The Effectiveness of Salt Business Empowering Program (Pugar) on Salt Farmers’ Income Improvement in Kedungmutih Village of Demak Regency

Indonesian national low productivity of salt which is unequal between the need level and salt consumption eventually results in salt import made mainly to meet the industrial needs. The government through the Ministry of Marine Affairs and Fisheries has released a Public Salt Business Empowering Program (known as PUGAR/Pemberdayaan Usaha Garam Rakyat). PUGAR is an empowering program focusing on the improvement of job opportunities and welfare for salt farmers/managers to achieve the self-sufficiency of salt for consumptions and industries. This research aims at examining the influence of salt business empowering program on the salt farmers’ income improvement in Kedungmalang village of Jepara Regency; the implementation level of salt business empowering program in Kedungmutih Village of Demak Regency when compared to that in Kedungmalang Village of Jepara Regency; and the influence of salt business empowering program on the salt farmers’ income improvement in Kedungmutih village of Demak regency. The research was conducted using a descriptive method with a case study approach. The program implementation was quantitatively analyzed. Furthermore, the effectiveness of PUGAR on income was analyzed using T-test. The test result showed that there were income differences in Kedungmutih and Kedungmalang Village before and after the implementation of PUGAR. This finding showed that PUGAR was proven as an effective program to improve the salt farmers’ welfare through income improvement.

High Efficency isolated DC-DC boots converter for Renewable energy Appliction { BS Project]

A huge amount of electrical energy in Pakistan is lost due to inefficient generation and distribution of power. [13] This project aims to address a very specific problem in this regard which is the energy conversion losses in power converters used with systems of renewable energy generation. The main problem that is being looked into is how the efficiency of an Isolated DC-DC Boost Converter can be improved. Addressing this issue helps in making effective use of renewable energy sources which in turn helps in reducing the energy deficit. To improve upon the design of an Isolated DC-DC Boost converter, it is imperative that first an in-depth study of the already existing designs be carried out. A detailed literature review helped in identifying areas that can be worked upon to increase efficiency. The major losses that occur in an isolated converter come from core and copper losses in its high frequency (HF) magnetic components that are the inductor and transformer. Apart from that, MOSFET losses and diode rectifying losses are also quite significant if chosen poorly. Hence, to increase efficiency, the most important part is an optimized design of HF components, careful selection when it comes to MOSFETs and diodes and finally selecting an appropriate converter topology. Increasing efficiency of HF magnetic components needs a rigorous analysis of design methodologies used to implement them. It was identified that some of the main factors involved in that were core material and geometry and its winding methodology.The killer for inductor and transformer are the leakage inductance and AC resistance which occur due to proximity and skin effect. It was identified that the main losses occur due to the winding method and the type of copper winding geometry. After an in-depth study and comparison between different winding types and methods, it was realized that copper foils help in reducing skin-depth effect and interleaving the windings would help in dealing with proximity effect. Interleaving is when primary windings of the transformer are sandwiched between secondary windings. To validate this design, first a theoretical analysis was carried out after which this design was implemented xi and tested in the lab where significantly low AC resistance and leakage inductance was observed.The major challenges in this project in the design phase were to identify methods for inductor and transformer construction. For transformer design, from analysis it wasdecided to implement interleaved windings but it was challenging to understand how the windings will terminate and physically implementing the windings without any gaps in etween. An unexpected challenge during transformer implementation was soldering the winding terminals using a high wattage soldering iron. This was because the solder has to be minimal to avoid any bumps. Another tight spot faced was while procuring material for the project as most of the required components were not available locally and that led to slight delays in the implementation phase. The converter proposed after the design and analysis has a theoretical efficiency of 97%. There can be a huge impact in utilizing renewable energy effectively if a practical use of this converter is carried out. However, to validate this research, the next step would be to implement the proposed device and computing its actual efficiency. Careful and precise implementation of the design can potentially achieve the calculated efficiency because of the design considerations taken into account. This can then be taken forward to local stakeholders such as the Alternate Energy Development Board (AEDB) as using locally designed and implemented converter will have a significant impact on the cost and benefit breakdown of sustainable energy projects being deployed