Design of a thermoelectric energy source for water pumping applications: A case study in Sharjah, United Arab Emirates

Obaid, Waleed; Hamid, Abdul-Kadir; Ghenaï, Chaouki; Assad, Mamdouh El Haj

doi:10.11591/ijece.v11i6.pp4751-4758

Cited by 3 publications

(3 citation statements)

References 16 publications

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“…Figures 4 and 5 illustrate the output of a photovoltaic cell under conditions of an irradiation of 500 W/m 2 and a temperature of 323 K, respectively. These results are derived from (3) through (5). The impact of temperature change with constant irradiance was tested by setting the irradiance value to 500 W/m 2 and adjusting the temperature to 323 K, 360 K, and 373 K. These temperatures were chosen so that the effect could be studied [154].…”

Section: Mathematical Model Of Pv Cellmentioning

confidence: 99%

Modernisation of DC-DC converter topologies for solar energy harvesting applications: A review

Sutikno

Purnama

Aprilianto

et al. 2022

IJEECS

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Solar photovoltaic (PV) power generation has become increasingly important as a renewable source of energy due to the many benefits it offers. These benefits include the ease with which it can be allocated; the absence of noise; the longer life; the absence of pollution; the shorter amount of time required for installation; the high mobility and portability of its parts; and the capability of its output power to meet peak load requirements. DC-DC converters are typically incorporated into solar energy harvesting systems because they allow for the more efficient exploitation of solar cells. One of the difficulties is in the selection of a suitable converter since this has an effect on the operation of the PV system. This study discusses the modernisation of several different DC-DC converter topologies for solar energy harvesting systems. Some of these topologies are boost, buck-boost, single-ended primary-inductance converter (SEPIC), Cuk, and flyback. The topologies have been compared so that detailed information on the complexity of the hardware, the cost of implementation, the efficiency of the energy transfer elements, the tracking efficiency, and the efficiency of the converters can be provided. This paper will be useful as a handy reference in choosing the best converter topology for solar energy harvesting applications.

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Section: Mathematical Model Of Pv Cellmentioning

confidence: 99%

Modernisation of DC-DC converter topologies for solar energy harvesting applications: A review

Sutikno

Purnama

Aprilianto

et al. 2022

IJEECS

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“…There are two stages: one stage and two stages. The single-stage SPV is directly integrated to the utility grid using an only DC to AC converter, while the double-stage SPV is integrated to the supply grid using a boost converter; both topologies are extensively discussed in [9]- [19]. However, single stage topology is now recommended because a boost converter is not required in this scheme, which not only reduces costs but also improves overall system efficiency.…”

Section: Introductionmentioning

confidence: 99%

The performance of a multilevel multifunctional solar inverter under various control methods

Shukla¹,

Zaveri²,

Sutikno³

2023

Bulletin EEI

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Photovoltaic (PV) inverters are now supposed to provide additional supporting services with more reliability and efficiency. This paper presents three different control methods for generating reference current in a multifunctional, multilevel grid-tied PV inverter for harmonic, reactive, and unbalance compensation. These methods are the synchronous reference frame (SRF) theory (d-q), the instantaneous reactive power (IRP) theory (p-q), and the conservative power theory (CPT). As a result, the primary goal is to propose a low-cost multifunctional solar invert for distributed generation, with an appropriate prototype developed in the laboratory for experimental validation of various modes of operation. Demonstrated results show that the presented inverter is capable of providing various ancillary services with all three types of control.

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“…A lot of research and development is in progress on micro-energy harvesting technology to drive low-power electronic systems by harvesting energy from the environment. Compared to the technology using light energy [1]- [6] or vibration energy [7]- [11], the technology using thermal energy [12]- [22] is somewhat slow in research and development due to the technical difficulty that the voltage level extracted from a thermal energy transducer is small. However, since the thermal energy is suitable for application to living organisms including humans, it is possible to create a variety of application fields such as health care systems.…”

Section: Introductionmentioning

confidence: 99%

A self-startup DC-DC boost converter for thermal energy harvesting in a 0.35 μm CMOS process

Yun

2022

Bulletin EEI

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In this paper a self-startup DC-DC boost converter for thermal energy harvesting applications is presented. A startup circuit boosts an internal supply voltage using a low voltage generated from a thermoelectric generator to operate the internal circuitry of the converter. To reduce power dissipation, the startup circuit is disabled after the startup operation is finished. A boosted output voltage is obtained by alternating an auxiliary converter for the internal supply voltage and a main converter for the output voltage. The converter has been implemented in a 0.35 μm complementary metal–oxide–semiconductor (CMOS) process. Measurement results shows that the designed converter is capable of generating an output voltage close to 3V from an input voltage of 200 mV, and can provide a maximum output power of 278 μW with an end-to-end power efficiency of 46.5%. It occupies an active area of 0.36 mm2.

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Design of a thermoelectric energy source for water pumping applications: A case study in Sharjah, United Arab Emirates

Cited by 3 publications

References 16 publications

Modernisation of DC-DC converter topologies for solar energy harvesting applications: A review

Modernisation of DC-DC converter topologies for solar energy harvesting applications: A review

The performance of a multilevel multifunctional solar inverter under various control methods

A self-startup DC-DC boost converter for thermal energy harvesting in a 0.35 μm CMOS process

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