The carbon burning is a practice which is attributive to global warming and similarly the solar heaters are also affecting the environment with harmful means to body organs because of charged sub-atomic particles. The burning fire is harmful to body in that it can cause suffocation and respiratory problems, while electric heaters and ACs are similarly health problematic to bring dehydration of body and the disease of respiratory system like asthma. The demand of the doctors and heat basking consumers is the kind of heating system which means to be without dehydrating, blood clotting and suffocating effects on body. For this purpose a self-generation of heat energy is required which should not need fire, electricity, chemical reaction process, rather than the physical change mechanism had nothing to do with a pollution of environmental construct. The design of such a prospective facility for both health and global milieu has been made feasible after four year serial researches of this present author.
The heater had without the use of fire and electricity may be manufactured by virtue of exothermic reaction between inorganic chemicals which will pollute respiratory system through surrounding atmosphere of a room, besides its very expensiveness. A flameless ration heater, or FRH, according to general report from Administration, is a water-activated exothermic chemical heater included with meals, ready-to-eat, that is used to heat the food. US military specifications for such an easily portable heater require the same as being capable of raising the temperature of an eight-ounce (226.8 g) entree by 100 °F (56 °C) in twelve minutes, and that it has no visible flame.
Table of Contents
1. Background
2. Problem Statement
3. Theory
4. Objective of the research
5. Discussion
6. Experimentation
7. Conclusion
8. Personal Recommendation
Objective and Research Focus
The research proposes a cost-effective and environmentally friendly heating solution that avoids the health hazards and pollution associated with traditional combustion-based or electric heating systems. The primary objective is to develop a method to generate heat through the concentration of light energy using magnetic fields, combined with a chemical heat-recycling mechanism involving glycerin and hydrocarbons.
- Analysis of the health risks associated with conventional heating systems (fire, electric, solar).
- Exploration of physical and chemical principles for light deflection and heat generation.
- Development of a prototype using magnets, glycerin, and hydrocarbon mixtures.
- Evaluation of safety, cost-efficiency, and environmental impact of the proposed system.
Excerpt from the Book
6. Experimentation
After such a household invention of the present author done, a medium sized bottle was filled with normal water up-to more than its half of the level while showing demonstration about scientific and technological research by self in office, Nepal Philosophical Research Center, Kathmandu on 2019-january-12. The remaining volume of the bottle was poured in with petroleum liquid. Then further 20 drops of rectified spirit were added in order to increase the concentration of hydrocarbon liquid and consequently its inflammability. After that again a sealed bottle of pure glycerin was dipped into the so prepared mixture. The cap of the bottle containing all necessary materials had been closed. The bottle was placed over a powerful magnet and around the glass wall of the same container other pieces of magnet were wrapped for increasing the attractive power of these to deflect light to their possible capacity. Later a few moments the bottle gave warmth to surrounding environment of room. The rectified spirit could be added further after two hours when the heat temperature reduces because of the usage of inflammable substances like petrol and spirit in the water mixture (Adhikari, 2018).
Summary of Chapters
1. Background: This chapter reviews the environmental and health drawbacks of existing heating methods, highlighting the need for a safe, non-polluting alternative.
2. Problem Statement: It details the negative physiological impacts of electromagnetic radiation and electric heating devices, necessitating a cleaner approach to domestic warmth.
3. Theory: The chapter explores the physics of light deflection using magnetic fields and the conversion of radiant energy into thermal energy.
4. Objective of the research: This section defines the goal of creating an affordable, environmentally sustainable, and health-conscious heating system.
5. Discussion: It evaluates the use of glycerin and hydrocarbons in a water-based system to effectively store and distribute heat.
6. Experimentation: The author documents the practical demonstration of the prototype, showing how magnets and hydrocarbons can generate warmth.
7. Conclusion: It summarizes the heat-recycling process and the role of water as a temperature stabilizer within the experimental device.
8. Personal Recommendation: The final chapter offers suggestions for optimizing the heating system, including material choices and the integration of light sources.
Keywords
Heater, Heat energy, Exothermic reaction, Magnetic field, Glycerin, Hydrocarbon, Light deflection, Environmental health, Respiratory system, Innovation, Sustainable heating, Temperature control, Galvanic cell, Radiation, Thermal energy.
Frequently Asked Questions
What is the core focus of this research?
The research focuses on proposing an innovative, low-cost heating system that generates warmth without the use of fire, electricity, or harmful chemical reactions, thereby protecting indoor air quality and environmental health.
What are the primary themes discussed?
Central themes include the health risks of traditional heaters, the application of magnetic fields for light convergence, and the development of a sustainable heat-recycling mechanism using chemical substances like glycerin.
What is the main objective of the proposed device?
The primary objective is to create a heating device that is affordable, safe for human health, and environmentally friendly, addressing the limitations of existing heating technologies.
Which scientific methodology is employed?
The author uses an empirical and conceptual approach, combining principles of physics regarding light and electromagnetism with chemical experiments to test heat generation and retention.
What is covered in the main body of the work?
The main body examines the theory of light deflection, explains the chemical interactions required to create a heat-recycling cycle, and provides a documented experiment demonstrating the prototype.
Which keywords best characterize the work?
Keywords include heat energy, sustainable heating, magnetic field, light deflection, glycerin, and environmental health.
How does the system utilize magnets?
Magnets are used to deflect and concentrate light rays toward the container of the mixture, which helps initiate and sustain the thermal energy required for heating the room.
Why is glycerin used in the heating system?
Glycerin acts as an absorbent and heat-recycling medium; it captures heat generated within the system and helps distribute it outward through the glass walls.
What safety precautions are suggested for the device?
The author recommends using hard glass to prevent explosion risks and cautions against using excessive heat sources that could cause the hydrocarbon mixture to ignite uncontrollably.
What is the estimated cost of implementing this solution?
The author estimates that the required materials for the proposed heating system can be obtained for approximately US$ 10.
- Arbeit zitieren
- Dr. Roshan Adhikari (Autor:in), 2019, Heater at Less Cost, Rather More Benefit. A Concept Proposal, München, GRIN Verlag, https://www.grin.com/document/465422
