JP2006333556A - Power supply controller of electric system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To effectively improve a fuel consumption even if an electric system uses a storage apparatus having a restriction of charging and discharging. <P>SOLUTION: Early consumable power is calculated as power early consumed by a power demand in an electric load (S203). A calculation for determining distributed power supplied from power suppliers and minimizing a power cost in the whole electric system is implemented based on the power cost, the power required for the electric load and the early consumable power (S210). <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an electric power supply control device.

2. Description of the Related Art Conventionally, there has been proposed a vehicle electrical system management method aimed at improving fuel efficiency by managing the power cost of the vehicle electrical system (see, for example, Patent Document 1). The vehicle electrical system management method disclosed in Patent Document 1 acquires or calculates information on power cost, which is the cost per unit power of each power energy supply source such as engine power generation or deceleration regenerative power generation. Based on this, the power supply ratio of the power energy supply source and the power reception ratio of the electric load or the battery are adjusted in the direction in which the power energy cost is reduced.
JP 2004-260908 A

  By the way, in the conventional management method described above, when the power generation cost can be reduced, the power is stored in the battery, and when the power generation cost is high, the power is discharged from the battery, thereby reducing the power cost of the entire electric system. Is possible.

  However, for example, in the case of an electric system using a power storage device that has a high internal resistance and deteriorates rapidly due to repeated charge and discharge, such as a lead storage battery, the deterioration of the power storage device is suppressed while securing a necessary power supply voltage. Therefore, it is difficult to charge and discharge a large amount of power at a time, and as a result, the total output power from each power supply source becomes more dependent on the required power of the electrical load, and the entire electrical system It becomes difficult to reduce power costs.

  The present invention has been made in view of the above problems, and provides an electric power control device that can effectively improve fuel efficiency even in an electric system using a power storage device with restrictions on charging and discharging. The purpose is to provide.

The electric power supply control device according to claim 1, which is made to achieve the above object, is a power supply control device that controls distribution of supply power supplied to an electric load from a plurality of power supply sources.
Power control device
Calculate the power cost, which is the cost per unit power, for the power supplied by each power supplier,
Calculate the electrical load required power, which is the power required for the operation of the electrical load,
Calculate the pre-consumable power that the electrical load can consume before the demand,
Based on the electric power cost, electric load required electric power, and preceding consumable electric power, the distribution of the electric power supplied by each electric power supply source is determined so that the electric power cost of the entire electric system is minimized,
Control is performed so that the supply power of the determined distribution is supplied from each power supply source.

  For example, in an electrical system including a power storage device with restrictions on charging and discharging, such as a lead-acid battery, it is necessary to suppress the deterioration of the power storage device. It is necessary to avoid repeated charging and discharging, such as discharging power from the power storage device when the power generation cost is high. Therefore, it becomes impossible to reduce the power cost of the entire electrical system.

  Therefore, in the present invention, although it is not necessary at the present time, the preceding consumable power that is the power that can be consumed in advance of the power demand of the electric load is calculated, and the electric power of the entire electric system is calculated based on the preceding consumable power. The power supply distribution of each power supply source with the lowest cost is determined.

  As a result, if necessary, it can be consumed in advance of power demand and can be supplied in advance, so that the power supply of each power supply source is minimized so that the power cost of the entire electrical system is minimized. Even in an electric system including a power storage device with restrictions on charging and discharging, such as a lead storage battery, fuel efficiency can be effectively improved.

  According to the electric power supply control device of claim 2, the electric system includes the power storage device, and the power supply control device controls the distribution of the electric load and the supply power supplied to the power storage device. It is characterized by that. Thereby, in the electric system including the power storage device, the distribution of the electric load and the supply power supplied to the power storage device can be controlled.

  The power supply control device for the electric system according to claim 3, as the other electric power different from the electric load required electric power, the pre-supplied electric power supplied in advance of the demand for the electric load for reducing the electric power cost of the entire electric system. Control is performed so that the preceding supply power is supplied to the electric load that is calculated and shows the power that the preceding consumable power exceeds zero. As a result, it is possible to supply the preceding supply power separately from the electric power while reliably supplying the electric load necessary power that the electric load originally needs.

  The electric power supply control device according to claim 4 requires an electric load from a total supply power from each power supply source in which the power cost of each power supply source is equal to or lower than a predetermined target cost and the power cost is minimized. The power obtained by subtracting the power and the required charging power of the power storage device is calculated as the preceding supply power. Thereby, the preceding supply power which can be actually supplied can be calculated.

  The electric power supply control device according to claim 5, wherein when the minimum power cost of each power supply source is a constant power region with respect to the supplied power, the total supply power from each power supply source is each power supply It is characterized in that the maximum value of the supply power that is the minimum power cost within a range that does not exceed the original maximum supply power and does not exceed the preceding consumable power is calculated as the preceding supply power. Thereby, more electric power with low electric power cost can be allocated as preceding supply electric power.

  According to a sixth aspect of the present invention, there is provided a power control apparatus for an electric system that calculates priority of an electric load that supplies preceding supply power, and performs control so that the preceding supply power is supplied in descending order of priority. . Thereby, prior supply electric power can be allocated from the electric load with high priority.

  According to the electric power control apparatus of the electric system according to claim 7, the electric system has an electric cooling fan for cooling the engine as an electric load, and the electric power control apparatus performs electric cooling based on the cooling water temperature of the engine. It is characterized in that the preceding consumable power of the fan is calculated.

  The required power of the electric cooling fan is normally set (solid line) so that the engine coolant temperature is balanced in the temperature range between the set maximum temperature and the set maximum temperature, as shown by the solid line in FIG. However, the required power in the figure is the minimum power required to prevent excessive engine temperature rise, and the power consumption increases at any water temperature in the temperature range between the set minimum temperature and the set maximum temperature. Even if cooling is performed before the cooling water temperature approaches the set maximum temperature (that is, the cooling capacity is increased), it does not affect the operation or emission of the engine. In addition, since the power consumed in advance is power that is required as the cooling water temperature increases, the total power consumption of the entire electric system does not change greatly.

  Therefore, as the preceding consumable power, as shown by the dotted line in FIG. 3, in the temperature range between the set minimum temperature and the set maximum temperature, the preceding consumable power with the maximum power consumption of the electric cooling fan as an upper limit is set. (This pre-consumable power does not include the required power at that time). Thereby, the preceding consumable power of the electric cooling fan can be calculated from the set preceding consumable power based on the engine coolant temperature.

  The electric power supply control device according to claim 8, wherein the electric power consumption control device sets the electric power that can be consumed in advance so that the total electric power of the electric power that can be consumed in advance and the electric power required for the electric load is equal to or less than the maximum electric power consumption of the electric load. It is characterized by calculating. Thereby, it can prevent that the voltage level of an electric system will be in the unstable state with the electric power which is not consumed by the electric load.

  According to a ninth aspect of the present invention, there is provided a power supply control device for an electric system, which calculates preceding consumable power that is equal to or less than a target charging cost of a power storage device. For example, as shown in FIG. 5, when the remaining capacity of the battery as the power storage device is larger, the charging target cost is set smaller, and when the remaining charging capacity is smaller, the charging target cost is set larger. When the cost is high, less power can be consumed in advance. As a result, it is possible to prevent a large amount of power from being consumed in advance when the charging target cost is high.

  Embodiments of an electric power supply control apparatus according to the present invention will be described below with reference to the drawings. In the present embodiment, an application example of an electric power supply control device in an automobile will be described. However, the present invention is not limited to an automobile. Electricity of a mobile object including a power source such as an engine such as a railway vehicle, a ship, an aircraft, etc. It can also be applied to the system.

  FIG. 1 is a block diagram showing an electric system of a vehicle in the present embodiment. The engine 101 is connected to an engine generator 102 such as an alternator by a belt 107. The engine generator 102 is connected through a power line (power bus) 108 to, for example, a battery 103 and a load control unit 110a to 110e as a power storage device having restrictions on charging and discharging such as a lead storage battery.

  The load control unit 110a performs power feeding control of the loads 111a1 to 111a3, the load control unit 110b performs power feeding control of the loads 111b1 to 111b3, and the load control unit 110e performs power feeding control of the loads 111e1 to 111e3. These load control means 110a to 110e include operation switches (not shown) necessary for performing the above control and various sensors (not shown) for this control. External input signals and outputs of these sensors are included. Depending on the output, the output control of the load belonging to itself is performed or interrupted.

  The engine control means 104 is a control device for controlling the engine 101, is connected to the power supply control means 105, and is detected by a sensor (not shown) that detects various states of the engine 101. Various information such as the number of revolutions is transmitted to the power supply control means 105, and the output of the engine 101 is increased or decreased according to a command from the power supply control means 105.

  The waste heat regenerator 113 is a device that converts waste heat of the exhaust gas exhausted from the engine 101 and the engine 101 into power. The waste heat generator 112 generates power using the power converted by the waste heat regenerator 113, and the power is output to the power bus 108.

  The power control means 105 monitors the state of the engine generator 102, the waste heat generator 112, the battery 103, the power bus 108, and the like. Further, an engine power generation control unit as a controller for controlling the engine generator 102 and a waste heat power generation control unit (none of which are shown) as a controller for controlling the waste heat power generator 112 are provided. The power generated by the engine generator 102 and the waste heat generator 112 is controlled by a command from the power supply control means 105.

  The power control means 105 is connected to the load control means 110a to 110b through the multiplex signal transmission line 106, and exchanges information bi-directionally with the load control means 110a to 110b through multiplex communication.

  A battery current sensor 107, a temperature sensor 114, and a battery voltage sensor (not shown) are connected to the power supply control means 105. The battery control unit 105 receives the input / output current, battery temperature, and battery voltage of the battery 103 and receives the state of the battery 103 (remaining) Capacity).

  Hereafter, the characteristic part of this embodiment is demonstrated. In an electrical system including a power storage device with restrictions on charging and discharging as in this embodiment, it is necessary to avoid frequent charging and discharging of a large current in order to suppress deterioration of the power storage device. In this way, there is a limit to charge / discharge repetition, such as storing power in the power storage device when the power generation cost can be reduced, and releasing power from the power storage device when the power generation cost is high. Therefore, it becomes difficult to reduce the power cost of the entire electrical system.

  Therefore, in the present embodiment, as in the conventional case, not only the timing of charging / discharging the power storage device is determined based on the power cost, but also, for example, power is generated at a timing when the power cost is low, and the demand is advanced. The power consumption timing is determined based on the power cost, such that the power consumption is suppressed by suppressing the power consumption of the load that has previously consumed power at the timing when the power is consumed and the power cost is high.

  In other words, although it is not necessary at the present time, the preceding consumable power, which is the power that can be consumed in advance of the power demand of the electric load, is calculated, and based on this preceding consumable power, the power cost of the entire electrical system is minimized. The distribution of the supply power of each power supply source is determined.

  Next, the operation of the power management process executed by the power control unit 105 will be described according to the flow of the flowchart shown in FIG. In the present embodiment, the power supply sources are the engine generator 102 (power supply source α), the waste heat generator 112 (power supply source β), and the battery 103 (power supply source γ). Further, the following power management process is repeatedly executed every predetermined time (time step).

  In step (hereinafter referred to as S) 201 shown in FIG. 2, the maximum supply power that can be constantly supplied from each power supply source is calculated. The maximum supply power of the power supply sources α and β is determined by the maximum supply power of the engine generator 102 and the waste heat generator 112, the efficiency, the power that can be absorbed from the engine 101 that is the power source, the waste heat regenerator 113, and the like. . The maximum supply power of the power supply source γ is determined as the maximum discharge power that can maintain the bus voltage of the power supply bus 108 at a predetermined voltage or higher.

  In S202, the power cost for the power supplied by each power supply source is calculated. The power cost is calculated at predetermined power intervals between the supply power of zero (0) [kW] and the maximum supply power of each power supply source, and the fuel consumption increase amount [g / kWh].

  For example, regarding the power cost of the power supply source α (engine power generation), the engine output when the power generation is zero at the current engine speed is b_base [kW], the fuel consumption rate of the engine 101 is a1 [g / kWh], When the fuel consumption rate when the supply power generated by the engine generator 102 is b [kW] is a2 [g / kWh] and the input power of the generator is b2 [kW], the supply power b [kW] The power cost corresponding to is obtained by the following equation. However, the power cost when (b = 0) is zero (0).

(Equation 1)
Electric power cost [g / kWh] = (a2 × (b_base + b2) −a1 × b_base) / b
Since the power supply source β (waste heat power generation) uses the waste heat of the engine 101 as a power source, the fuel consumption of the engine 101 does not increase, so the power cost is always zero (0). For the power supply source γ (battery), a time average value of the power cost of the charging power at the time of battery charging is calculated, and this is used as the power cost. It is assumed that the power cost of the power supply source γ (battery) does not change depending on the supplied power.

  In S203, the electric load required power that is the total electric power required for each electric load calculated based on the load switch and other operating conditions, the preceding consumable power, and the priority are calculated. The pre-consumable power is power that can be consumed in advance of demand for electric loads, although it is not currently required immediately. The preceding consumable power is set for each electric load, and is not necessarily set for all electric loads.

  As the preceding consumable power calculated here, the preceding consumable power is calculated so that the total power of the preceding consumable power of the electric load and the required electric load is equal to or less than the maximum power consumption of the electric load. Thereby, it can prevent that the voltage level of an electric system will be in the unstable state with the electric power which is not consumed by the electric load.

  Examples of the electric load that can be set for the preceding consumable power include an electric cooling fan of the engine 101. The required power of the electric cooling fan is normally set so that the cooling water temperature of the engine 101 is balanced in the temperature range between the set maximum temperature and the set maximum temperature, as indicated by the solid line shown in FIG.

  However, the required power in the figure is the minimum power required to prevent an excessive temperature rise of the engine 101. In any temperature range between the set minimum temperature and the set maximum temperature, the power consumption can be achieved at any water temperature. Even if the cooling is increased before the cooling water temperature approaches the set maximum temperature (ie, the cooling capacity is increased), the operation of the engine 101, the emission, etc. are not affected. In addition, since the power consumed in advance is power that is required as the cooling water temperature increases, the total power consumption of the entire electric system does not change greatly.

  Therefore, as the preceding consumable power, the preceding consumable power with the maximum power consumption of the electric cooling fan as an upper limit is set in the temperature range between the set minimum temperature and the set maximum temperature as shown by the dotted line in FIG. (This prior-consumable power does not include the required power at that time.) Thereby, the preceding consumable power of the electric cooling fan can be calculated from the set preceding consumable power based on the engine coolant temperature.

  In S203, the priority of each electric load is calculated. The priority of each electric load is determined according to the operation state of each electric load as disclosed in Japanese Patent Application Laid-Open No. 2004-194495. Thereby, the advance supply electric power mentioned later can be allocated from the electrical load with a high priority.

  In S204, the charging required power and the preceding supply power of the battery 103 are calculated. The required charging power is the power to charge the battery 103, is determined by the remaining capacity of the battery 103 determined by the battery voltage, input / output current, temperature, etc., and the maximum input power at which the battery 103 does not exceed a predetermined upper limit voltage It is decided as follows.

  FIG. 5 shows an outline of a method for calculating the required charging power. As the input when calculating the required charging power, the power of the power supply sources α and β is excluded from the target charging cost and the power supply source γ calculated in S202 (because charging from the battery 103 to the battery 103 is impossible). Cost information, maximum charging power of the battery 103 (maximum input power at which the battery 103 does not exceed a predetermined upper limit voltage), and electric load required power. Based on these input values, a value obtained by subtracting the electric load required power from the maximum power that can be output below the charging target cost is output as the required charging power. However, the required charging power is not less than zero (0) and not more than the maximum required power.

  The charging target cost indicates the target of the power cost when charging the battery 103, and is determined by the remaining capacity of the battery 103 as shown in the target cost map, and is set small when the remaining capacity of the battery 103 is large. When the remaining capacity is small, it is set large. For example, when the remaining capacity of the battery 103 is sufficient and the charging target cost is zero (0), the battery 103 is not charged except for the electric power whose power cost is zero (0) such as waste heat regeneration. In addition, when the remaining capacity of the battery 103 decreases, the charging target cost is gradually increased so that the battery 103 does not run out of electric power when the battery 103 covers the electric load necessary power during parking, and charging is performed even if the power cost is generated. To do.

  In addition, when the total power obtained by summing up the maximum supply powers of the power supply sources α and β other than the battery 103 is smaller than the electric load required power, the battery 103 is forced to discharge, so the charge request power is set to zero (0). Is done.

  On the other hand, the pre-supplied power is power that is supplied prior to the generation of the required power in the electric load in order to reduce the power cost. FIGS. 6A and 6B show a method for calculating the preceding supply power. FIG. 6A shows the time of power generation by the engine generator 102. As shown in FIG. 5A, the preceding supply power is calculated from the total supply power at which the power cost of the power supply source is equal to or lower than a predetermined target cost smaller than the charge target cost and the power cost is minimized. It is assumed that the required electrical load power and the required charging power are subtracted.

  Further, as shown in FIG. 6B, when the minimum power cost of each power supply source is a constant power region with respect to the supplied power, such as during deceleration (during deceleration regeneration), that is, the minimum When more power can be output at the power cost, the total supply power does not exceed the maximum total supply power of the power supply source and the preceding supply power does not exceed the preceding consumable power as the preceding supply power Set to the maximum value of the supplied power that is the minimum power cost in the range.

  Thereby, more electric power with low electric power cost can be allocated as preceding supply electric power. Then, by bringing the power consumption of the electric load ahead of demand, the total supply power can be adjusted so as to reduce the power cost, and the fuel efficiency can be further improved.

  In S205, it is determined whether the electric load required power is larger than the total power of the maximum supply power of the power supply sources α, β, γ. If an affirmative determination is made (power shortage), the process proceeds to S213. If a negative determination is made, the process proceeds to S208.

  In S208, it is determined whether the required charging power of the battery 103 is zero (0) or more. Here, when the required charging power is zero (0) or more, in S209, since the battery 103 cannot be discharged simultaneously with charging, the maximum supply power of the power supply source γ (battery) is set to zero (0). And

  In S213, the load control means 110a to 110e is instructed after adjusting so that the required electric load power is equal to or less than the total power of the maximum supply power of the power supply sources α, β, γ. In S214, each power supply source is instructed. Allocate the maximum power supply as distributed power.

  In S210, an operation for determining the distributed power of each power supply source is performed. A method for determining the distributed power will be described with reference to FIG. In addition, the figure has shown the case where the charge request | requirement electric power to the battery 103 is zero (0). The distribution power of each power supply source is such that the total value of the power supply from each power supply source is equal to the total power of the electric load request power and the charge request power (charge request power = 0 in the figure), and each power supply This is determined by obtaining a combination of power supply sources that minimizes the fuel consumption rate, which is the power cost associated with power supply, on condition that the original supply power does not exceed the maximum supply power of the power supply source.

  Thereby, in the electric system including the power storage device, the distribution of the electric load and the supply power supplied to the power storage device can be controlled, and the fuel consumption rate, that is, the power cost of the entire electric system can be minimized.

  In S211, the preceding consumable power of each electric load in descending order of the priority of each electric load calculated in S203 with respect to the electric load in which the preceding consumable power is greater than zero in S203. Assign a smaller range. In S212, a supply command amount indicating the distributed power of each power supply source is transmitted to each power supply source. As a result, it is possible to supply the preceding supply power separately from the electric power while reliably supplying the electric load necessary power that the electric load originally needs. In the next time step, the process proceeds to S201, and the above-described process is repeated.

  As described above, in the electric system of the vehicle according to the present embodiment, if necessary, it can be consumed in advance of power demand and can be supplied in advance, so that the power cost of the entire electric system is minimized. Thus, even when the electric system includes a power storage device with restrictions on charging and discharging, such as a lead storage battery, while adjusting the supply power of each power supply source, it is possible to effectively improve fuel efficiency.

  In the present embodiment, the electric cooling fan of the engine 101 is taken as an example of the electric load that can be set for the preceding consumable power. However, in addition to this, the electric power of the thermal system such as the compressor, heater, defogger, etc. If it is a load, it is generally applicable.

It is a block diagram which shows the electric system of the vehicle in embodiment of this invention. 3 is a flowchart showing a flow of power management processing executed in a power supply control means 105. It is a figure for demonstrating preceding consumption power. It is a figure for demonstrating the calculation method of distributed electric power. 6 is a diagram for explaining a method for calculating required charging power of a battery 103. FIG. (A) is a figure for demonstrating the calculation method of the advance supply electric power at the time of engine electric power generation, (b) is a figure for demonstrating the calculation method of the advance supply electric power at the time of deceleration (regeneration).

Explanation of symbols

  DESCRIPTION OF SYMBOLS 101 ... Engine, 102 ... Engine generator, 103 ... Battery, 104 ... Engine control means, 105 ... Power supply control means, 106 ... Multiple communication line, 107 ... Current sensor , 108 ... power line (power bus), 110a to e ... load control means, 112 ... waste heat generator, 113 ... waste heat regenerator, 114 ... temperature sensor

Claims (9)

In an electric power supply control device that controls the distribution of supply power supplied to an electric load from a plurality of power supply sources,
The power supply control device
Calculate a power cost that is a cost per unit power for the power supplied by each power supply source,
Calculating the electric load required power, which is the power required for the operation of the electric load,
Calculating the preceding consumable power that the electrical load can be consumed in advance of demand;
Based on the electric power cost, the electric load required electric power, and the preceding consumable electric power, the distribution of the electric power supplied to each electric power supply source is determined so that the electric power cost of the entire electric system is minimized,
An electric power supply control apparatus for controlling the supply power of the determined distribution to be supplied from each of the power supply sources. The electrical system includes a power storage device,
The electric power control apparatus according to claim 1, wherein the power control apparatus controls distribution of power supplied to the electric load and the power storage device. The power supply control device
As another power different from the power required for the electrical load, a preceding supply power to be supplied in advance of the demand for the electrical load for reducing the power cost of the entire electrical system is calculated.
The electric power supply control device according to claim 1 or 2, wherein control is performed such that the preceding supply power is supplied to an electric load indicating the power that the preceding consumable power exceeds zero.   The power supply control device includes the electric load required power and the power storage from the total supply power from each power supply source in which the power cost of each power supply source is a predetermined target cost or less and the power cost is minimized. 4. The electric power supply control device according to claim 3, wherein the power obtained by subtracting the charging required power of the device is calculated as the preceding supply power.   When the minimum power cost of each power supply source is a constant power region with respect to the supplied power, the power supply control device determines that the total supply power from each power supply source is the maximum supply power of each power supply source. 4. The electric power supply control device according to claim 3, wherein a maximum value of supply power that is a minimum power cost within a range not exceeding the preceding consumable power is calculated as the preceding supply power. . The power supply control device
Calculating the priority of the electrical load supplying the preceding supply power;
The electric power supply control device according to any one of claims 3 to 5, wherein control is performed so that the preceding supply power is supplied in descending order of priority. The electric system has an electric cooling fan for cooling the engine as the electric load,
The electric power supply control according to any one of claims 1 to 6, wherein the power supply control device calculates preceding consumable power of the electric cooling fan based on a cooling water temperature of the engine. apparatus.   The power supply control device calculates the preceding consumable power so that a total power obtained by totaling the preceding consumable power of the electric load and the required electric load is equal to or less than the maximum power consumption of the electric load. The power supply control device for an electric system according to any one of claims 1 to 7.   The electric power supply control device according to any one of claims 2 to 8, wherein the power supply control device calculates a pre-consumable power that is equal to or lower than a charging target cost of the power storage device.

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