Effect of particle size on phase transitions of positive active materials made from novel leady oxide during soaking process and its influence on lead-acid battery capacity

Junxiong Wang; Mingyang Li; Jingping Hu; Yan Ke; Wenhao Yu; Zhongyi Wang; Sha Liang; Keke Xiao; Huijie Hou; Jiakuan Yang

doi:10.1016/j.est.2019.101175

Effect of particle size on phase transitions of positive active materials made from novel leady oxide during soaking process and its influence on lead-acid battery capacity

Junxiong Wang, Mingyang Li, Jingping Hu, Yan Ke, Wenhao Yu, Zhongyi Wang, Sha Liang, Keke Xiao, Huijie Hou^*, Jiakuan Yang

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

7 Scopus citations

Abstract

Novel leady oxides with different particle sizes are prepared via pyrolysis of lead citrate in rotary kiln and subsequent ball-milling. The mechanism of how particle size influences the phase transition route of novel leady oxides during soaking process is investigated. PbO with larger particle size (D50 diameter = 22.4 μm) is converted to 3PbO∙PbSO4, and 3PbO∙PbSO4 is then partially transformed to PbO∙PbSO4 while PbO∙PbSO4 are gradually converted to PbSO4. PbO with smaller particle size (D50 diameter = 8.3 μm) is directly converted to PbSO4, and 3PbO∙PbSO4 is partially transformed to PbO∙PbSO4. Phase compositions after the soaking process determine the PbO2 content in positives plates because PbO2 is the oxidation product of PbSO4 in the sequent formation process. Particle size of leady oxides determines the initial capacity of testing cells through affecting the soaking process and a linear correlation between the initial capacity and PbO2 content in positive plates is obtained (R2 = 0.78). Therefore, leady oxides with larger particle size requires higher sulfuric acid density (1.045 g cm⁻³) to achieve an optimized initial capacity (2.17 Ah), while a lower sulfuric density (1.015 g cm⁻³) is recommended for small particle leady oxides to achieve an optimized capacity of 2.58 Ah.

Original language	English
Article number	101175
Journal	Journal of Energy Storage
Volume	28
DOIs	https://doi.org/10.1016/j.est.2019.101175
State	Published - Apr 2020
Externally published	Yes

Keywords

Lead-acid battery
Novel leady oxide
Particle size
Phase transitions
Positive active materials
Soaking process

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1016/j.est.2019.101175

Cite this

@article{4f899f80ca3144aaa4002f96909a554d,

title = "Effect of particle size on phase transitions of positive active materials made from novel leady oxide during soaking process and its influence on lead-acid battery capacity",

abstract = "Novel leady oxides with different particle sizes are prepared via pyrolysis of lead citrate in rotary kiln and subsequent ball-milling. The mechanism of how particle size influences the phase transition route of novel leady oxides during soaking process is investigated. PbO with larger particle size (D50 diameter = 22.4 μm) is converted to 3PbO∙PbSO4, and 3PbO∙PbSO4 is then partially transformed to PbO∙PbSO4 while PbO∙PbSO4 are gradually converted to PbSO4. PbO with smaller particle size (D50 diameter = 8.3 μm) is directly converted to PbSO4, and 3PbO∙PbSO4 is partially transformed to PbO∙PbSO4. Phase compositions after the soaking process determine the PbO2 content in positives plates because PbO2 is the oxidation product of PbSO4 in the sequent formation process. Particle size of leady oxides determines the initial capacity of testing cells through affecting the soaking process and a linear correlation between the initial capacity and PbO2 content in positive plates is obtained (R2 = 0.78). Therefore, leady oxides with larger particle size requires higher sulfuric acid density (1.045 g cm−3) to achieve an optimized initial capacity (2.17 Ah), while a lower sulfuric density (1.015 g cm−3) is recommended for small particle leady oxides to achieve an optimized capacity of 2.58 Ah.",

keywords = "Lead-acid battery, Novel leady oxide, Particle size, Phase transitions, Positive active materials, Soaking process",

author = "Junxiong Wang and Mingyang Li and Jingping Hu and Yan Ke and Wenhao Yu and Zhongyi Wang and Sha Liang and Keke Xiao and Huijie Hou and Jiakuan Yang",

note = "Publisher Copyright: {\textcopyright} 2019 Elsevier Ltd",

year = "2020",

month = apr,

doi = "10.1016/j.est.2019.101175",

language = "英语",

volume = "28",

journal = "Journal of Energy Storage",

issn = "2352-152X",

publisher = "Elsevier BV",

}

TY - JOUR

T1 - Effect of particle size on phase transitions of positive active materials made from novel leady oxide during soaking process and its influence on lead-acid battery capacity

AU - Wang, Junxiong

AU - Li, Mingyang

AU - Hu, Jingping

AU - Ke, Yan

AU - Yu, Wenhao

AU - Wang, Zhongyi

AU - Liang, Sha

AU - Xiao, Keke

AU - Hou, Huijie

AU - Yang, Jiakuan

PY - 2020/4

Y1 - 2020/4

N2 - Novel leady oxides with different particle sizes are prepared via pyrolysis of lead citrate in rotary kiln and subsequent ball-milling. The mechanism of how particle size influences the phase transition route of novel leady oxides during soaking process is investigated. PbO with larger particle size (D50 diameter = 22.4 μm) is converted to 3PbO∙PbSO4, and 3PbO∙PbSO4 is then partially transformed to PbO∙PbSO4 while PbO∙PbSO4 are gradually converted to PbSO4. PbO with smaller particle size (D50 diameter = 8.3 μm) is directly converted to PbSO4, and 3PbO∙PbSO4 is partially transformed to PbO∙PbSO4. Phase compositions after the soaking process determine the PbO2 content in positives plates because PbO2 is the oxidation product of PbSO4 in the sequent formation process. Particle size of leady oxides determines the initial capacity of testing cells through affecting the soaking process and a linear correlation between the initial capacity and PbO2 content in positive plates is obtained (R2 = 0.78). Therefore, leady oxides with larger particle size requires higher sulfuric acid density (1.045 g cm−3) to achieve an optimized initial capacity (2.17 Ah), while a lower sulfuric density (1.015 g cm−3) is recommended for small particle leady oxides to achieve an optimized capacity of 2.58 Ah.

AB - Novel leady oxides with different particle sizes are prepared via pyrolysis of lead citrate in rotary kiln and subsequent ball-milling. The mechanism of how particle size influences the phase transition route of novel leady oxides during soaking process is investigated. PbO with larger particle size (D50 diameter = 22.4 μm) is converted to 3PbO∙PbSO4, and 3PbO∙PbSO4 is then partially transformed to PbO∙PbSO4 while PbO∙PbSO4 are gradually converted to PbSO4. PbO with smaller particle size (D50 diameter = 8.3 μm) is directly converted to PbSO4, and 3PbO∙PbSO4 is partially transformed to PbO∙PbSO4. Phase compositions after the soaking process determine the PbO2 content in positives plates because PbO2 is the oxidation product of PbSO4 in the sequent formation process. Particle size of leady oxides determines the initial capacity of testing cells through affecting the soaking process and a linear correlation between the initial capacity and PbO2 content in positive plates is obtained (R2 = 0.78). Therefore, leady oxides with larger particle size requires higher sulfuric acid density (1.045 g cm−3) to achieve an optimized initial capacity (2.17 Ah), while a lower sulfuric density (1.015 g cm−3) is recommended for small particle leady oxides to achieve an optimized capacity of 2.58 Ah.

KW - Lead-acid battery

KW - Novel leady oxide

KW - Particle size

KW - Phase transitions

KW - Positive active materials

KW - Soaking process

UR - http://www.scopus.com/inward/record.url?scp=85077331527&partnerID=8YFLogxK

U2 - 10.1016/j.est.2019.101175

DO - 10.1016/j.est.2019.101175

M3 - 文章

AN - SCOPUS:85077331527

SN - 2352-152X

VL - 28

JO - Journal of Energy Storage

JF - Journal of Energy Storage

M1 - 101175

ER -

Effect of particle size on phase transitions of positive active materials made from novel leady oxide during soaking process and its influence on lead-acid battery capacity

Abstract

Keywords

UN SDGs

Access to Document

Other files and links

Fingerprint

Cite this