KR20180047709A - Vehicle and Controlling Method of Vehicle - Google Patents

Abstract

A vehicle includes a generator that produces electricity; a plurality of electric components receiving power from the generator; a battery for storing a part of electric power generated from the generator; and a vehicle body control module that calculates a power availability rate from a charged amount of the battery and a power consumption amount of the electric components, and limits the operations of the electric components step by step when the power availability rate is smaller than a predetermined first reference availability rate. In addition, when the ratio of the operation limit time of the electric components to the running time of the vehicle is larger than a predetermined first reference value and the power availability ratio is smaller than a second reference availability rate which is larger than the first reference availability rate, the module can limit the operations of the electrical components step by step.

Description

[0001] The present invention relates to a method of controlling a vehicle,

The disclosed invention relates to a method of controlling a vehicle and a vehicle, and more particularly, to a method of controlling a vehicle and a vehicle that can minimize the inconvenience due to power limitation.

Generally, a vehicle means a moving means or a transportation means that travels on a road or a line using fossil fuel, electricity, or the like as a power source.

The vehicle is equipped with various electrical components to protect the driver and provide the driver with convenience and fun. For example, vehicles are equipped with electric components that consume large amounts of power, such as a traveling assistance system and seat heating.

As a result, the consumption of the battery supplying power to the starter motor is increased, causing a problem that the starter is not started, or the life of the battery is shortened.

An aspect of the disclosed invention is to provide a vehicle and a control method of a vehicle that can limit the operation of electrical components according to the availability of a battery.

Another aspect of the disclosed invention is to provide a vehicle and a control method of a vehicle that can minimize a driver's inconvenience due to restriction of operation of electric components.

According to an aspect of the disclosed invention, a vehicle includes a generator for generating electric power; A plurality of electric components supplied with power from the generator; A battery for storing a part of electric power produced by the generator; Calculating a power availability rate from a power generation amount of the generator, a charge amount of the battery, and a power consumption amount of the plurality of electric components, and if the power availability rate is smaller than a predetermined first reference utilization rate, When the ratio of the operation restriction time of the plurality of electric components to the running time of the vehicle is larger than a predetermined first reference value, the vehicle body control module determines that the power availability ratio is larger than the first reference availability ratio And the operation of the plurality of electrical components can be restricted step by step if the second reference utilization rate is smaller than the second reference utilization rate.

When the ratio of the operation limit time is not larger than the first reference value and the ratio of the number of operation limit times of the plurality of electric component parts to the number of times of driving the vehicle is larger than a predetermined second reference value, Is smaller than the second criterion availability rate, the operation of the plurality of electrical components can be limited step by step.

The vehicle body control module may limit the operation of the plurality of electric component parts in a stepwise manner if the power availability factor is smaller than the first reference value, .

When the ratio of the operation limit time is greater than the first reference value, the vehicle body control module may block the operation of the electric component previously selected by the driver.

The vehicle body control module may delay the turn-on time of the plurality of electrical components on a step-by-step basis if the power availability rate is smaller than the first reference allowable amount.

When the ratio of the operation limit time is larger than the first reference value, the vehicle body control module may delay the turn-on time of the plurality of electric component parts stepwise if the power availability ratio is smaller than the second reference use rate.

The vehicle body control module may reduce the output of the plurality of electric component parts step by step if the power availability factor is smaller than the first reference occupancy rate.

When the ratio of the operation limit time is greater than the first reference value, the body control module may reduce the output of the plurality of electric component parts step by step if the power use rate is smaller than the second reference usage rate.

The vehicle body control module may block the operation of the plurality of electrical components in a stepwise manner if the power availability rate is smaller than the first reference occupancy rate.

When the ratio of the operation limit time is larger than the first reference value, the body control module may block the operation of the plurality of electrical components in a stepwise manner if the power availability rate is smaller than the second reference value.

A method of controlling a vehicle according to an aspect of the present invention includes the steps of calculating a power availability rate from a power generation amount of a generator, a charge amount of a battery, and a power consumption amount of a plurality of electric parts; Limiting the operation of the plurality of electric component parts in a stepwise manner if the power availability factor is smaller than a predetermined first reference service factor; And when the ratio of the operation limit time of the plurality of electric components to the running time of the vehicle is larger than a predetermined first reference value and if the power availability ratio is smaller than the second reference usability rate which is larger than the first reference usage rate, And may include a step of limiting the operation of the component step by step.

When the ratio of the operation limit time is not larger than the first reference value and the ratio of the number of times of operation restriction of the plurality of electrical parts to the number of times of running of the vehicle is larger than a predetermined second reference value, And limiting the operation of the plurality of electric components in a stepwise manner if the second reference utilization rate is smaller than the second reference utilization rate.

Wherein the control method further includes a step of limiting the operation of the plurality of electric components in a stepwise fashion if the power availability percentage is larger than a third reference value rate that is larger than the second reference value, .

The step of stepwise limiting the operation of the plurality of electric component parts may include a step of blocking the operation of the electric component parts previously selected by the driver.

The step of stepwise limiting the operation of the plurality of electrical component parts when the power availability factor is smaller than the first reference value of availability may include setting the turn on time of the plurality of electrical component parts in a stepwise manner if the power availability factor is smaller than the first reference allowable amount As shown in FIG.

The step of stepwise limiting the operation of the plurality of electrical component parts when the power availability factor is smaller than the second reference attainment rate is a step of gradually changing the turn on time of the plurality of electrical component parts when the power use rate is smaller than the second reference attainment rate Delaying the process.

Wherein the step of limiting the operation of the plurality of electrical component parts in a stepwise manner if the power availability factor is smaller than the first reference use rate step includes the step of decreasing the output of the plurality of electrical component parts stepwise . ≪ / RTI >

Wherein the step of limiting the operation of the plurality of electrical component parts in a stepwise manner if the power availability factor is smaller than the second reference attainment rate is a step of gradually reducing the output of the plurality of electrical component parts when the power availability factor is smaller than the second reference attainment rate . ≪ / RTI >

Wherein the step of limiting the operation of the plurality of electric component parts in a stepwise manner if the power availability factor is smaller than the first reference use rate is a step of stepwise blocking the operation of the plurality of electric component parts when the power availability factor is smaller than the first reference value, . ≪ / RTI >

Wherein the step of limiting the operation of the plurality of electrical component parts in a stepwise manner when the power availability factor is smaller than the second reference attainment rate is a step of stepwise blocking the operation of the plurality of electrical component parts when the power availability factor is smaller than the second reference attainment rate . ≪ / RTI >

According to an aspect of the disclosed subject matter, there is provided a vehicle and a control method of a vehicle that can limit the operation of electrical components according to the availability of the battery.

According to another aspect of the disclosed invention, there is provided a vehicle and a control method of a vehicle that can minimize a driver's inconvenience due to an operation restriction of an electric component.

1 shows a vehicle according to an embodiment.
Fig. 2 shows electrical components of a vehicle according to an embodiment.
Figure 3 shows the interior of the vehicle according to one embodiment.
4 shows a power system of a vehicle according to one embodiment.
5 shows a configuration of a vehicle body control module included in a vehicle according to an embodiment.
6 shows an example of a method for limiting power consumption of a vehicle according to an embodiment.
Fig. 7 shows an example of the operation of electrical components according to the power consumption limiting method shown in Fig.
FIG. 8 shows an example of a method for improving the power availability of a vehicle according to an embodiment.
Fig. 9 shows an example of the operation of electrical components by the power availability improvement method shown in Fig.

Like reference numerals refer to like elements throughout the specification. This specification does not describe all the elements of the embodiments, and duplicate descriptions of the contents or embodiments in the technical field to which the disclosed invention belongs are omitted. The term 'part, module, member, or block' used in the specification may be embodied in software or hardware, and a plurality of 'part, module, member, and block' may be embodied as one component, It is also possible that a single 'part, module, member, block' includes a plurality of components.

Throughout the specification, when a part is referred to as being "connected" to another part, it includes not only the case directly connected but also the case where the connection is indirectly connected, and the indirect connection includes connection through the wireless communication network do.

Also, when an element is referred to as "comprising ", it means that it can include other elements as well, without departing from the other elements unless specifically stated otherwise.

Throughout the specification, when a member is located on another member, it includes not only when a member is in contact with another member but also when another member exists between the two members.

The terms first, second, etc. are used to distinguish one element from another, and the elements are not limited by the above-mentioned terms.

The singular forms " a " include plural referents unless the context clearly dictates otherwise.

In each step, the identification code is used for convenience of explanation, and the identification code does not describe the order of the steps, and each step may be performed differently from the stated order unless clearly specified in the context. have.

Hereinafter, the working principle and embodiments of the disclosed invention will be described with reference to the accompanying drawings.

1 shows a vehicle according to an embodiment. Fig. 2 shows electrical components of a vehicle according to an embodiment. Figure 3 also shows the interior of the vehicle according to one embodiment.

1, 2 and 3, a vehicle 1 includes a vehicle body 10 that forms an outer appearance of the vehicle 1 and accommodates various components, and a wheel 20 that moves the vehicle 1 do.

The vehicle body 10 forms an interior space in which the driver can stay, an engine room for accommodating the engine, and a trunk room for accommodating the cargo.

The vehicle body 10 includes a hood 11, a front fender 12, a roof panel 13, a door 14, a trunk lid 15, A quarter panel 16, and the like. A front window 17 is provided in front of the vehicle body 10 and a side window 18 is provided on a side surface of the vehicle body 10 in order to secure a view of the driver, A rear window 19 may be provided at the rear of the vehicle body 10. Further, the door 14 may be provided with a side mirror 14a for providing a rear view of the vehicle 1 to the driver.

A power generation device, a power transmission device, a steering device, a braking device, and the like may be provided inside the vehicle body 10 so that the vehicle 1 can run. The power generation device generates a rotational force and may include an engine, a fuel supply device, a cooling device, an exhaust device, an ignition device, and the like. The power transmitting device transmits the rotational force generated by the power generating device to the wheel 20, and may include a clutch, a shift lever, a transmission, a differential device, a drive shaft, and the like. The steering apparatus controls the running direction of the vehicle 1, and may include a steering wheel, a steering gear, a steering link, and the like. The braking device stops the rotation of the wheel 20 and may include a brake pedal, a master cylinder, a brake disk, a brake pad, and the like.

The wheel 20 receives rotational force from the power generating device through the power transmitting device, and can move the vehicle 1. [ The wheel 20 may include a front wheel 21 provided at the front of the vehicle and a rear wheel 22 provided at the rear of the vehicle.

The vehicle 1 may include various electrical components 30 for the safety and comfort of the driver and passenger, as well as the control of the vehicle 1, as well as the mechanical components described above.

For example, the vehicle 1 may include an engine management system (EMS) 31, a transmission control unit (TCU) 32, an electronic braking system (EBS) 33, An electric power steering (EPS) 34, an audio device 35, a heating / ventilation / air conditioning (HVAC) device 36, a battery sensor 37, body control module (BCM) 100. The vehicle 1 includes an auxiliary heater 41, a seat heater 42, a headrest heater 43, an armrest heater 44, a steering wheel heater 45, a rear window heater 46, And a side mirror heat 47. In addition, a battery B may be provided to supply electric power to the electric component parts 30. [

The engine management system 31 can control the operation of the engine and manage the engine in response to the driver's acceleration command through the accelerator pedal 31a. For example, the engine management system 31 can perform engine torque control, fuel consumption control, engine failure diagnosis, and the like.

The transmission control module 32 can control the operation of the transmission in response to the driver's shift command via the shift lever 32a or the running speed of the vehicle 1. [ For example, the transmission control module 32 can perform shift control, damper clutch control, pressure control at the time of friction clutch on / off, and engine torque control during shifting.

The electronic braking system 33 can control the braking device of the vehicle 1 and maintain the balance of the vehicle 1 in response to the driver's braking command through the braking pedal 33a. For example, the electronic braking system 33 may include an anti-lock brake system (ABS) and an electric stability control (ESC).

The electric steering system 34 can assist the driver to easily operate the steering wheel 34a by the driver. For example, the electric power steering apparatus 34 may assist the user in steering operations such as reducing the steering force at low-speed driving or parking, and increasing the steering force at high-speed driving.

The audio device 35 can provide various information and entertainment to the driver through the sound. For example, the audio device 35 may reproduce an audio file stored in an internal storage medium or an external storage medium according to a command from the driver, and output sound included in the reproduced audio file. In addition, the audio device 35 may receive an audio broadcast signal and output a sound corresponding to the received audio broadcast signal.

The air conditioner 36 can introduce air outside the vehicle 1 into the interior of the vehicle 1 or circulate air inside the vehicle 1. [ Further, the air conditioning apparatus 36 can heat or cool the indoor air according to the indoor temperature of the vehicle 1. [

The battery B can store electric energy generated from the rotational force of the engine and supply electric power to various electric components 30 included in the vehicle 1. [ For example, during running of the vehicle 1, the generator can convert the rotational energy of the engine into electrical energy, and the battery B can receive and store electrical energy from the generator. In addition, during parking of the vehicle 1, it is possible to supply the starting motor with electric power for starting the engine or to supply the electric parts 30 of the vehicle 1 with electric power.

The battery sensor 37 can acquire various information related to the battery B. [ For example, the battery sensor 37 detects the rated capacity of the battery B, the state of charge (SoC) of the battery B, the remaining life of the battery B (State of Health, SoH) The output voltage V of the battery B, the output current I of the battery B, the temperature t of the battery B, and the like.

The vehicle body control module 100 can control the operation of electrical parts that provide convenience to the driver or ensure the safety of the driver. For example, the vehicle body control module 100 includes an auxiliary heater 41, a seat heater 42, a headrest heater 43, an armrest heater 44, a steering wheel heater 45, The rear window heater 46, the side mirror heat 47, and the like.

The auxiliary heater (41) can assist the air conditioning system (36) during heating by the air conditioning system (36). At the time of heating, the air conditioning system (36) uses the heat of cooling water to heat indoor air of the vehicle (1). At this time, the auxiliary heater 41 can heat the indoor air of the vehicle 1 before the cooling water is sufficiently heated.

The seat heater 42 may be provided on the body of the driver's seat seat S1 and the seat back S2 and on the backrest and may be mounted on the body of the seat S1 and the seat S2 according to the operation of the driver and the temperature of the seat S1, The backrest can be heated. Further, the headrest heater 43 can be provided on the headrest of the sheets S1 and S2, and can also heat the headrest according to the operation of the driver and the temperature of the headrest.

The armrest heater 44 may be provided on the armrest A between the driver's seat sheet S1 and the assistant seat S2 so that the armrest A can be moved in accordance with the operation of the driver and the temperature of the armrest A. It can be heated. The steering wheel heater 45 may be provided on the steering wheel 34a and may heat the steering wheel 34a according to the operation of the driver and the temperature of the steering wheel 34a.

The rear window heater 46 may be provided on the rear window 19 and may heat the rear window 19 to remove moisture or gasses generated in the rear window 19. [ The side mirror heater 47 may be provided on the side mirror 14a and may heat the side mirror 14a to remove the moisture or gasses generated in the side mirror 14a.

These electrical components 30 can communicate with each other through a vehicle communication network (CNT). For example, the engine management system 31, the transmission control unit 32, the electronic braking system 33, the electric steering system 34, the audio device 35, the air conditioner 36, the battery sensor 37, The vehicle body control module 100 can send and receive data via the vehicle communication network CNT. The vehicle body control module 100, the auxiliary heater 41, the seat heater 42, the headrest heater 43, the armrest heater 44, the steering wheel heater 45, the rear window heater 46, The mirror hit 47 can also send and receive data via the vehicle communication network (CNT).

The Car Communication Network (CNT) has a communication protocol such as Ethernet, MOST (Media Oriented Systems Transport), Flexray, CAN (Controller Area Network), LIN (Local Interconnect Network) Can be adopted. Further, the vehicular communication network NT can employ not only a single communication protocol such as a modem, flex-ray, can, and lean but also a plurality of communication protocols. However, in the following description, it is assumed that the vehicle communication network (CNT) uses the CAN communication protocol to facilitate understanding.

In addition, the electrical components 30 can receive power from the battery B via the vehicle power network PNT. As described above, the battery B can supply electric power to the electric components 30 during driving of the vehicle 1 or during parking.

The supply of electric power to the electric components 30 by the battery B will be described in more detail below.

4 shows a power system of a vehicle according to one embodiment.

4, the power system of the vehicle may include a starter motor M, an engine E, a generator G, a battery B, and electrical components 30.

The starter motor M can provide rotational force to the engine E to start the engine E while the engine E is stopped. The starter motor M can receive power from the battery B and the starter motor M can consume a very large amount of electric power to start the engine E. [ Therefore, the battery B maintains a certain amount of electric power (for example, a charging ratio of about 80% or more) for a predetermined level or more for the operation of the starter motor M.

The engine E generates power for moving the vehicle 1. [ Specifically, the engine E can generate rotational force using the explosive combustion of the fuel, and the rotational force of the engine E can be transmitted to the wheel 20 via the transmission. The vehicle 1 can be moved by the rotation of the wheel 20. In addition, some of the rotational force generated by the engine E may be provided to the generator G. [

The generator G is provided with rotational force from the engine E and can produce electric energy or electric power from the rotational force of the engine E. The generator G can regulate the amount of power generation according to the running state of the vehicle 1 and the charge ratio SoC of the battery B. [ For example, the generator G may have the form of a motor in which both the rotor and the stator include a coil, the rotor may be rotated by the rotational force of the engine E, and the stator may be fixed so as not to be rotatable. When a current is supplied to the coil of the rotor while the rotor is rotating, a rotating magnetic field is generated, and an electromotive force is generated in the coil of the stator due to the rotating magnetic field. By using this, the generator (G) can produce electric power. Also, the magnitude of the magnetic field changes according to the magnitude of the current supplied to the coil of the rotor, and the electromotive force generated in the coil of the stator may also vary. By using this, the generator (G) can regulate the production of electric power.

A part of the electric power produced by the generator G may be supplied to the electric component parts 30 of the vehicle 1 and the other part may be stored in the battery B of the vehicle 1. [ In other words, the electric power produced by the generator G is supplied to the electric field components 30, and the remaining electric power can be stored in the battery B.

The battery B receives power from the generator G and can store the supplied power in the form of chemical energy. The battery B can also supply electric power for starting the engine E to the starter motor M when the engine E is stopped.

The battery B may not only receive power from the generator G but also supply electric power to the electric components 30. [ For example, the battery B can supply electric power to the electric components 30 because the generator G can not generate electric power during the parked state of the engine E. Further, when the electric power consumed by the electric component parts 30 is larger than the electric power produced by the generator G, the battery B can supply electric power to the electric component parts 30.

As such, the generator G and the battery B can supply electric power to the electric components 30 in a mutually complementary manner. The electric components 30 receive power from the generator G or the battery B and can control the configuration of the vehicle 1, protect the driver, or provide the driver with fun and convenience.

In particular, the vehicle body control module 100 can control various electric components that protect the driver or provide the driver with fun and convenience. Furthermore, the vehicle body control module 100 can control the electric power consumed by various electric components in order to maintain the charged amount of the battery B in which the starter motor M can operate.

Hereinafter, the configuration of the vehicle body control module 100 will be described.

5 shows a configuration of a vehicle body control module included in a vehicle according to an embodiment.

5, the vehicle body control module 100 may include a communication unit 120, a storage unit 130, and a control unit 110. As shown in FIG.

The communication unit 120 may include a CAN transceiver 121 that receives a communication signal from the electrical components 30 through the vehicle communication network CNT and transmits a communication signal to the electrical components 30 have. The CAN transceiver 121 receives an analog communication signal from the vehicle communication network CNT, converts the analog communication signal into digital communication data, and outputs the digital communication data to the control unit 110. [ The can transceiver 121 receives the digital communication data from the control unit 110, converts the digital communication data into an analog communication signal, and transmits the analog communication signal to the vehicle communication network CNT.

In this way, the communication unit 120 can exchange data with the electric components 30 of the vehicle 1 via the vehicle communication network CNT, and the vehicle body control module 100 can communicate with the vehicle 1 To the electrical components 30 of the vehicle.

The storage unit 130 may include a secondary memory 131 for storing a control program for controlling the vehicle body control module 100 and control data. The secondary memory 131 may include a nonvolatile memory in which stored data is not lost even if power supply is interrupted. The secondary memory 131 may store data or delete stored data according to a control signal of the controller 130. The secondary memory 131 may include a hard disk drive (HDD) or a solid state drive (SSD).

The control unit 110 includes a primary memory 112 for storing a control program and control data for controlling the vehicle body control module 100 and a control unit 110 for generating a control signal according to control programs and control data stored in the primary memory 112 And a processor 111 for processing the data.

The primary memory 112 may temporarily store the communication data received through the communication unit 120 or may temporarily store the control program and control data stored in the storage unit 130. [ The primary memory 112 may also provide programs and / or data to the processor 111 in accordance with the control signals of the processor 111. [

The primary memory 112 may include a volatile memory such as a static random access memory (S-RAM) or a dynamic random access memory (D-RAM). The primary memory 112 may further include a ROM for storing programs for booting or power on reset of the vehicle body control module 100, an Erasable Programmable Read Only Memory (EPROM) ), And a non-volatile memory such as an EEPROM (Electrically Erasable Programmable Read Only Memory).

The processor 111 may include various logic circuits and arithmetic circuits and may process data according to a program provided from the memory 112 and generate control signals according to the processing results. For example, the processor 111 processes the data relating to the generator G, the data relating to the battery B and the data relating to the operation of the electrical components 30, and the power consumption of the electrical components 30 It is possible to generate a control signal for controlling.

The control unit 110 collects data on the vehicle 1 through the communication unit 120 and processes the data according to the program stored in the storage unit 130 to control the power consumption of the electric components 30 Can be generated.

Specifically, the control unit 110 calculates the utilization rate of electric power available to the electric components 30 from the data on the generator G, the data on the battery B, and the data on the operation of the electric components 30 And generate a control signal for controlling the power consumption of the electrical components 30 according to the calculated power availability ratio.

At this time, the amount of electric power that the electric component 30 can supply at present is referred to as the electric power availability, and the controller 110 can calculate the electric power availability using the following formula (1).

[Equation 1]

Here, the amount of electric power available means the amount of electric power currently available to the electric component 30, the amount of electric power generated means the amount of electric power currently generated by the generator G, and the amount of electric charge means the amount of electric power currently stored in the battery B , And the amount of consumption means the amount of power currently consumed by the electric power components 30.

As such, the amount of power available can be calculated from the power generation amount, the charging amount and the consumption amount. At this time, the power generation amount is calculated from the rotation speed of the generator G, the temperature and the voltage of the generator G, and the charging amount can be calculated from the charging ratio of the battery B. Further, the consumption amount can be calculated from the operation information of the electric component parts 30 or the output current of the battery B.

Also, the maximum amount of electricity that can be supplied to the electric component parts 30 is referred to as a maximum usable amount, and the controller 110 can calculate the maximum usable amount using the following equation (2).

&Quot; (2) "

Here, the maximum usable amount means the maximum amount of electric power that the electric component 30 can use, and the amount of generated electricity means the amount of power that the generator G can produce to the maximum, And the consumption amount refers to an amount of power that the electric power components 30 basically consume.

Thus, the maximum usable capacity can be calculated from the maximum power generation amount, the maximum charge amount, and the basic consumption amount. At this time, the maximum power generation amount, the maximum charge amount and the basic consumption amount can be obtained in advance through experiments.

The ratio of the amount of power that can be supplied by the electrical component parts 30 to the maximum amount of electric power that can be supplied to the electric component parts 30, that is, the ratio of the maximum usable capacity to the electric power usable capacity, The control unit 110 can calculate the power availability using the following equation (3).

Here, the power availability factor means a ratio of the amount of power that the electrical component parts 30 can currently receive to the amount of electrical power that the electrical component parts 30 can receive at the maximum, Means the amount of power currently available, and the maximum usable amount may mean the maximum amount of electric power that the electric component 30 can use.

As described above, the power availability factor is a ratio of the current power G supplied by the generator G to the maximum electric power that the battery B can supply to the electric component 30, and the current electric power G supplied by the battery B to the electric component 30 And can be used as an index indicating the power supply state of the vehicle 1. [ In other words, if the power availability rate is high, the control unit 110 can determine that the vehicle 1 is in a good power supply state. If the power availability rate is low, the control unit 110 determines that the power supply state of the vehicle 1 is poor It can be judged.

Hereinafter, the operation of the vehicle 1, particularly the operation of the body control module 100, will be described.

6 shows an example of a method for limiting power consumption of a vehicle according to an embodiment. Fig. 7 also shows an example of the operation of electrical components according to the power consumption limiting method shown in Fig.

6 and 7, a method 1000 for limiting power consumption of the vehicle 1 is described.

The vehicle 1 calculates a power availability rate of the electric components 30 (1010).

The vehicle body control module 100 of the vehicle 1 determines whether the electric components 30 can be used from the data on the generator G, the data on the battery B and the data on the operation of the electric components 30 The available rate of power can be calculated.

Specifically, the vehicle body control module 100 calculates the electric power availability from the electric power generation amount of the generator G, the electric energy amount of the battery B and the electric power consumption amount of the electric parts 30 by using the formula (1) The maximum usable amount can be calculated from the maximum power generation amount of the generator G, the maximum power amount of the battery B, and the maximum power consumption of the electric components 30 using the equation (2). Also, the vehicle body control module 100 can calculate the electric power availability from the electric power availability and the maximum electric energy using (Equation 3).

Thereafter, the vehicle 1 determines whether the power availability rate is smaller than a predetermined first reference level (1020).

The vehicle body control module 100 of the vehicle 1 compares the power availability rate with the first reference availability rate and determines whether the power availability rate is smaller than the first reference availability rate. The first reference availability rate may indicate the availability rate at which the power consumption limiting operation of the electric component parts 30 is started. For example, as shown in FIG. 7, if the operation of electrical components (auxiliary heater according to FIG. 7) is restricted when the power availability is 80%, the first power availability rate can be defined as 80%.

If the power availability rate is not smaller than the first reference availability rate (NO in 1020), the vehicle 1 repeats the calculation of the power availability rate.

If the power availability rate is smaller than the first reference availability rate (YES in 1020), the vehicle 1 limits the power consumption of the electric components 30 according to the calculated power availability rate (1030).

If the power availability rate is smaller than the first reference usage rate, it can be determined that the power supply state of the vehicle 1 is poor. In other words, if the power availability rate is smaller than the first reference usage rate, it can be determined that the amount of charge of the battery B is reduced due to a large amount of electric power consumption of the electric components 30 than the electric power generated by the generator G. Further, if the amount of charge of the battery B is continuously reduced, there is a possibility that the start of the engine E may fail due to a shortage of the amount of the battery B charged when the engine E is restarted.

Therefore, the vehicle 1 can perform the power consumption limitation operation for reducing the power consumption of the electric components 30. Specifically, the vehicle body control module 100 of the vehicle 1 can perform the power consumption restricting operation for reducing the power consumption of the electric components 30 step by step according to the electric power availability rate. In other words, the vehicle body control module 100 can perform the power consumption limitation operation of the electric components 30 if the power availability rate becomes smaller than the individual reference use rate of the electric components 30.

For example, if the power availability rate is less than 80%, the vehicle body control module 100 may delay the turn-on time of the electric component 30 to the power saving first step. Specifically, the vehicle body control module 100 may delay the turn-on time of the electrical components 30 that are periodically turned on / off.

The vehicle body control module 100 includes an auxiliary heater 41, a seat heater 42, a headrest heater 43, an armrest heater 44, a steering wheel heater 45, a rear window heater 46 ), The side mirror heat 47 can be operated for the on-time, and the operation can be stopped for the off-time.

At this time, if the power availability is less than 80%, the vehicle body control module 100 controls the auxiliary heater 41, the seat heater 42, the headrest heater 43, the armrest heater 44, The steering wheel heater 45, the rear window heater 46, and the side mirror heater 47 can be delayed.

For example, as shown in FIG. 7, the body control module 100 may delay the turn-on time of the auxiliary heater 41 by approximately 5 to 10 seconds if the power availability rate is less than 80% The turn-on time of the rear window heater 46 can be delayed by approximately 10 to 20 seconds. The vehicle body control module 100 may delay the turn-on time of the seat heater 42 by approximately 30 to 60 seconds if the power availability rate is less than 76%, and may delay the turn-on time of the armrest heater 44 when the power availability rate is less than 74% The turn-on time can be delayed by about 10 to 20 seconds.

In addition, if the power availability rate is smaller than 70%, the vehicle body control module 100 can operate the electric component parts 30 with low power in the second power saving mode. Specifically, the vehicle body control module 100 can reduce the power supplied to the electric component parts 30 or consumed by the electric component parts 30. For example, the vehicle body control module 100 can reduce the current supplied to the electric components 30 or reduce the on time (running time) of the electric components 30.

Specifically, the vehicle body control module 100 reduces the output of the armrest heater 44 by about 50% when the power availability rate becomes smaller than 70%, and decreases the output of the seat heater 41 by about 50% Can be reduced by 50%. In addition, the vehicle body control module 100 reduces the output of the steering wheel heater 45 by about 50% when the power availability rate becomes smaller than 56%, and decreases the output of the headrest heater 43 by about 50% Can be reduced by 50%.

If the power availability rate is less than 50%, the vehicle body control module 100 can block the operation of the electric components 30 in the third power saving mode.

For example, the vehicle body control module 100 stops the operation of the side mirror heater 47 when the power availability rate becomes smaller than 50%, and stops the operation of the steering wheel heater 45 when the power availability rate becomes smaller than 48% . In addition, the body control module 100 can stop the operation of the armrest heater 44 if the power availability rate is less than 44%, and stop the operation of the seat heater 42 if the power availability rate is less than 40%. The vehicle body control module 100 stops the operation of the auxiliary heater 41 when the power availability rate is less than 38% and stops the operation of the rear window heater 46 when the power availability rate is less than 36% Is less than 22%, the operation of the headrest heater 43 can be stopped.

As described above, the vehicle 1 can gradually limit the operation of the electric components 30 according to the power availability. For example, the vehicle 1 may delay the turn-on time of the electric components 30, reduce the running time of the electric components 30, or operate the electric components 30 depending on the electric power availability rate Can be stopped.

In this way, the vehicle 1 can prevent the charge amount of the battery B from rapidly decreasing by stepwise limiting the operation of the electric component parts 30. [

In addition, the stepwise limitation of the operation of these electric component parts 30 may sacrifice the driver's convenience. In other words, since the operation of the electric component parts 30 is stepwise restricted, the driver may be inconvenienced.

Particularly, when the charged amount of the battery B can not sufficiently increase due to the driving habit or the traveling pattern of the driver, the operation of the electric components 30 may be continuously restricted, and the driver may be continuously inconvenienced . The operation of the electric components 30 can be continuously restricted due to insufficient charging of the battery B, for example, when the running distance of the vehicle 1 is short or when the vehicle 1 is parked for a long time And the driver may be constantly disturbed.

In this way, when the operation of the electrical components 30 is continuously restricted, the vehicle 1 temporarily reduces the power consumption of the electrical components 30 to a minimum to increase the power availability, ) Can be minimized. For example, the vehicle 1 may increase the individual reference availability rate at which the operation of the electrical components 30 is limited to increase the power availability.

Hereinafter, a method for temporarily decreasing the power consumption of the electrical components 30 by the vehicle 1 in order to increase the power availability rate will be described.

FIG. 8 shows an example of a method for improving the power availability of a vehicle according to an embodiment. Fig. 9 shows an example of the operation of electrical components by the power availability improvement method shown in Fig.

8 and 9, a method 1200 for improving the power availability of the vehicle 1 is described.

The vehicle 1 calculates 1210 the ratio of the time limit of the operation restriction to the number of times of operation restriction due to the drop in the power availability rate.

The vehicle body control module 100 of the vehicle 1 can calculate the time ratio of the operation restriction of the electric components 30 from the time when the running time of the vehicle 1 and the operation of the electric components 30 are restricted.

As described above, when the power availability rate becomes smaller than the first reference usage rate, the vehicle 1 can partially limit the operation of the electric components 30 to increase the charge amount of the battery B. [ The vehicle body control module 100 determines whether or not the operation of the electric components 30 with respect to the entire running time of the vehicle 1 is limited by using Equation 4 so as to obtain a limited degree of operation of the electric component 30 The ratio of time can be calculated.

&Quot; (4) "

At this time, the traveling time of the vehicle 1 may be the time at which the engine E is started, and the operation limit time may be a time at which the operation of the electric components 30 is limited due to the decrease of the electric power availability rate.

The vehicle body control module 100 can calculate the ratio of the number of times of operation restriction of the electric components 30 from the number of times of running of the vehicle 1 and the limited number of operations of the electric components 30. The vehicle body control module 100 determines whether or not the operation of the electric components 30 with respect to the total number of travels of the vehicle 1 is limited by using Equation 5 so as to obtain a limited degree of operation of the electric component 30 The ratio of the number of times can be calculated.

&Quot; (5) "

At this time, the running frequency of the vehicle 1 may be the number of times the engine E is started, and the operation limit time may be the number of times that the operation of the electric components 30 is limited due to the decrease of the power availability.

Then, the vehicle 1 determines whether the power limit time ratio is greater than the first reference value (1220).

The vehicle body control module 100 of the vehicle 1 compares the power limit time ratio and the first reference value and can determine whether the power limit time ratio is larger than the first reference value. The first reference value may represent a criterion for starting the restriction of the electric power consumption of the electric components 30 for improving the electric power availability rate and may include a limit value for limiting the operation limit of the electric components 30 Lt; / RTI > The first reference value may be stored in advance by the designer of the vehicle 1 or may be set by the driver. For example, the first reference value may be set to 50%.

If the power limit time ratio is not greater than the first reference value (No at 1220), the vehicle 1 determines whether the ratio of the power limit times is greater than the second reference value (1230).

The vehicle body control module 100 of the vehicle 1 compares the ratio of the number of times of power limitation with the second reference value and determines whether the ratio of the number of times of power limitation is larger than the second reference value. The second reference value may indicate a criterion at which the operation minimization of the electric component 30 is started to improve the electric power availability rate and may indicate an operation restriction rate at which the driver starts to feel discomfort due to the operation restriction of the electric component 30 . This second reference value may be stored in advance by the designer of the vehicle 1 or set by the driver. For example, the second reference value may be set to 50%.

If the power limit time ratio is not greater than the first reference value (NO in 1220) and the number of power limit times is not greater than the second reference value (NO in 1230), the vehicle 1 determines whether the ratio of the time limit of operation limit to the number of times of operation limit Repeat the calculation.

If the power limit time ratio is greater than the first reference value (e.g., 1220) and the number of power limit times is greater than the second reference value (e.g., 1230), the vehicle 1 temporarily minimizes the operation of electrical components 30 (1240).

The vehicle control module 100 temporarily minimizes the operation of the electric components 30 in order to temporarily increase the power operation rate when the operation restriction of the electric component 30 is frequently / can do.

As described above, when the power availability rate is lower than the first power availability rate, the vehicle body control module 100 starts to limit the operation of the electric components 30, and the power consumption rate and the individual reference usage rate Thereby restricting the operation of each of the electric component parts 30 in accordance with the operation of the electric component parts 30. [ For example, when the power availability factor is less than 80%, the vehicle body control module 100 starts to limit the operation of the electric component parts 30, delays the turn-on time of the electric component parts 30 in the first power saving mode, If the power availability factor is less than 70%, the electric components 30 are operated with low power in the power saving two steps, and if the power availability is less than 50%, the electric components 30 can be shut off in the power saving three stages.

The body control module 100 sets the first reference availability rate (for example, 80%) to a second reference availability rate (for example, 90%) at which the operation restriction of the electric component 30 starts to increase the power availability rate, To increase the individual reference availability rate at which the operation of the electrical components 30 is limited.

Specifically, as shown in FIG. 9, when the first power operation rate and the first available power saving rate are increased to 90%, and the power availability is less than 90%, the body control module 100 determines the turn-on time Can be delayed. The vehicle body control module 100 can increase the availability level of the power saving second stage to 80% and operate the electric components 30 at a low power level if the power availability rate is less than 80%. In addition, the vehicle body control module 100 can increase the availability level of the power saving third stage to 60% and shut off the operation of the electric components 30 if the power availability is less than 60%.

For example, as shown in FIG. 9, the vehicle body control module 100 may delay the turn-on time of the auxiliary heater 41 by about 5 to 10 seconds if the power availability rate is less than 90% The turn-on time of the rear window heater 46 can be delayed by approximately 10 to 20 seconds. The body control module 100 may delay the turn-on time of the seat heater 42 by about 30 to 60 seconds if the power availability rate is less than 86% and turn on the turn-on time of the armrest heater 44 if the power availability rate is less than 84% For about 10 seconds to 20 seconds.

The body control module 100 reduces the output of the armrest heater 44 by about 50% when the power availability rate becomes smaller than 80%, and decreases the output of the seat heater 41 by about 50% when the power availability rate becomes smaller than 78% %. The vehicle body control module 100 reduces the output of the steering wheel heater 45 by about 50% when the power availability rate becomes smaller than 66%, and outputs the output of the headrest heater 43 by about 50% when the power availability rate becomes smaller than 65% Can be reduced by 50%.

In addition, the body control module 100 can stop the operation of the side mirror heater 47 when the power availability rate is less than 60%, and stop the operation of the steering wheel heater 45 when the power availability rate is less than 58% . In addition, the body control module 100 can stop the operation of the armrest heater 44 when the power availability rate is less than 54%, and can stop the operation of the seat heater 42 if the power availability rate is less than 50%. The vehicle body control module 100 stops the operation of the auxiliary heater 41 when the power availability rate becomes smaller than 48% and stops the operation of the rear window heater 46 when the power availability rate becomes smaller than 46% Is less than 32%, the operation of the headrest heater 43 can be stopped.

As described above, by increasing the individual reference availability rate at which the operation of the electric component 30 is limited, the vehicle control module 100 can reduce the power consumption of the electric component 30. For example, when the electric power availability rate is 72%, the turn-on of the protective heater 41, the rear window heater 46, the seat heater 42, and the armrest heater 44 is started before the electric components 30 are minimized The turn-on of the protective heater 41 and the rear window heater 46 is delayed and the seat heater 42 and the armrest heater 44 can be reduced to low power after the electric components 30 are minimized in operation . As a result, after the electric components 30 are minimized in operation, the electric power consumption of the electric components 30 decreases and the amount of the charged electricity of the battery B increases, compared to before the operation is minimized. In other words, the availability of power can increase.

In addition, the vehicle body control module 100 can block the operation of electrical components previously selected by the driver to increase the power availability. For example, when the driver sets the interruption of the headrest heater 43 and the armrest heater 44 in advance, the vehicle body control module 100 controls the headrest heater 43 and the armrest 44 in order to increase the power availability, The operation of the heater 44 can be cut off.

Then, the vehicle 1 calculates 1250 the power availability rate of the electric components 30 of the vehicle 1.

The vehicle body control module 100 of the vehicle 1 determines whether the electric components 30 can be used from the data on the generator G, the data on the battery B and the data on the operation of the electric components 30 The available rate of power can be calculated.

Specifically, the vehicle body control module 100 calculates the electric power availability from the electric power generation amount of the generator G, the electric energy amount of the battery B and the electric power consumption amount of the electric parts 30 by using the formula (1) The maximum usable amount can be calculated from the maximum power generation amount of the generator G, the maximum power amount of the battery B, and the maximum power consumption of the electric components 30 using the equation (2). Also, the vehicle body control module 100 can calculate the electric power availability from the electric power availability and the maximum electric energy using (Equation 3).

Then, the vehicle 1 determines whether the power availability rate is greater than a predetermined third reference rate (step 1260).

The vehicle body control module 100 of the vehicle 1 compares the power availability rate with the third reference availability rate and determines whether the power availability rate is larger than the third reference availability rate. The third reference availability rate may be a value that is larger than the first reference availability rate and may be defined as being able to maintain the power availability rate higher than the first reference usage rate for at least a certain period of time even if the individual reference usage rate of the electric component 30 is restored . For example, the third criterion availability rate can be defined as 95%.

If the power availability rate is not greater than the predetermined third reference availability rate (NO in 1260), the vehicle 1 repeats the calculation of the power availability rate.

If the power availability rate is greater than a predetermined third criterion availability rate (example of 1260), the vehicle 1 terminates the operation minimization of the electrical components 30 (1270).

The vehicle body control module 100 may terminate the operation minimization of the electric component 30 in order to minimize the inconvenience of the driver because the amount of charge of the battery B is sufficient if the electric power availability rate is larger than the predetermined third standard usage rate.

The vehicle body control module 100 can restore the first power operation rate at which the operation restriction of the electric component 30 starts and the individual reference availability rate at which the operation of the electric component 30 is restricted. Specifically, the vehicle body control module 100 restores the first power utilization rate and the first-step avail- able availability rate to 80%, restores the avail- able availability level of the second-stage power saving to 70%, and restores the avail- able availability rate of the third- .

In the above description, the vehicle 1 terminates the minimization of the operation of the electrical components 30 if the power availability is higher than the predetermined third reference utilization rate, but is not limited thereto. For example, when the predetermined reference time elapses after minimizing the operation of the electric components 30, the vehicle 1 may terminate the operation minimization of the electric components 30.

As described above, when the operation of the electrical components 30 is frequently restricted by the power availability factor, the vehicle 1 can temporarily minimize the operation of the electrical components 30 to secure a power availability rate . As a result, the operation of the electric component parts 30 can be prevented from being continuously restricted.

Meanwhile, the disclosed embodiments may be embodied in the form of a recording medium storing instructions executable by a computer. The instructions may be stored in the form of program code and, when executed by a processor, may generate a program module to perform the operations of the disclosed embodiments. The recording medium may be embodied as a computer-readable recording medium.

The computer-readable recording medium includes all kinds of recording media in which instructions that can be decoded by a computer are stored. For example, it may be a ROM (Read Only Memory), a RAM (Random Access Memory), a magnetic tape, a magnetic disk, a flash memory, an optical data storage device, or the like.

The embodiments disclosed with reference to the accompanying drawings have been described above. It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the following claims. The disclosed embodiments are illustrative and should not be construed as limiting.

1: vehicle 100: Body control module

Claims (20)

A power generator;
A plurality of electric components supplied with power from the generator;
A battery for storing a part of electric power produced by the generator;
Calculating a power availability rate from a power generation amount of the generator, a charge amount of the battery, and a power consumption amount of the plurality of electric components, and if the power availability rate is smaller than a predetermined first reference utilization rate, And a body control module,
When the ratio of the operation restriction time of the plurality of electric components to the running time of the vehicle is larger than a predetermined first reference value, the vehicle body control module determines that the power availability is lower than the second reference availability rate And limits the operation of the plurality of electric component parts in a stepwise manner. The method according to claim 1,
When the ratio of the operation limit time is not larger than the first reference value and the ratio of the number of operation limit times of the plurality of electric component parts to the number of times of driving the vehicle is larger than a predetermined second reference value, Is smaller than the second criterion availability rate, the operation of the plurality of electric component parts is restricted stepwise. The method according to claim 1,
Wherein the vehicle body control module limits the operation of the plurality of electric component parts in a stepwise manner when the power availability factor is smaller than the first reference value, when the power availability factor is larger than the third reference value. The method according to claim 1,
Wherein when the ratio of the operation limit time is greater than the first reference value, the vehicle body control module blocks the operation of the electric component previously selected by the driver. The method according to claim 1,
Wherein the vehicle body control module gradually delays the turn-on time of the plurality of electric component parts when the power availability rate is smaller than the first reference allowable amount. 6. The method of claim 5,
Wherein when the ratio of the operation limit time is larger than the first reference value, the vehicle body control module delays the turn-on time of the plurality of electric components on a step-by-step basis if the power availability rate is smaller than the second reference value. The method according to claim 1,
Wherein the vehicle body control module gradually reduces the output of the plurality of electrical components when the power availability rate is smaller than the first reference occupancy rate. 8. The method of claim 7,
Wherein when the ratio of the operation limit time is larger than the first reference value, the vehicle body control module gradually reduces the output of the plurality of electric component parts when the power availability rate is smaller than the second reference usage rate. The method according to claim 1,
Wherein the vehicle body control module steps the operation of the plurality of electric components in a stepwise manner if the power availability ratio is smaller than the first reference occupancy rate. 10. The method of claim 9,
Wherein when the ratio of the operation limit time is larger than the first reference value, the vehicle body control module steps the operation of the plurality of electric component parts stepwise if the power availability ratio is smaller than the second reference use rate. Calculating a power availability rate from a power generation amount of the generator, a charged amount of the battery, and a power consumption amount of a plurality of electric parts;
Limiting the operation of the plurality of electric component parts in a stepwise manner if the power availability factor is smaller than a predetermined first reference service factor;
When the ratio of the operation limit time of the plurality of electric components to the running time of the vehicle is larger than a predetermined first reference value and the power availability is smaller than the second reference usability rate which is larger than the first reference usability, And limiting the operation of the vehicle in a stepwise manner. 12. The method of claim 11,
When the ratio of the operation limit time is not larger than the first reference value and the ratio of the number of operation limit times of the plurality of electric component parts to the number of driving times of the vehicle is larger than a predetermined second reference value, And limiting the operation of the plurality of electric component parts in a stepwise manner if the availability factor is lower than the availability factor. 12. The method of claim 11,
Further comprising the step of limiting the operation of the plurality of electric component parts in a stepwise fashion if the power availability percentage is larger than a third reference percentage rate which is larger than the second reference value, Control method. 12. The method of claim 11,
Wherein the step of limiting the operation of the plurality of electric component parts step-
And stopping the operation of the electric parts previously selected by the driver. 12. The method of claim 11,
Wherein the step of limiting the operation of the plurality of electric component parts in a stepwise manner if the power availability factor is smaller than the first reference use rate,
And delaying the turn-on time of the plurality of electric component parts in a stepwise manner if the power availability factor is smaller than the first reference allowable component amount. 16. The method of claim 15,
Wherein the step of limiting the operation of the plurality of electric component parts in a stepwise manner if the power availability factor is smaller than the second reference use rate,
And delaying the turn-on time of the plurality of electric component parts in a stepwise manner if the power availability factor is smaller than the second reference use rate. 12. The method of claim 11,
Wherein the step of limiting the operation of the plurality of electric component parts in a stepwise manner if the power availability factor is smaller than the first reference use rate,
And gradually reducing the output of the plurality of electrical components when the power availability is lower than the first reference occupancy rate. 18. The method of claim 17,
Wherein the step of limiting the operation of the plurality of electric component parts in a stepwise manner if the power availability factor is smaller than the second reference use rate,
And gradually reducing the output of the plurality of electrical components when the power availability is lower than the second reference occupancy rate. 12. The method of claim 11,
Wherein the step of limiting the operation of the plurality of electric component parts in a stepwise manner if the power availability factor is smaller than the first reference use rate,
And blocking the operation of the plurality of electrical components step by step if the power availability factor is smaller than the first reference occupancy rate. 20. The method of claim 19,
Wherein the step of limiting the operation of the plurality of electric component parts in a stepwise manner if the power availability factor is smaller than the second reference use rate,
And blocking the operation of the plurality of electrical components step by step if the power availability factor is less than the second criterion availability rate.

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