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Bioethanol fuel gel is renewable energy (renewable energy) potential as the source is updated and more secure when compared with liquid bioethanol. Besides ethanol gel fuel is also cheaper than fossil fuels such as premium, gas and kerosene. However, the use of bioethanol gel as a substitute for fossil fuels are still very minimal. This is due to factory producing bioethanol gel is limited and little is know how to capitalize on bioethanol gel that can be used in everyday life, as well as bio-ethanol gel stoves. For that, a special study is needed regarding the manufacture and performance of bioethanol gel-fueled stove.This study aims to create a prototype stove bioethanol gel and seek to know the characteristics and comparative performance of bioethanol gel fuel stove by creating a wide variety of combustion (burner) and the air hole diameter 5 mm, 4 mm, 3 mm, 2.5 mm, and 2 mm. Control variables in this study is the production of bioethanol gel CV. Fresh Joy International with ethanol content of 70%, 1.05% Carbopol, 7.33% moisture content with HHV 16942.572 (kJ / kg) and LVH 16717.369 (kJ / kg). Incinerators (burner) made from canned drinks (soft drinks) ex. The data in this study will be processed using a method Boilling Water Tester (WBT) in order to obtain results in the form of influence each - each a variation on bioethanol fuel burner on the stove gel. From the study showed, a stove with a second variation (V2) with a diameter of 4 mm air holes are stoves most effective and efficient with thermal efficiency values (hc) 67% and, blue flame characteristics and stable. 130421008

The use of manure and litter as bio gas-producing material is one solving problem of sanitation and environmental health as well as the control of environmental pollution, especially in the vicinity of the farm and the market environment. To obtain biogas productivity and optimum quality then conducted a study with the aim to determine the effect of a composition ratio mix of fish maw, kale and feces of pigs against pH, productivity in this case, the gas pressure (Pa), gas mass (kg) and the volume of gas (m3), as well as the quality of the biogas as measured by the amount of calorific value (J), and power (watts), and the color of the flame produced. The results showed that the composition ratio of a mixture of 1: 1: 1 has the most stable pH with the average of 7. The gas pressure, gas mass and the volume of gas produced by the mixture composition ratio of 1: 1: 1 is larger than the composition ratio of a mixture of 2 : 1: 1, 1: 2: 1 and 1: 1: 2 with 3851.4 Pa gas pressure, gas mass kg 0.011568938 and 0.145424439 gas volume m3 calorific value of 19.680 kJ and 177.142 watts of power, as well as the color of the flame, produced that is blue. It can be concluded that the mixture composition ratio of 1: 1: 1 is the productivity and quality of the most optimal.

Indonesia has big amount of natural zeolite reserve which is spread in Sumatra, Java and Borneo. It can be utilized as catalyst in transesterification step to produce biodiesel from off grade palm fruit. This research aims to produce biodiesel from low quality raw material and determine the effectiveness of the process by looking at the process conditions effect such as temperature, methanol/oil molar ratio and catalyst concentration on the yield of biodiesel. Biodiesel production from off grade palm oil is done with two step reactions, that is esterification and transesterification. The esterification step is done to reduce free fatty acid (FFA) concentration till <2% as condition in transesterification step. Esterification step use H2SO4 as catalyst, whereas modified zeolite with KOH solution use in transesterification step. Both of process are done in three-neck flask, using magnetic stirrer and condenser. FFA concentration from raw material can be reduce from 11,32% to 0,989% in esterification step with 12:1 methanol/oil ratio, 60 oC temperature and 1%-wt catalyst concentration. Biodiesel with highest yield from transesterification step is 95,84% at 60 oC temperature, 8:1 methanol/oil ratio and 7,36% catalyst concentration. The result of research furthermore processed by Response Surface Methodology (RSM) to determine the effect of process condition toward biodiesel yield. Based on P-value analysis, process conditions that have real effect to the response (biodiesel yield) are temperature and catalyst concentration.

Utilization of alternative energy sources is still very minimal in the area of Losari Beach. Noise from visitors can be used as an alternative energy source in Losari Beach area. Sound saves potential energy that can be generated. In the process of utilization, piezoelectric material will be given input from the noise of the visitors of Losari Beach beach. This research will analyze the electrical energy generated (power on LED lamp) from piezoelectric material to various condition in Losari Beach area. The results of the study found the amount of output generated when the piezoelectric material is not coupled in series is 0.7 volts, while at the time strung in series reaches 1.9 volts. Makassar city government support, is expected in implementing the results of this study.

The phenomenon of global warming which is accompanied by climate changed, is the real threat to the community in the present and future. Indonesia is one of the most vulnerable countries affected by climate change. Tasikmalaya is the district with rank of hazard indexes is 5th in Indonesia. Sub district Salawu in Tasikmalaya district is a disaster-prone districts. One kampong in Salawu which still holds strong culture and customs is Kampung Naga. The aim of the study were analyzed potential disaster that related of climate change in Kampung Naga, and analyzed the the abilities of Kampung Naga community in mitigating disaster of climate change. The study used a qualitative descriptive analysis method. Potential disaster analyzed qualitatively based on condition of geomorphologi and location. Disaster mitigation capabilities were analyzed qualitatively from customs. Based on geomorphologi condition and location, hazards of climate change that could potentially be disastrous in Kampung Naga were landslide and floods. The abilities of Kampung Naga community in disaster mitigation of climate change, is affected by the traditional wisdom that was reflected from forest conservation, building, infrastructure and spatial patterns of kampong which could prevent landslide and flood. Fenomena pemanasan gobal yang diiringi dengan terjadinya Perubahan iklim, merupakan ancaman nyata bagi masyarakat di masa kini dan yang akan datang.Indonesia merupakan salah satunegara yang rentan terkena dampak Perubahan iklim. Kabupaten Tasikmalaya menduduki urutan kelima peringkat indeks rawan bencana di Indonesia. Kecamatan Salawu di Kabupaten Tasikmalaya rawan bencana. Kampung Naga adalah kampung yang masih memegang kuat budaya dan adat di Kecamatan Salawu. Tujuan penelitian adalah untuk menganalisis potensi bencana terkait Perubahan iklim di Kampung Naga dan menganalisis kemampuan mitigasi bencana masyarakat Kampung Naga terhadap Perubahan iklim. Penelitian ini menggunakan metoda analisis deskriptif kualitatif. Potensi bencana dianalisis secara kualitatif berdasarkan kondisi geomorfologi dan lokasi kampung. Kemampuan mitigasi bencana dianalisis secara kualitatif berdasarkan adat istiadat. Bahaya akibat Perubahan iklim yang berpotensi menjadi bencana di Kampung Naga adalah tanah longsor dan banjir. Kemampuan mitigasi bencana masyarakat Kampung Naga terhadap Perubahan iklim dipengaruhi kearifan tradisional yang tercermin dari konservasi hutan, bangunan, infrastruktur dan pola ruang kampung yang dapat mengurangi ancaman bencanatanah longsor dan banjir.

Banana peel (musa sapientum) is organic waste that have value of carbohydrates that high and nutrition that can help the growth of a microbe. Based on it, then appears an idea to make use of the bioethanol from the peel as a source of raw materials. Bioethanol is one alternative energy that are spoken currently who is expected to replace energy source of petroleum that has existed that is the fluid a result fermentation of sugar from sources of carbohydrate used the aid microorganisms. In this research process of waste the banana peel become bioethanol is aimed to determine the process of waste the banana peel plantain and kepok, ranging from process of smoothing the hydrolysis of, fermentation until distillation of which are then analyzed levels of each bioetanol each kind of the banana peel based on the number of yeast and time. In this process of fermentation by the addition of saccharomyces cerevisiae by number of yeast, as many as 3 5, 7 gram with long fermentation different namely during 2, 4, 6, 8 days influencing the outcome of the level of bioethanol on the type of skin of plantain and kepok. This result of research produce levels of bioethanol the most high that is on the type of kepok banana peel with yeast fermentation as many as seven gram during the time of 8 days worth 17.05 % while on the peel of plantain with heavy yeast and the same time having bioetanol levels as many as 16.55 %. The longer fermentation, microorganisms more active and the extension of yeast the result of ethanol is increasing contained in a sample of the banana peel with heavy yeast 3, 5 grams, 7 gram levels of ethanol more robust on the day to 8.

The electrical energy is one of the important needs for coastal communities particularly in small islands that has not reached by national electricity network. In order to fulfill this particular electricity needs, we do variety diversification efforts, such as the utilization of the ocean currents. The purpose of this survey is to recognize the morphology of seafloor and characteristic of hydro-oceanography as a fixed reference location in using the current energy. The study area is in the Larantuka Strait between Flores and Adonara islands which is part of the Flores Strait, East Nusatenggara Province. The methods of this study are current measurements, tidal and meteorological parameter observations, condition of coastal morphology and seafloor of the study area. The result show that, the location for turbine position is in area with relatively gentle slope morphology at a 20 meters water depth and it is close to local community. Based on the analysis of ADCP mobile current measurement, the minimum current velocity is 0.004 m/sec and maximum 3.68 m/sec. Whereas, from the ADCP static measurements the current velocity is from 0.002 m/sec to 2.83 m/sec. This condition is closely related to the semi-diurnal tide type in the study area, with two pairs of flood and web events within 24 hours. Therefore, the results of ocean current energy analysis indicate that the study area is very potential for using as a power plant location.

Biodiesel is an alternative fuel from renewable raw materials. One of the raw material can be used to make biodiesel is coconut oil. This research aims is determine the maximum biodiesel yield by using varying amounts of H-zeolite catalyst and methanol mole ratios of coconut oil through a process methanolysis. The independent variables used in this study is the mole ratio of methanol-oil 3: 1; 6: 1; 8: 1 9: 1 and catalyst concentration of 1%, 2%, 3% respectively. Temperature of 60°C, 1.5 hours and stirrer speed is keep constant. The yield of biodiesel produced in this study reached 84.78% at a concentration of 2% catalyst mole ratio of methanol-oil 6: 1. The density of biodieselproduced at the maximum yield was 880.90 kg / m3, kinematic viscosity of 4.59 mm2 / s, the flashpoint of 110oC, the water content of 0.048% v, and the acid number of 0.65 mg KOH / g, respectively in addition, analysis of the chemical compositions of biodiesel is used GC - MS. All the characteristics of the physical properties of biodiesel produced have met the standard range contained in the SNI 04-7182-2006.

One of the alternatives is by utilizing bioethanol as a renewable alternative energy source. This study aims to obtain ethanol from pineapple feel using solid state fermentation process and the purification using distillation and adsorption process, obtain comparative data on the adsorption capacity of the natural zeolite without activation and the activated natural zeolite, to get data the optimum of adsorbent to produce bioethanol, and characterize the physical properties of bioethanol and qualitative test by GC-MS. The pore size of adsorbent variations are 60; 100; 200 mesh and variation of treatment of adsorbent the natural zeolite without activation and the activated natural. From the research is obtained the highest bioethanol concentration average is 10,44 % volume. The most effective process for ethanol purification is distillation and adsorption process by natural zeolite adsorbent without activation with pore size of 200 mesh. Ethanol content increased from 95 % to 99.8 % v. Bioethanol from distillation and adsorption process in accordance with ISO standards.

Indonesia has petroleum reserves about 9 billion barrels, which the average production rate is 0.5 billion barrels per year, and was predicted would be exhaust within 18 years. Government has ordered a program and policy to develop bioethanol and biodiesel for the energy crisis in Indonesia. It is targeted can be provide about 15-20% of the fuel for transportation and national industry in 2025. This research's goals were to produce fuel grade ethanol by distillation-adsorption method, determined the effect of activation temperature of bentonite and the effect ratio of bentonite to bioethanol. The raw materials were bioethanol from nypa sap (8% ethanol content). The ethanol concentration was not too high, so it needed to improve its purity by distillation-adsorption process. The research was held in three phases, which were distillation of nypa sap's bioethanol to 96% ethanol content, activation of bentonite, and distillation-adsorption using activated bentonite. Activation temperature of bentonite were 400oC, 500oC and the ratio of bentonite:bioethanol were 1:2; 1:3; and 1:4. The most effective process for the purification of bioethanol was distillation-adsorption at 500oC activated temperature and the ratio of bentonite:bioethanol was 1:2 with the purity is 99.5% and has been categorized as a fuel grade ethanol