Lead acid battery

The invention claimed is: 1. A flooded-type lead acid battery comprising: a plate group including: a negative plate having negative active material filled in a negative electrode current collector; and a positive plate having positive active material filled in a positive electrode current collector, the negative plate and the positive plate being stacked on each other through a separator and accommodated in a battery container together with an electrolyte, the flooded-type lead acid battery being discharged to a load in partially charged state, wherein, during use under a partial state of charge, the negative plate is contacted with, throughout a plate surface, a nonwoven fabric formed of at least one fiber material selected from a material group consisting of glass, pulp, and polyolefin, not integrated with the plate, and the negative plate contacted with the nonwoven fabric is accommodated in an envelope separator formed of a microporous synthetic resin sheet. 2. The lead acid battery according to claim 1 , wherein the nonwoven fabric is a mixed nonwoven fabric including glass fiber, pulp, and inorganic oxide powder as a principal component. 3. The lead acid battery according to claim 2 , wherein the inorganic oxide powder is silica powder. 4. The lead acid battery according to claim 1 , wherein the nonwoven fabric is bent so that surfaces are opposite to each other, and the negative plate is disposed between the surfaces opposite to each other. 5. The lead acid battery according to claim 1 , wherein the negative active material includes a bisphenol A-aminobenzene sodium sulfonate-formaldehyde condensate expressed in a chemical constitutional formula in Chemical Formula 1 as an organic compound that suppresses formation of coarse negative active materials in association with charging and discharging: where R 1 and R 2 are hydrogen or except where both of R 1 and R 2 are hydrogen. 6. The lead acid battery according to claim 5 , wherein the negative active material includes a flake graphite having an average primary particle size of 100 μm or more for the carbon conductive material. 7. The lead acid battery according to claim 5 , wherein a positive active material utilization ratio ranges from 50 to 65%. 8. The lead acid battery according to claim 2 , wherein the nonwoven fabric is bent so that surfaces are opposite to each other, and the negative plate is disposed between the surfaces opposite to each other. 9. The lead acid battery according to claim 3 , wherein the nonwoven fabric is bent so that surfaces are opposite to each other, and the negative plate is disposed between the surfaces opposite to each other. 10. The lead acid battery according to claim 2 , wherein the negative active material includes a bisphenol A-aminobenzene sodium sulfonate-formaldehyde condensate expressed in a chemical constitutional formula in Chemical Formula 1 as an organic compound that suppresses formation of coarse negative active materials in association with charging and discharging: where R 1 and R 2 are hydrogen or except where both of R 1 and R 2 are hydrogen. 11. A flooded-type lead acid comprising: a plate group including: a negative plate having negative active material filled in a negative electrode current collector; and a positive plate having positive active material filled in a positive electrode current collector, the negative plate and the positive plate being stacked on each other through a separator and accommodated in a battery container together with an electrolyte, the flooded-type lead acid battery being discharged to a load in partially charged state, wherein, of the negative plate and the positive plate, only the negative plate is contacted with, throughout a plate surface, a nonwoven fabric formed of at least one fiber material selected from a material group consisting of glass, pulp, and polyolefin, not integrated with the plate, the negative plate contacted with the nonwoven fabric is accommodated in an envelop separator formed of a microporous synthetic resin sheet, the nonwoven fabric is bent so that surfaces are opposite to each other, and the negative plate is disposed between the surfaces opposite to each other. 12. A flooded-type lead acid battery comprising: a plate group including: a negative plate having negative active material filled in a negative electrode current collector, wherein the negative active material includes formaldehyde condesates of bishenols and aminobenzenesulfonic acid; and a positive plate having positive active material filled in a positive electrode current collector, the negative plate and the positive plate being stacked on each other through a separator and accommodated in a battery container together with an electrolyte, the flooded-type lead acid battery being discharged to a load in partially charged state, wherein, of the negative plate and the positive plate, only the negative plate is contacted with, throughout a plate surface, a nonwoven fabric formed of at least one fiber material selected from a material group consisting of glass, pulp, and polyolefin, not integrated with the plate, and the negative plate contacted with the nonwoven fabric is accommodated in an envelop separator formed of a microporous synthetic resin sheet. 13. A flooded-type lead acid battery comprising: a plate group including: a negative plate having negative active material filled in a negative electrode current collector, wherein the negative active material includes lignin sodium sulfonate; and a positive plate having positive active material filled in a positive electrode current collector, the negative plate and the positive plate being stacked on each other through a separator and accommodated in a battery container together with an electrolyte, the flooded-type lead acid battery being discharged to a load in partially charged state, wherein, of the negative plate and the positive plate, only the negative plate is contacted with, throughout a plate surface, a nonwoven fabric formed of at least one fiber material selected from a material group consisting of glass, pulp, and polyolefin, not integrated with the plate, and the negative plate contacted with the nonwoven fabric is accommodated in an envelop separator formed of a microporous synthetic resin sheet.