Metal battery, and management system and control method thereof

What is claimed is: 1. A battery management system comprising: a detection circuit configured to detect a plurality of electrical parameters of a metal battery that includes a plurality of battery cells connected to each other, the plurality of electrical parameters including a resting voltage of each of the plurality of battery cells when the metal battery is in a resting state; a memory electrically connected to the detection circuit, and storing the plurality of electrical parameters and a preset value; and a control circuit configured to: be electrically connected to the memory to obtain the plurality of electrical parameters; and determine a safety performance of the metal battery according to the electrical parameters, including: obtaining, from the memory, a value of a resting voltage of each of the plurality of battery cells at a same time when the metal battery is in the resting state; determining, for the plurality of battery cells, resting voltage differences each being a difference between values of resting voltages of two of the plurality of battery cells at the same time; determining a maximum value of the resting voltage differences; and determining the safety performance of the metal battery according to a comparison result between the maximum value of the resting voltage differences and the preset value. 2. The battery management system of claim 1 , wherein: the detection circuit includes at least one of a current detection circuit, a voltage detection circuit, or a voltameter, and/or the plurality of electrical parameters further include at least one of an energy of the metal battery, a capacity of the metal battery, a voltage of the metal battery, a current of the metal battery, an energy of each of the plurality of battery cells, a capacity of each of the plurality of battery cells, a voltage of each of the plurality of battery cells, or a current of each of the plurality of battery cells. 3. The battery management system of claim 1 , wherein the control circuit includes at least one of a microprocessor or a circuit including one or more circuit boards. 4. The battery management system of claim 1 , wherein the control circuit is further configured to: obtain values of the plurality of electrical parameters of the metal battery at different times from the memory; and determine the safety performance of the metal battery according to the values of the plurality of electrical parameters at the different times. 5. The battery management system of claim 4 , wherein: the memory further stores a preset change value; and the control circuit is further configured to: determine a change value of one of the plurality of electrical parameters of the metal battery according to the values of the plurality of electrical parameters at the different times; and determine the safety performance the metal battery further according to a comparison result between the change value and the preset change value. 6. The battery management system of claim 5 , wherein the change value is determined when the metal battery is in a charging state. 7. The battery management system of claim 6 , wherein: the plurality of electrical parameters include at least one of a charging capacity or a charging energy of one of the plurality of battery cells; and the control circuit is further configured to, while the metal battery is in a constant voltage charging state: determine at least one of an increase rate of the charging capacity or an increase rate of the charging energy according to at least one of a difference of values of the charging capacity at the different times or a difference of values of the charging energy at the different times; and in response to the at least one of the increase rate of the charging capacity or the increase rate of the charging energy being greater than the preset change value, determine that dendrites are formed inside the one of the plurality of battery cells of the metal battery and positive and negative electrodes of the one of the plurality of battery cells are connected by the dendrites. 8. The battery management system of claim 6 , wherein: the plurality of electrical parameters include a charging current of one of the plurality of battery cells; and the control circuit is further configured to, while the metal battery is in a constant voltage charging state: determine an increase rate of the charging current according to a difference of values of the charging current at the different times; and in response to the increase rate of the charging current being greater than the preset change value, determine that dendrites are formed inside the one of the plurality of battery cells of the metal battery and positive and negative electrodes of the one of the plurality of battery cells are connected by the dendrites. 9. The battery management system of claim 6 , wherein: the plurality of electrical parameters include a charging energy of one of the plurality of battery cells; and the control circuit is further configured to, while the metal battery is in a constant current charging state: determine an increase rate of the charging energy according to a difference of values of the charging energy at the different times; and in response to the increase rate of the charging energy being greater than the preset change value, determine that dendrites are formed inside the one of the plurality of battery cells of the metal battery and positive and negative electrodes of the one of the plurality of battery cells are connected by the dendrites. 10. The battery management system of claim 6 , wherein: the plurality of electrical parameters include a charging voltage of one of the plurality of battery cells; and the control circuit is further configured to, while the metal battery is in a constant current charging state: determine a decrease rate of the charging voltage according to a difference of values of the charging voltage at the different times; and in response to the decrease rate of the charging voltage being greater than the preset change value, determine that dendrites are formed inside the one of the plurality of battery cells of the metal battery and positive and negative electrodes of the one of the plurality of battery cells are connected by the dendrites. 11. The battery management system of claim 5 , wherein the change value is determined when the metal battery in a discharging state. 12. The battery management system of claim 11 , wherein: the plurality of electrical parameters include at least one of a discharging capacity or a discharging energy of one of the plurality of battery cells; and the control circuit is further configured to, while the metal battery is in the discharging state: determine at least one of an increase rate of the discharging capacity or an increase rate of the discharging energy according to at least one a difference of values of the charging capacity at the different times or a difference of values of the charging energy at the different times; and in response to the at least one of the increase rate of the discharging capacity or the increase rate of the discharging energy being less than the preset change value, determine that dendrites are formed inside the one of the plurality of battery cells of the metal battery and positive and negative electrodes of the one of the plurality of battery cells are connected by the dendrites. 13. The battery management system of claim 11 , wherein: the plurality of electrical parameters include a discharging current of one of the plurality of battery cells; and the control circuit is further configured to, wh