Innovative Solutions: Improving Energy Plan Research Paper
In recent decades, energy is becoming probably the most important resources for humanity. However, having less attention to the topic has generated a pressing have to review the existing energy used in order to optimize its consumption without lowering our standard of living. Numerous solutions have already been proposed to address the problem. The paper outlines probably the most feasible methods to improving the power plan by increasing the proportion of renewable energy in the power mix and reducing demand for energy in the construction and transportation industries.
Two overall directions are believed viable in the power plan optimization process. The initial direction is the reduced amount of the demand for energy. The proposed change may be accomplished by implementing numerous innovative solutions in the construction industry. One particular innovation is AERspire, a roofing technology implemented as part of the AER II cross-border project. The project offers a roofing solution that’s both visually pleasing and highly functional. The machine uses photovoltaic elements built-into glass panels which are with the capacity of producing electricity sufficient for powering the average household. Furthermore, AERspire uses solar thermal heat to supply the supply of warm water essential for personal means (InnoEnergy, n.d.). The installation process begins with the assessment of the energy requirements of a particular household, after which some photovoltaic elements is installed. The rest of the space is then filled up with dummy panels to make sure an aesthetically pleasing result. The described modular system supplies the necessary flexibility and visual attractiveness for the consumers, promoting the adoption of green energy use while simultaneously redistributing energy load more evenly over the system.
Another consumer-level solution is Plactherm, a good floor heating system contained in SMEInst-09-2016-2017 initiative being an energy consumption reduction technology. Plactherm uses an automated, remotely-controlled system operated by way of a cloud-based application for maintaining a well balanced room temperature that’s adjusted according to a couple of factors. The perfect solution is is oriented primarily at offices and similar environments made to contain a large numbers of people. The heating element is manufactured by means of a floor tile with embedded sensors and works with with numerous energy sources, including renewable ones (Plactherm, n.d.). Most of all, the system is with the capacity of creating several thermal zones inside a single space. These zones are individually configurable and may be adjusted automatically, developing a highly adjustable energy consumption plan. Based on the estimates, the intake of energy for heating purposes could be reduced by around 30% due to Plactherm installation (Plactherm, n.d.). Furthermore, an individualized climate enhances the standard of workplace conditions, increasing the chance of adoption.
The 3rd technology suggested for energy demand reduction is OGGA, a smart consumer-level energy management solution contained in a good Buildings Alliance for Smart Cities program. An OGGA unit carries a thermostat, energy meter, and a circuit breaker that connects heating and lighting systems to the grid. The objective of OGGA would be to optimize energy consumption by disabling unnecessary devices or reducing their operational capacity to nominal levels (OGGA, n.d.). The machine has two main advantages over competing solutions. First, the power consumption control is facilitated using smart adaptive technologies that determine optimal distribution in line with the behavior of the residents, which maximizes its efficiency. Second, the machine was created with simplicity and accessibility at heart, which results in a comparatively low priced and improves the selling point of the technology to wider audiences. Admittedly, it really is difficult to estimate the common percentage of energy savings because of large numbers of variables. Nevertheless, it really is reasonable to expect a substantial decrease in individual energy consumption, especially taking into consideration the automated principle of operation.
Finally, you’ll be able to suggest innovative insulation solutions as part of an energy plan. Among the possible candidates may be the Active Insulation technology, something of adjustable insulation panels that change their thermal conductivity predicated on external conditions. A channel structure embedded in insulation panels allows controlling the surroundings inside the building in line with the difference between internal and external temperature (“Active insulation,” n.d.). Once an adequate difference is detected, the channels are opened with a forced ventilation switch, effectively disabling an insulation effect and, consequently, normalizing the temperature minus the usage of external power sources. Importantly, the described principle works in both directions, ensuring heating or cooling of the surroundings based on preset conditions and resident preferences. The usage of Active Insulation decreases the necessity for additional heating equipment and, perhaps moreover, mitigates heat from internal sources, minimizing the necessity for air-con and, by extension, reducing the demand for energy.
It must be noted that the proposed technologies are employed as examples because the market offers a much wider selection of innovative solutions for reducing energy demand in the construction industry. Additionally it is worth noting that of your options described above are in keeping with the trend of power grid decentralization, which gradually gains momentum among individuals and corporate entities (Sorrell, 2015). Thus, it really is reasonable to anticipate that at a particular point, they’ll be found in combination, ensuring exponential growth in the energy-saving domain.
The next direction may be the increase of renewable energy proportion in the power mix. The increasingly rapid depletion of resources necessitates a remedy that would enable sustainable sources, thus ensuring long-term development. The transportation sector offers great potential in this regard. The recent advancements in the domain of electric vehicles (EVs) allow both individuals and organizations to change to electricity as a primary way to obtain power. Admittedly, some energy plants still operate on fossil fuels. However, you’ll be able to expect that over time, the mass adoption of EVs will raise the demand for cleaner energy sources, thus adding to the cause.
Several approaches could be identified that are likely to facilitate development in the required direction. The initial approach has been incorporated as an element of green building philosophy and includes several interconnected principles. Probably the most recognizable top features of green construction may be the reliance on green energy in powering the facilities. The progress manufactured in the field of renewable energy generation is particularly prominent in your community of solar power design, where in fact the latest generation of hardware permits the highly efficient conversion of solar technology into electricity. Furthermore, solar energy will not require additional space because it can be mounted on the structure, which, in the cases of small-scale buildings is enough for powering the complete house (Kibert, 2016). This principle has been progressed into an independent idea of solar architecture – a strategy in which the contact with the Sun is roofed in the look process as a way to obtain clean renewable energy. Solar architecture incorporates multiple aspects that differ in complexity, cost, and efficiency (Kibert, 2016). Thus, it really is reasonable to acknowledge these principles to experience a sufficient upsurge in renewable sources in the power mix.
Another facet of resource use included in the green building approach that could donate to renewable energy adoption is water consumption. It’s been established that water consumption by the average household could be reduced at the very least twofold due to innovative approaches and technologies (Kibert, 2016). First, the water heating process could be optimized through various automated solutions such as for example an adaptive heating unit that estimates the necessity for warm water and adjusts power distribution accordingly, thus reducing waste of energy. On an industrial level, additionally it is possible to introduce designs that could require a minimum level of water for heating, thus driving energy consumption down. Finally, the problem of using normal water for non-consumption purposes could be addressed through innovative design solutions. For instance, you’ll be able to install reservoirs that could allow collecting and storing greywater along with runoff from external surfaces and deploying it for irrigation and technical reuse. When implemented at the level, the proposed approach will eventually bring about the reduced waste of resources and, by extension, raise the percentage of renewable energy in the power mix. Additionally it is worth mentioning that approach is in keeping with the goals of Water Security Strategy 2036. Specifically, the introduction of water-saving designs and tactics is likely to contribute to the full total demand for water resources along with raise the water productivity index by improving its reusability capacity. Due to decreased consumption, additionally it is possible to expect a decrease in water scarcity in the long run.
Currently, energy is among the most valuable resources on earth. Its availability and quality determine the chance of further development of science and technology. The implementation of the outlined innovative solutions is likely to optimize the existing energy generation and consumption process to be able to ensure its sustainability and efficiency.
Active insulation. (n.d.). Web.
InnoEnergy. (n.d.). AERspire . Web.
Kibert, C. J. (2016). Sustainable construction: Green building design and delivery (4th ed.). Hoboken, NJ: John Wiley & Sons.
OGGA. (n.d.). Heating management . Web.
Plactherm. (n.d.). Product . Web.
Sorrell, S. (2015). Reducing energy demand:
Overview of issues, challenges and approaches. Renewable and Sustainable Energy Reviews, 47 , 74-82.