Study on performance optimization of sodium sulfate decahydrate phase change energy storage materials Xian Dong 1 · Jinfeng Mao 1 · Shibin Geng 1 · Yong Li 1 · Pumin Hou 1 · Huiliang Lian 1
Customer ServiceFor example, sodium sulfate decahydrate, Na 2 SO 4 ·10H 2 O (SSD), has been identified as one of the most promising salt hydrates for building applications due to its low cost (1.60 $/kWh), high energy storage capacity (254 J/g),
Customer ServiceThese results demonstrate the potential of as-prepared microencapsulated SSD composite phase-change energy storage materials for cooling water applications. Discover the
Customer ServiceIt appears that the major problem preventing use of sodium sulfate decahydrate for thermal energy storage can be avoided by using the composition which is at or slightly to the water-rich side of the invariant point in the phase diagram. A mixture of 68.2 w/o Na/sub 2/SO/sub 4/ x 10H/sub 2/O and 31.8 w/o H/sub 2/O is suggested for a TES material.
Customer ServiceFor example, sodium sulfate decahydrate, Na 2 SO 4 ·10H 2 O (SSD), has been identified as one of the most promising salt hydrates for building applications due to its low
Customer ServiceIn this paper, the system Li 2 SO 4 –Na 2 SO 4 is proposed as a candidate material for thermal energy storage applications at high temperatures (450–550 °C). Depending on the composition, the thermal energy can be stored by using a eutectoid reaction and solid–solid phase transition.
Customer ServiceCooling experiments and fruit storage performance experiments showed that SSD-BCKN3 has good potential for energy storage in cold chain transportation applications.
Customer ServiceSemantic Scholar extracted view of "Thermal energy storage using sodium sulfate decahydrate and water" by D. Biswas. Skip to search form Skip to main content Skip to account menu. Semantic Scholar''s Logo. Search 222,699,199 papers from all fields of science. Search. Sign
Customer ServiceTelkesd et al. [1,2,3] extensively studied the PCMs for energy storage applications and, for the first time, established an energy storage solar house using sodium sulfate decahydrate (Na 2 SO 4 ·10H 2 O) as a PCM. Since the 1970s, the theoretical understanding and utilization of heat storage technology have gained significant research
Customer ServiceU.S. DEPARTMENT OF ENERGY OFFICE OF ENERGY EFFICIENCY & RENEWABLE ENERGY 7 Thermal Energy Storage Research Needs 2019 Workshop on Fundamental Needs for Dynamic and Interactive Thermal
Customer ServiceSodium sulfate decahydrate (SSD) is a low-cost phase-change material (PCM) for thermal energy storage applications that offers substantial melting enthalpy and a suitable temperature range for near-ambient
Customer ServiceIn this paper, the system Li 2 SO 4 –Na 2 SO 4 is proposed as a candidate material for thermal energy storage applications at high temperatures (450–550 °C). Depending on the
Customer ServiceThese results demonstrate the potential of as-prepared microencapsulated SSD composite phase-change energy storage materials for cooling water applications. Discover the latest articles, news and stories from top researchers in related subjects.
Customer Service十水硫酸钠(sodium sulfate decahydrate,SSD)具有适宜的相变温度(2.4 ℃)、较高的相变潜热值(大于200 J/g)、价格低廉、来源广和安全无毒等优点,是一种广受关注的无机水合盐相变材料。然而,在应用过程中存在过冷度大、相分离严重
Customer ServiceThis work explores the use of sodium sulfate and diatomite to formulate composite materials for high temperature thermal energy storage applications. Sodium sulfate in the composite functions as a phase change material (PCM) and diatomite as a structural skeleton for shape stabilization.
Customer ServiceMost energy analysts believe LIB will capture most all energy-storage growth in stationery/transportation markets over the next 10 years. The appeal of LIB storage is its continuous price drop, flexible installation (including modular stacking), fast response, and short construction time.
Customer ServiceIn this paper, sodium sulfate decahydrate (SSD) with a phase transition temperature of 32 °C was selected as the phase change energy storage material. However,
Customer ServiceSodium sulfate decahydrate (Na2SO4.10H2O, SSD), a low-cost phase change material (PCM), can store thermal energy. However, phase separation and unstable energy storage capacity (ESC) limit its use. To address these concerns, eight polymer
Customer ServiceThis result is significantly important for the application of the sodium sulfate in the thermal energy storage system. Download: Download high-res image (218KB) Download: Download full-size image; Fig. 4. Temporal evolution of the spreading area of the sodium sulfate on the nanoscale calcium oxide substrate. Download: Download high-res image (203KB)
Customer ServiceIn this paper, sodium sulfate decahydrate (SSD) with a phase transition temperature of 32 °C was selected as the phase change energy storage material. However, SSD has the problems of large degree of supercooling,
Customer Service摘要: 十水硫酸钠(sodium sulfate decahydrate,SSD)具有适宜的相变温度(2.4 ℃)、较高的相变潜热值(大于200 J/g)、价格低廉、来源广和安全无毒等优点,是一种广受关注的无机水合盐相变材料。
Customer ServiceSodium sulfate decahydrate (Na2SO4.10H2O) is known to decompose peritetically upon heating to 32.4 C to yield anhydrous sodium sulfate and a saturated solution of Na2SO4 in water. Results are presented for an experimental study designed to find out a means for obtaining many of the advantages of the Na2SO4-H2O reaction for thermal energy storage while eliminating the
Customer ServiceCooling experiments and fruit storage performance experiments showed that SSD-BCKN3 has good potential for energy storage in cold chain transportation applications.
Customer ServiceThese are available for a wide range of phase transition temperature for thermal energy storage (TES) application. They have some most desired properties for TES applications like high latent heat value, good thermal conductivity, nonexpensive, and were nonflammable. Besides these, due to the undesirable properties like phase segregation,
Customer Service十水硫酸钠(sodium sulfate decahydrate,SSD)具有适宜的相变温度(2.4 ℃)、较高的相变潜热值(大于200 J/g)、价格低廉、来源广和安全无毒等优点,是一种广受关注的无机水合盐相变材料。然而,在应用过程中存在过冷度大、相分离严重及泄漏等问题。本文综述了近年来
Customer ServiceFor example, sodium sulfate decahydrate, Na 2 SO 4 ·10H 2 O (SSD), has been identified as one of the most promising salt hydrates for building applications due to its low cost (1.60 $/kWh), high energy storage capacity (254 J/g), and moderate melting temperature (32.4 °C) [20,21]. Nonetheless, the widespread use of SSD as a PCM has been
Customer ServiceSodium sulfate decahydrate (SSD) is a low-cost phase-change material (PCM) for thermal energy storage applications that offers substantial melting enthalpy and a suitable temperature range for near-ambient applications. However, SSD''s consistent phase separation with decreased melting enthalpy over repeated thermal cycles limits its
Customer ServiceSodium sulfate decahydrate (Na2SO4.10H2O, SSD), a low-cost phase change material (PCM), can store thermal energy. However, phase separation and unstable energy storage capacity
Customer ServiceMost energy analysts believe LIB will capture most all energy-storage growth in stationery/transportation markets over the next 10 years. The appeal of LIB storage is its continuous price drop, flexible installation (including modular
Customer ServiceIn this paper, sodium sulfate decahydrate (SSD) with a phase transition temperature of 32 °C was selected as the phase change energy storage material. However, SSD has the problems of large degree of supercooling, obvious phase stratification, and low thermal conductivity.
For example, sodium sulfate decahydrate, Na2 SO 4 ·10H 2O (SSD), has been identified as one of the most promising salt hydrates for building applications due to its low cost (1.60 $/kWh), high energy storage capacity (254 J/g), and moderate melting temperature (32.4 °C) [20, 21 ].
Sodium sulfate decahydrate has been studied due to its high supercooling, phase separation, and low thermal conductivity, which greatly limit the practical application of sodium sulfate decahydrate [45, 46].
The melting temperature of sodium sulfate in the composite materials is around 880 °C and no confinement effect is observed due to the nanoscale diatomite pore size. This indicates that the material should be used at temperatures over 890 °C to maximize the energy density.
In the samples SSD-BCKN3, SSD-BCKN3-1, SSD-BCKN3-2, SSD-BCKN3-3, and SSD-BCKN3-4, with the same proportion of added materials, the thermal conductivity increased with the decrease of sodium sulfate decahydrate content. The standard deviations were mostly similar.
When SSD undergoes melting, the water molecules from the crystalline SSD phase are released to the liquid water phase. The remaining anhydrous sodium sulfate (SS) salt cannot be fully dissolved in the water, resulting in a saturated salt solution with undissolved salt particles (Fig. 1 b and f).
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