LEO-focused satellite propulsion technology has gained significant importance over the past three years (2018-2020). An increase in the requirement of high-speed information transfer and Earth observation across the globe without any lag has generated the demand for LEO-focused satellite propulsion technology. The industry is currently focusing on developing high-efficient and low-weight LEO-focused satellite propulsion technology products that can be used for several years. The research study is based on extensive primary interviews (in-house industry players, market leaders, and experts) and secondary research (a host of paid and unpaid databases), along with analytical tools to predict the forecast analysis for the study period. With the help of these, the LEO-focused satellite propulsion technology study provides a broader perspective of the industry.
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The industry outlook section of the report describes diverse factors governing the growth potential of the global LEO-focused satellite propulsion technology market. The market overview provides an in-depth understanding of the direction in which the market is headed and the impact of various factors on the same. The section will also encompass an in-depth understanding of the supply chain, current and futuristic technological trends, ongoing and upcoming projects, start-ups and investment scenarios, business drivers, challenges, key developments, and business opportunities that have the potential to capture significant market share over the coming years.
Space agencies and commercial organizations have been developing efficient propulsion systems, which address technologies that enhance existing electric, chemical, and hybrid propulsion systems. These technologies reflect upon the future demand for an increased number of satellite launches by different end users such as government, commercial, and defense. The introduction of electric propulsion in satellites reduced weight loss, risk to some extent, and increased performance capabilities. However, the solid fuel engines can significantly be improved by finding a green propellant alternative to current oxidizers, developing domestic sources for critical materials used in manufacturing, and formulating advanced hybrid fuels to get energy density equivalent to solid fuel.
The dipole drive is a new propulsion system, which does not carry its own propellant, and utilizes the surrounding space plasma as a propellant. The dipole drive propulsion system has the capability of generating thrust within planetary magnetospheres as well as in any direction in interplanetary space, raising or lowering its orbit or changing its orbital inclination, thereby overcoming the two flaws of the conventional electric sail.
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The dipole drive is built from two parallel panels, one of which is positively charged and the other negatively charged. This creates an electric field between them with no major field outside. When the surrounding solar wind protons enter the dipole drive field from the negative screen side, they are reflected out, providing lift if the screen is positioned at an angle to the plasma wind. Also, only drag is created if the screen is positioned perpendicular to the solar wind.
