Low budget solar cookers: An alternative to diminish the use of wood as a source of fuel

Escobar, E.

doi:10.1016/0960-1481(96)88393-5

“…The cooking time was reduced by one hour when paraffin wax used as an energy storage medium. 27 Comparative studies between solar cooker with and without energy storage was reported by Reddy et al 2 Paraffin PCM was used and a temperature difference of 17 °C was maintained during evening time in the cooker with TES compared to the cooker without TES. Use of erythritol as an energy storage medium was investigated 28 using a box-type solar cooker and it was reported that both the charging and discharging time was increased using PCM.…”

Section: Use Of Organic Pcmmentioning

confidence: 99%

Analysis of energy storage materials for developments in solar cookers

Khatri¹,

Goyal²,

Sharma³

2023

F1000Res

1

0

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Solar energy is accessible freely and can be utilized for many household and industrial applications. The consumption of solar energy for cooking applications has found significant success. Various innovations have been employed in facilitating cooking during off-sunshine hours. Thermal energy storage helps in overcoming the fluctuations in the supply of energy required for cooking during different time periods of the day. This study focuses on the different types of thermal energy storage mediums that are currently utilized in solar cooking. Primarily, oils and pebbles are most commonly used as sensible heat storage (SHS) while organic phase change materials (PCMs) are used as latent heat thermal energy storage materials (LHTES). The properties and performances of various SHS and latent heat storage (LHS) mediums have been compared for their suitable utilization. SHS materials are cost-effective but have lower thermal gradient compared to LHTES materials. The energy storage capability of LHTES is high while degradation with the increasing number of charging and discharging cycles is also considerable. The melting point should be close to the utilization temperature for being used as LHTES as thermal diffusivity of the materials greatly influences the performance of solar cookers. The cooking time is lower for solar cooking systems equipped with energy storage compared to non-equipped cooking systems. It is recognized that the use of energy storage has been proved as a huge advantage to solar cooking systems, however, the design, and heat transfer characteristics of the cooking vessel along with the storage material type and volume must be optimized in order to make this technology more influential.

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“…The cooking time was reduced by one hour when paraffin wax used as an energy storage medium. 23 Comparative studies between solar cooker with and without energy storage was reported by Reddy et al 2 Paraffin PCM was used and a temperature difference of 17 °C was maintained during evening time in the cooker with TES compared to the cooker without TES.…”

Section: Use Of Organic Pcmmentioning

confidence: 99%

“…1 The social importance of solar cookers was explored by Escobar. 2 The unavailability of energy during off-sunshine hours is its major drawback. Solar cookers with thermal energy storage (TES) are a good alternative to the traditional cooking methods and also reduce CO 2 emissions in a significant manner.…”

Section: Introductionmentioning

confidence: 99%

Analysis of energy storage materials for developments in solar cookers

Khatri

¹

,

Goyal²,

Sharma³

2022

F1000Res

1

0

View full text Add to dashboard Cite

Solar energy is accessible freely and can be utilized for many household and industrial applications. The consumption of solar energy for cooking applications has found significant success. Various innovations have been employed in facilitating cooking during off-sunshine hours. Thermal energy storage helps in overcoming the fluctuations in the supply of energy required for cooking during different time periods of the day. This study focuses on the different types of thermal energy storage mediums that are currently utilized in solar cooking. Primarily, oils and pebbles are most commonly used as sensible heat storage (SHS) while organic phase change materials (PCMs) are used as latent heat thermal energy storage materials (LHTES). The properties and performances of various SHS and latent heat storage (LHS) mediums have been compared for their suitable utilization. SHS materials are cost-effective but have lower thermal gradient compared to LHTES materials. The energy storage capability of LHTES is high while degradation with the increasing number of charging and discharging cycles is also considerable. The melting point should be close to the utilization temperature for being used as LHTES as thermal diffusivity of the materials greatly influences the performance of solar cookers. The cooking time is lower for solar cooking systems equipped with energy storage compared to non-equipped cooking systems. It is recognized that the use of energy storage has been proved as a huge advantage to solar cooking systems, however, the design, and heat transfer characteristics of the cooking vessel along with the storage material type and volume must be optimized in order to make this technology more influential.

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