Lithium ion battery charging method and battery-equipped device

The invention claimed is: 1. A lithium ion battery charging method which performs constant current charging of a lithium ion battery, wherein the constant current charging includes at least three consecutive charging stages, the at least three consecutive charging stages include consecutive first, second, and third charging stages, a negative-electrode active material of the lithium ion battery includes graphite, and the second charging stage has a set current value which is set lower than set current values of the first and third charging stages, and is performed under a charging state in which there is a change in a crystal state of the graphite. 2. The lithium ion battery charging method according to claim 1 , wherein an upper limit value of the set current value during charging in the second charging stage is set lower than upper limit values of the set current values or the set watt values during charging in the first and third charging stages, under irregular and repetitive control of charging and discharging. 3. The lithium ion battery charging method according to claim 1 , wherein the second charging stage includes one or more suspension periods in which charging is suspended. 4. The lithium ion battery charging method according to claim 1 , wherein the set current value depends on a temperature of the lithium ion battery or an ambient temperature of the lithium ion battery. 5. A battery-equipped device comprising: a lithium ion battery; and a charging controller which is configured to control charging of the lithium ion battery using the lithium ion battery charging method according to claim 1 . 6. The lithium ion battery charging method according to claim 1 , wherein a diffraction image of the graphite particles measured by a wide angle X-ray diffraction method has a peak attributed to a (101) plane and a peak attributed to a (100) plane, and a ratio of intensity I (101) of the peak attributed to the (101) plane and intensity I (100) of the peak attributed to the (100) plane satisfies 0.01<I(101)/I(100)<0.25. 7. The lithium ion battery charging method according to claim 1 , wherein a diffraction image of the graphite particles measured by a wide angle X-ray diffraction method has a peak attributed to a (101) plane and a peak attributed to a (100) plane, and a ratio of intensity I (101) of the peak attributed to the (101) plane and intensity I (100) of the peak attributed to the (100) plane satisfies 0.08<I(101)/I(100)<0.2. 8. A lithium ion battery charging method which performs constant watt charging of a lithium ion battery, wherein the constant watt charging includes at least three consecutive charging stages, the at least three consecutive charging stages include consecutive first, second, and third charging stages, a negative-electrode active material of the lithium ion battery includes graphite, and the second charging stage has a set watt value which is set lower than set watt values of the first and third charging stages, and is performed under a charging state in which there is a change in a crystal state of the graphite. 9. The lithium ion battery charging method according to claim 8 , wherein an upper limit value of the set watt value during charging in the second charging stage is set lower than upper limit values of the set current values or the set watt values during charging in the first and third charging stages, under irregular and repetitive control of charging and discharging. 10. The lithium ion battery charging method according to claim 8 , wherein the second charging stage includes one or more suspension periods in which charging is suspended. 11. The lithium ion battery charging method according to claim 8 , wherein the set watt value depends on a temperature of the lithium ion battery or an ambient temperature of the lithium ion battery. 12. A battery-equipped device comprising: a lithium ion battery; and a charging controller which is configured to control charging of the lithium ion battery using the lithium ion battery charging method according to claim 8 . 13. The lithium ion battery charging method according to claim 8 , wherein a diffraction image of the graphite particles measured by a wide angle X-ray diffraction method has a peak attributed to a (101) plane and a peak attributed to a (100) plane, and a ratio of intensity I (101) of the peak attributed to the (101) plane and intensity I (100) of the peak attributed to the (100) plane satisfies 0.01<I(101)/I(100)<0.25. 14. The lithium ion battery charging method according to claim 8 , wherein a diffraction image of the graphite particles measured by a wide angle X-ray diffraction method has a peak attributed to a (101) plane and a peak attributed to a (100) plane, and a ratio of intensity I (101) of the peak attributed to the (101) plane and intensity I (100) of the peak attributed to the (100) plane satisfies 0.08<I(101)/I(100)<0.2.