Rotating electrical machine

The invention claimed is: 1. A rotating electrical machine, comprising: a housing; a rotor including a field winding, the rotor being coaxially fixed to a rotation shaft which is supported by the housing in a rotatable manner; a stator including an armature winding, the stator being fixed to the housing so as to surround the rotor; a slip ring fixed to the rotation shaft; a brush disposed at a position in contact with the slip ring; urging member for urging the brush against the slip ring; a temperature detector that acquires information on a temperature of the brush; a rotation sensor that acquires information on a rotation angle of the rotation shaft; and a processor storing instructions configured to implement; a wear amount calculation section for acquiring the temperature of the brush based on temperature information including output information of the temperature detector, and for calculating a total wear amount of the brush by integrating a product of a value corresponding to the temperature of the brush, the value being a wear amount function defined as a wear amount per unit sliding distance of the brush with the temperature of the brush used as a variable, and a value including a rotational speed of the rotor determined based on a temporal change of the rotation angle of the rotation shaft, with respect to time from immediately after start of use of the brush to a current time. 2. A rotating electrical machine according to claim 1 , wherein the wear amount function is defined as a function including the rotational speed of the rotor as a variable, and wherein the wear amount calculation section calculates the total wear amount of the brush by integrating a product of a value of the wear amount function corresponding to an output of the rotation sensor and the value including the rotational speed of the rotor, with respect to the time from immediately after the start of use of the brush to the current time. 3. A rotating electrical machine according to claim 1 , further comprising a current detector for acquiring information on a field current flowing through the field winding, wherein the wear amount function is defined as a function including the field current as a variable, and wherein the wear amount calculation section calculates the total wear amount of the brush by integrating a product of a value of the wear amount function corresponding to outputs of the temperature detector and the current detector and the value including the rotational speed of the rotor, with respect to the time from immediately after the start of use of the brush to the current time. 4. A rotating electrical machine according to claim 3 , further comprising: a battery; a field circuit section, implemented by the processor, for turning ON/OFF energization between the battery and the field winding; a power circuit section, implemented by the processor, for turning ON/OFF energization between the battery and the armature winding; and a circuit control section, implemented by the processor, for controlling the power circuit section and the field circuit section, wherein the wear amount calculation section serves also as the current detector, and acquires information on a magnitude of the field current based on an output voltage of the battery and a duty cycle of the field circuit section. 5. A rotating electrical machine according to claim 3 , further comprising: a battery; a field circuit section, implemented by the processor, for turning ON/OFF energization between the battery and the field winding; a power circuit section, implemented by the processor, for turning ON/OFF energization between the battery and the armature winding; and a circuit control section, implemented by the processor, for controlling the power circuit section and the field circuit section, wherein the wear amount calculation section is configured to: calculate a voltage applied to the brush based on an output voltage of the battery and a duty cycle of the field circuit section, and calculate a resistance value of the brush as an electric charge-converted resistance value based on the calculated output voltage and the field current measured by the current detector; and calculate a current length of the brush based on the total wear amount of the brush, calculate a current resistance value of the brush as a wear amount-converted resistance value based on information on a resistance value of the brush measured before the brush wears, and reflect a result of comparison between the electric charge-converted resistance value and the wear amount-converted resistance value in a calculation of a wear amount of the brush, thereby calculating the total wear amount of the brush. 6. A rotating electrical machine according to claim 1 , further comprising a current detector for acquiring information on a field current flowing through the field winding, wherein the wear amount function is defined as a function including the field current and the rotational speed of the rotor as variables, and wherein the wear amount calculation section calculates the total wear amount of the brush by integrating a product of the wear amount function corresponding to outputs of the temperature detector, the current detector, and the rotation sensor and the value including the rotational speed of the rotor, with respect to the time from immediately after the start of use of the brush to the current time. 7. A rotating electrical machine according to claim 6 , further comprising: a battery; a field circuit section, implemented by the processor, for turning ON/OFF energization between the battery and the field winding; a power circuit section, implemented by the processor, for turning ON/OFF energization between the battery and the armature winding; and a circuit control section, implemented by the processor, for controlling the power circuit section and the field circuit section, wherein the wear amount calculation section serves also as the current detector, and acquires information on a magnitude of the field current based on an output voltage of the battery and a duty cycle of the field circuit section. 8. A rotating electrical machine according to claim 6 , further comprising: a battery; a field circuit section, implemented by the processor, for turning ON/OFF energization between the battery and the field winding; a power circuit section, implemented by the processor, for turning ON/OFF energization between the battery and the armature winding; and a circuit control section, implemented by the processor, for controlling the power circuit section and the field circuit section, wherein the wear amount calculation section is configured to: calculate a voltage applied to the brush based on an output voltage of the battery and a duty cycle of the field circuit section, and calculate a resistance value of the brush as an electric charge-converted resistance value based on the calculated output voltage and the field current measured by the current detector; and calculate a current length of the brush based on the total wear amount of the brush, calculate a current resistance value of the brush as a wear amount-converted resistance value based on information on a resistance value of the brush measured before the brush wears, and reflect a result of comparison between the electric charge-converted resistance value and the wear amount-converted resistance value in a calculation of a wear amount of the brush, thereby calculating the total wear amount of the brush. 9. A rotating electrical machine according to claim 1 , wherein the temperature detector measures a temperature of a predetermined part outside the brush. 10. A rotating electrical machi