case and will also help in raising the brand value respectively. In addition, as the quality of the products is increased, the satisfaction levels of the customers will also be increased. Thus, the materials to be used are to be effectively selected by the company such that the required outcome is always met. 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