The present invention claims priority under 35 U.S.C. § 119 to Japanese Application No. 2022-058489 filed on Mar. 31, 2022, and Japanese Application No., 2023-025024, filed on Feb. 21, 2023, the entire contents of which being incorporated herein by reference.
The present disclosure relates to an electric work vehicle equipped with a travelling device and a working device.
Conventionally, work vehicles equipped with a working device are known. For example, a lawn mowing vehicle equipped with a lawn mower as a working device which is driven to perform lawn mowing work is conventionally known.
Further, such work vehicles can also be electric work vehicles equipped with a travel motor, which is an electric motor that drives a travelling device such as wheels, and a work motor, which is an electric motor that drives a working device.
For example, in Japanese Patent No. 6121213, there is described an electric work vehicle in which left and right travel motors, which are electric motors, drive wheels on the corresponding sides and a blade motor (work motor) drives a rotary blade of a lawn mowing unit (working device).
Furthermore, in the vehicle described in Patent No. 6121213, a temperature sensor detects the temperature of the blade motor, and, in a case where the temperature detected by the temperature sensor is higher than a threshold, an exception speed control section drives the travel motor so that the vehicle travels at an exception speed which is slower than the target travel speed that is determined by left and right control levers. Accordingly, protection of the blade motor is expected to be achieved.
Incidentally, regarding electric work vehicles equipped with at least one motor that drives one or both of a travelling device and working device, a high load on a battery that supplies power to the motor may cause a decrease in life of the battery. Further, if the upper limit of the power supplied to the motor is always kept sufficiently low to protect the battery, work efficiency may decrease. Accordingly, it is desirable to achieve both protection of the battery and improvement of work efficiency.
Further, in a case of controlling traveling of a vehicle equipped with a travel motor that drives a travelling device and a work motor that drives a working device, the discharge current from the battery may rise excessively if the traveling is controlled according to torque generated by each motor. If the discharge current of the battery exceeds the allowable upper limit value, a process of cutting off the current flowing from the battery to each motor, etc., is performed in order to protect the battery. The vehicle therefor stops abruptly, and thus the efficiency of work with the working device greatly decreases.
The purpose of the present disclosure is to achieve both protection of a battery and improvement of work efficiency in an electric work vehicle.
A first electric work vehicle according to the present disclosure includes: at least one motor configured to drive one or both of a travelling device and a working device included in the vehicle; an operation section configured to direct a rotational speed or actuation of the motor; a control section configured to control the motor according to an operation of the operation section; and a battery configured to supply power to the motor, wherein the control section decreases an upper limit of rotational speed of the motor, based on a detected result with regard to a battery condition including a voltage of the battery.
A second electric work vehicle according to the present disclosure includes: at least one motor configured to drive one or both of a travelling device and a working device included in the vehicle; an operation section configured to direct torque or actuation of the motor; a control section configured to control the motor according to an operation of the operation section; and a battery configured to supply power to the motor, wherein the control section decreases an upper limit of torque of the motor, based on a detected result with regard to a battery condition including a voltage of the battery.
A third electric work vehicle according to the present disclosure includes: a travel motor configured to drive at least one travelling device; a work motor configured to drive at least one working device; a battery configured to supply power to the travel motor and the work motor, the battery having a specified maximum discharge current; and a control section configured to control the travel motor and the work motor, wherein the control section controls a rotational speed of the travel motor so that a discharge current of the battery does not exceed the maximum discharge current during driving of the work motor.
Hereinafter, a detailed explanation is given of an embodiment of the present disclosure with reference to the drawings. Although the following description explains the case in which the electric work vehicle is a lawn mowing vehicle, the electric work vehicle is not limited to a lawn mowing vehicle and may be any other work vehicle equipped with a working device that performs one or more of snow removal work, excavation work, civil engineering work, and agricultural work. Further, although the following description explains the case of using left and right lever-type operators equipped with left and right operation levers, this is merely an example, and it is also possible that a steering wheel is used as a steering controller and that an accelerator pedal installed in the front of a seat is used as an acceleration controller. Although the following description explains the electric work vehicle as being equipped with wheels as a travelling device driven by a travel motor and as traveling by driving of the wheels, it is also possible that the travelling device is a crawler or the like. The shapes, number of parts, arrangement relationships of components, etc., explained in the following description are examples for explanation and thus may be changed as necessary to meet the specifications of electric work vehicles. In the following, similar elements are assigned with the same reference numerals in all of the drawings, so that redundant explanations are omitted or simplified.
By reference to
The vehicle 10 is a self-propelled lawn mowing vehicle suitable for lawn mowing. The vehicle 10 is equipped with the left wheel 12 and the right wheel 13 which are the left and right wheels (
The left wheel 12 and the right wheel 13 are rear wheels supported on both left and right sides of the rear side of a main frame 20, which is a vehicle body, and are the main drive wheels. The main frame 20 is formed of metal such as steel, so as to have a beam structure or the like. The main frame 20 includes side plate sections 20a and 20b, which extend approximately in the front-rear direction at both left and right ends, and the coupling section 20c, which couples the side plate sections 20a and 20b on the left and right sides. Between the rear end sections of the left and right side plate sections 20a and 20b, a driver's seat 21 on which the driver sits is fixed.
In the main frame 20, two guide panels 26 and 27 are fixed on left and right sides of the driver's seat 21, and the left and right operation levers 22 and 23 are supported on the main frame 20 so as to protrude upward from the two guide panels 26 and 27, respectively. The left operation lever 22 corresponds to an acceleration controller that directs acceleration of the left travel motor 30, and the right operation lever 23 corresponds to an acceleration controller that controls acceleration of the right travel motor 31. The tip sections of the respective operation levers 22 and 23 are grasped by the driver to control the rotational directions and rotational speeds of the left wheel 12 and the right wheel 13. The left operation lever 22 is operated to direct driving and acceleration of the left wheel 12 by changing the direction of the rotational speed of the left wheel 12 to a higher rotational speed. The right operation lever 23 is operated to direct driving and acceleration of the right wheel 13 by changing the direction of the rotational speed of the right wheel 13 to a higher rotational speed. Each of the operation levers 22 and 23 is in an approximate L-shape and has a grip section 24 extending in the left-right direction at the upper end section thereof. The grip section 24 is grasped and operated by the driver. Each of the operation levers 22 and 23 is pivotable about an axis along the left-right direction at the lower end section. Regarding each of the operation levers 22 and 23, in a case of being tilted toward the front side with respect to the N-position, which is the neutral position in the vicinity of the upright position, the motor 30 (or 31) on the same side as the operation lever 22 (or 23) is controlled to be driven at a target rotational frequency per unit time (sec−1) that is a target rotational speed corresponding to forward traveling. The target rotational speed may be set as a target rotational frequency per minute (min−1). The operation levers 22 and 23 direct the target rotational frequencies to be higher as the amounts of tilt become larger. In a case where the operation lever 22 or 23 is tilted toward the rear side with respect to the N-position, the motor 30 (or 31) on the same side as the operation lever 22 (or 23) is controlled to be driven at a target rotational frequency corresponding to backward traveling, and the target rotational frequency is controlled to be higher as the amount of tilt becomes larger. Accordingly, the respective operation levers 22 and 23 direct the target rotational frequencies of the corresponding travel motors 30 and 31.
The pivoting positions of the left and right two operation levers 22 and 23 in the front-rear direction are detected by a left lever sensor 50 and a right lever sensor 51 (
The left and right two caster wheels 15 and 16 are steered wheels supported on the front end section of the main frame 20 and are the front wheels. Each of the caster wheels 15 and 16 is installed so as to be apart from the left wheel 12 and the right wheel 13 in the front-rear direction of the vehicle 10. Each of the caster wheels 15 and 16 is capable of free rotation of 360 degrees or more about a vertical axis (up-down direction in
As illustrated in
The battery 82 (
As illustrated in
The lawnmower may be configured with a lawn mowing reel as a rotary tool for lawn mowing, which has a function of mowing a lawn or the like with a helical blade, for example, arranged on a rotary axis parallel to the ground surface and is driven by a deck motor.
Accordingly, the operation section 32 directs the target rotational frequencies of the left and right travel motors 30 and 31 and directs the actuation of the three deck motors 60. Alternatively, it is also possible that the vehicle is configured with only one travel motor instead of the left and right travel motors 30 and 31 and only one work motor instead of the three deck motors 60 so that the operation section directs the target rotational frequency of the one travel motor and directs the actuation of the one work motor.
The control system 80 includes the start switch 35, the operation section 32 including the working device activation switch 33 and the left and right operation levers 22 and 23, the left and right two lever sensors 50 and 51, the left and right travel motors 30 and 31 and travel inverters 84 and 86, the left and right motor speed sensors 54 and 55, the three deck motors 60 and deck inverters 88, the three deck motor speed sensors 52, and the control device 40. Although only one each of the deck motors 60, deck inverters 88, and deck motor speed sensors 52 is illustrated in
The left travel inverter 84 drives the left travel motor 30, and the right travel inverter 86 drives the right travel motor 31. Each of the travel inverter 84 and 86 is equipped with, for example, a travel inverter circuit, which includes three arms, each of which has two switching elements electrically connected in series, and a travel inverter control device, which controls the travel inverter circuit.
The actuation of each of the travel inverters 84 and 86 is controlled by the control device 40. Accordingly, the left travel motor 30 is controlled by the control device 40 via the left travel inverter 84. The right travel motor 31 is controlled by the control device 40 via the right travel inverter 86. Therefore, the rotational direction and rotational frequency of the left travel motor 30 and the right travel motor 31 are independently controlled by the control device 40. Therefore, the left travel motor 30 and the right travel motor 31 independently drive the left wheel 12 and the right wheel 13 with respect to the rotational directions and rotational frequencies.
Furthermore, detected values of the rotational frequency n (sec−1) of the left travel motor 30 are input from the left motor speed sensor 54 to the left travel inverter control device of the left travel inverter 84. Detected values of the rotational frequency n (sec−1) of the right travel motor 31 are input from the right motor speed sensor 55 to the right travel inverter control device of the right travel inverter 86. The left and right motor speed sensors 54 and 55 detect the rotational frequencies of the left and right travel motors 30 and 31, respectively. Detected values of the rotational frequency of each of the motor speed sensors 54 and 55 are output to the control device 40.
Each of the deck inverters 88 drives the corresponding deck motor 60. As with the travel inverter circuit and travel inverter control device of each of the travel inverters 84 and 86, each of the deck inverters 88 also has a deck inverter circuit, and a deck inverter control device that controls the deck inverter circuit.
The actuation of each of the deck inverters 88 is controlled by the control device 40. Accordingly, the respective deck motor 60 is controlled by the control device 40 via the deck inverter 88. Thus, each of the lawn mowing blades 18a, 18b, and 18c is driven to rotate by the corresponding deck motor 60. Each of the deck motors 60 is basically driven to maintain a predetermined target rotational frequency. The grass mowed by the lawnmower 18 is discharged to one side of the vehicle 10 through a discharge duct 18d installed on one side of the mower deck 19 in the left-right direction.
Furthermore, to the deck inverter control device of each of the deck inverters 88, detected values of the rotational frequency n (sec−1) of the deck motor 60 are input from the respective deck motor speed sensor 52. Each of the deck motor speed sensors 52 detects the rotational frequency of the corresponding deck motor 60. Detected values of rotational frequencies of the deck motor speed sensors 52 are output to the control device 40 via the corresponding deck inverters 88. Note that, in
The control device 40 includes an arithmetic section, such as a CPU, and a storage section, such as a memory, and is configured of a microcomputer, for example. The control device 40 obtains the operating positions of the two operation levers 22 and 23 based on the detection signals of the left and right lever sensors 50 and 51, so as to set the respective target rotational frequencies of the left travel motor 30 and right travel motor 31 according to the operating positions of the respective operation levers 22 and 23.
The control device 40 can perform execution of both straight traveling and turn traveling by setting target rotational frequencies of the left and right travel motors 30 and 31 according to the operating positions of the left and right operation levers 22 and 23.
Furthermore, the vehicle 10 of the present example is configured with the battery monitoring device 90 that monitors the battery condition, which at least includes battery voltage in the battery 82. Therefore, the battery monitoring device 90 detects battery voltage with a voltage sensor. Detected values of battery voltage are output to the control device 40. The control device 40 decreases the upper limit of the target rotational frequencies of at least one of the travel motors 30 and 31 and the deck motors 60 to a first rotational frequency limit, which is a preset first rotational speed limit, based on detection results of the battery condition including a detected value of a battery voltage Vb from the battery monitoring device 90. Here, for example, the control device 40 gradually, e.g., linearly, decreases the upper limit of the target rotational frequencies of the travel motors 30 and 31 in a predetermined time period, which is set in advance, by a first predetermined amount or first predetermined rate, which is set in advance. It is also possible that the control device 40 gradually, e.g., linearly, decreases the upper limit of the target rotational frequencies of the deck motors 60 in a predetermined time period, which is set in advance, by a second predetermined amount or second predetermined rate, which is set in advance.
According to the configuration in the present example, the load on the battery 82 can be reduced according to the condition of the battery 82. Specifically, the change amount in voltage of the battery 82 is different according to the current output from the battery 82. In a case where the change amount in voltage of the battery 82 is large, it means that the current output from the battery 82 is large, and thus the load on the battery 82 is large. Therefore, it is desired to reduce the load on the battery 82 in order to protect the battery 82. To solve this problem, the configuration of the present example decreases the upper limit of the target rotational frequencies of at least one of the travel motors 30 and 31 and the deck motors 60 in a case where the change amount in detected values of battery voltage is large. Thereby, the actual rotational frequencies are decreased, so that the load on the battery 82 can be reduced. Further, it is not necessary that the upper limit of power supplied to at least one of the travel motors 30 and 31 and the deck motors 60 is always kept sufficiently low to protect the battery 82. Accordingly, both protection of the battery 82 and improvement of work efficiency can be achieved.
Furthermore, in a case where the change amount in voltage of the battery 82 is large and the current output from the battery 82 is large, it is expected that the lawnmower 18, which is a working device, is under a large load. In this case, the deck motors 60 are overloaded, and thus protection of the deck motors 60 is desired. In the configuration of the present example, if the upper limit of the target rotational frequencies of the deck motors 60 is decreased in a case where the change amount in detected values of battery voltage is large, it is possible to reduce the load on the battery 82 and protect the deck motors 60.
Although the case in which the upper limit value of the target rotational frequencies of the travel motors 30 and 31 is decreased in a case where the change amount in voltage of the battery 82 is large is hereinafter explained with reference to
In
In
Furthermore, in a case where the battery voltage Vb decreases further from the voltage V2, the control section 100 sets the voltage V2 as the reference voltage and decreases the upper limit of the target rotational frequency of each of the travel motors 30 and 31 to a set second rotational frequency limit vT2 according to the magnitude of the change amount from the voltage V2. For example, the voltage change amount ΔVbat1 is compared with a voltage change amount ΔVbat2, and, in a case where ΔVbat2 is smaller than ΔVbat1, the amount of decrease of the second rotational frequency limit vT2 from the first rotational frequency limit vT1 is made smaller than the amount of decrease of the first rotational frequency limit vT1 from the reference rotational frequency vT0 by the ratio of the voltage change amounts (ΔVbat2/ΔVbat1), for example. Contrarily, in a case where ΔVbat2 is larger than ΔVbat1, the amount of decrease of the second rotational frequency limit vT2 from the first rotational frequency limit vT1 is made larger than the amount of decrease of the first rotational frequency limit vT1 from the reference rotational frequency vT0. Accordingly, the upper limit of the target rotational speed of each of the travel motors 30 and 31 is adjusted.
Therefore, since the target rotational frequency of each of the travel motors 30 and 31 can be decreased in steps according to an increase in the load on the battery 82, it is possible to protect the battery 82 while suppressing a decrease in work efficiency, as compared to a case in which the target rotational frequency is decreased significantly all at once. In the present example, the other configurations and functions are the same as those of
In the case of the present example, regarding
In
Each time a change of battery voltage occurs, the control device 40 adjusts the upper limit of the target rotational frequency of each of the travel motors 30 and 31 according to the change amount from the reference voltage V1 or V2 and a measured value of SOC. Therefore, the battery monitoring device 90 calculates the SOC by using, for example, a detected value of a current sensor that detects the input and output current of the battery 82 or a detected value of the current sensor and a detected value of a voltage sensor that detects the voltage of the battery 82. Measured values of SOC are output to the control device 40.
In the example illustrated in
In the present example, in a case where the measured value of SOC is the SOC threshold or higher, if the battery voltage Vb decreases with the magnitude of the change amount in the battery voltage Vb from the reference voltage V1 being the first threshold ΔVbat1 or larger, the control device 40 decreases the upper limit of the target rotational frequency of each of the travel motors 30 and 31 to the set first rotational frequency limit vT1. On the other hand, if the battery voltage Vb decreases to be lower than the voltage V2 and the measured value of SOC decreases to be lower than the SOC threshold, the control device 40 decreases the upper limit of the target rotational frequency of each of the travel motors 30 and 31 to the set second rotational frequency limit vT2. Here, the decrease amount in rotational frequency limit is changed depending on whether or not the measured value of SOC has decreased to be lower than the SOC threshold. That is, in a case where the SOC measurement value is lower than the SOC threshold, the decrease amount in rotational frequency limit is controlled to be larger than the case in which the SOC measurement value is the SOC threshold or higher.
The change amount in voltage of the battery 82 varies with SOC. For lithium-ion batteries in particular, the correlation between battery voltage and SOC is high. Therefore, by using a change amount in voltage of the battery 82 and a measured value of SOC to set a decrease amount in the rotational frequency limit of each of the travel motors 30 and 31, both protection of the battery 82 and improvement of work efficiency can be achieved with higher precision. In the present example, the other configurations and functions are the same as those of
In the case of the present example, regarding
Further, regarding the above-described configuration explained using
Further, regarding each of the above-described examples, it is also possible to have such a configuration in which the upper limit of the target rotational frequencies of at least one of the travel motors 30 and 31 and the deck motors 60 is decreased by using the change rate of battery voltage to the reference voltage V1 or V2, instead of the decrease amount in battery voltage from the reference voltage V1 or V2. Further, although, in the configuration explained using
In each of the above-described examples, the configuration for decreasing the upper limit of the target rotational frequency of each of the travel motors 30 and 31 could be, for example, the method illustrated in
Regarding
Although, in each of the above-described examples, the case is described in which the upper limit of the target rotational frequency or target torque of motors is decreased if the voltage of a battery changes significantly, it is also possible that the motors are controlled so that the upper limit of the actual rotational frequency or actual torque of the motors is decreased.
Further, the vehicle is also equipped with a first current sensor 61 that detects a discharge current is which is output from the battery 82 to the left travel inverter 84, a second current sensor 62 that detects a discharge current ib which is output from the battery 82 to the right travel inverter 86, and a third current sensor 63 that detects a discharge current is which is output from the battery 82 to each of the deck inverters 88. The first current sensor 61, the second current sensor 62, and the third current sensor 63 configure a current sensor that measures the actual discharge current of the battery 82.
Detected values of the first current sensor 61 are obtained by the left travel inverter control device of the left travel inverter 84. Detected values of the second current sensor 62 are obtained by the right travel inverter control device of the right travel inverter 86. Detected values of the third current sensor 63 are obtained by the deck inverter control device of the deck inverters 88. The control device 40 obtains, via signal lines S2, S3, and S4, the detected values of the discharge current from the battery 82 to each of the travel inverters 84 and 86, which are obtained by each of the travel inverters 84 and 86, and the detected values of the discharge current from the battery 82 to the deck inverters 88, which are obtained by the deck inverters 88, so as to calculate the actual discharge current of the battery 82, based on the sum of the respective detected values. Here, it is also possible to have such a configuration in which the detected values of the discharge current obtained by each of the inverters 84, 86, and 88 are constantly sent from each of the inverters 84, 86, and 88 via CAN communication. Instead of signal lines, it is also possible that each of the inverters 84, 86, and 88 and the control device 40 have a wireless communication section as a communication unit for sending and receiving wireless signals between the inverters 84, 86, and 88 and the control device 40.
Furthermore, the control device 40 controls the rotational speed of each of the travel motors 30 and 31 so that the actual discharge current of the battery 82 does not exceed the specified maximum discharge current while each deck motor 60 is being driven. For example, the control device 40 decreases the target rotational frequency of each of the travel motors 30 and 31 in a case where the actual discharge current of the battery 82 reaches a threshold current, which is lower than the maximum discharge current. Here, for example, the control device 40 gradually, e.g., linearly, decreases the target rotational frequency of the travel motors 30 and 31 in a predetermined time period, which is set in advance, by the first predetermined amount or first predetermined rate, which is set in advance, regardless of operations on the left and right operation levers 22 and 23. Here, to further enhance safety during traveling of the vehicle, it is also possible to have such a configuration in which, in a case where the left and right operation levers 22 and 23 are operated to decrease the speed of the vehicle, the target rotational frequency of the travel motors 30 and 31 is decreased according to the operation.
According to the configuration of the present example, by the control of the rotational frequency of each of the travel motors 30 and 31, it is possible to prevent the actual discharge current of the battery 82 from exceeding the maximum discharge current while each deck motor 60 is being driven. Thus, it is possible to prevent the vehicle from stopping abruptly even in a case where the process of cutting off the current flowing from the battery 82 to each of the motors 30, 31, and 60 is performed for the purpose of protecting the battery 82.
Further, if the control section 100 is configured to obtain the maximum discharge current from the battery monitoring device 90 via a communication unit, in a case where the type of battery is changed, it is only necessary to change the setting of the battery monitoring device 90 to set the maximum discharge current according to the type of battery, and thus there is no need to change the setting of the control section 100.
Further, as illustrated with a dashed line in
Further, in the description above, although a current sensor that detects the discharge current output from the battery 82 to the inverters 84, 86, and 88 is installed separately from each of the inverters 84, 86, and 88, it is also possible that the current sensor is included inside the inverter control device of each of the inverters 84, 86, and 88.
In
As illustrated in
Since the actual discharge current of the battery 82 is prevented from exceeding the maximum discharge current in this way, protection of the battery 82 can be achieved while preventing the vehicle from stopping abruptly. Accordingly, both protection of the battery 82 and improvement of work efficiency can be achieved. In the present example, the other configurations and functions are the same as those of
In
The pack connection sections 104 are connectors such as plugs that are removably connected to connectors of the battery packs 101, 102, and 103. Since such pack connection sections 104 have a well-known structure in the field of battery connection sections for electrically power assisted bicycles, etc., a detailed description is omitted. The user can easily attach and detach each of the multiple battery packs 101, 102, and 103 to the independently corresponding pack connection section 104. The battery packs 101, 102, and 103 have the voltage Vbat_1, Vbat_2, . . . , and Vbat_n, respectively.
One end side of each of multiple forward directional converters D1, D2, . . . , and Dn, which can flow current from the corresponding battery packs 101, 102, and 103 only in the direction of outputs to the travel motors 30 and 31 side, i.e., the load sections, is connected to the respective multiple pack connection sections 104. The forward directional converters D1, D2, . . . , and Dn are diodes, for example. The other ends of the multiple forward directional converters D1, D2, . . . , and Dn are connected at a connection section 105. The travel motors 30 and 31 are connected to the connection section 105 via the travel inverters 84 and 86.
According to the configuration of the present example, in a case of outputting power from the multiple battery packs 101, 102, and 103 to the load sections, current can be output to the loads in order from the battery pack 101, 102, or 103 with the highest voltage among the multiple battery packs 101, 102, and 103. Accordingly, there is no need to align the voltage of the multiple battery packs 101, 102, and 103 in advance before outputting current from the battery 82 to the load sections. Thus, it is possible to charge the battery 82 without excessively adjusting the voltage or charge amount of the multiple battery packs 101, 102, and 103. Furthermore, the voltage of the battery 82 can be more stabilized.
In
Furthermore, in a case where the voltages of the three battery packs 101, 102, and 103 are equal to each other (Vbat_1=Vbat_2=Vbat_3), power can be supplied from all of the three battery packs 101, 102, and 103 to the load section side.
In the present example, the other configurations and functions are the same as those of
In
The first bidirectional converters 110 are the switches SW1, SW2, . . . , and SWn that are connected in parallel to the forward directional converters D1, D2, . . . , and Dn. The switches SW1, SW2, . . . , and SWn are semiconductor switches or mechanical switches whose switching of conduction is controlled by a control signal that is output from the control device 40. By switching, each of the first bidirectional converters 110 can flow current in both of the direction of outputs from the corresponding battery packs 101, 102, and 103 and direction of inputs to the corresponding battery packs 101, 102, and 103.
Furthermore, the vehicle is equipped with voltage sensors 112, 113, and 114 that detect voltages of the multiple battery packs 101, 102, and 103, respectively. The detected signals representing detected values Vbat_1, Vbat_2, and Vbat_3 of the voltage sensors 112, 113, and 114 are output to the control device 40.
The control device 40 determines whether or not the voltages of two or more of the multiple battery packs 101, 102, and 103 match, based on the detected values of the voltage sensors 112, 113, and 114. Further, in a case where it is determined by the control device 40 that voltages of two or more of the battery packs 101, 102, and 103 match, the control device 40 outputs the control signals G1, G2, and Gn, which are for switching to bidirectionally conductive, to the first bidirectional converters 110 corresponding to the battery packs 101, 102, and 103 whose voltages have matched. Accordingly, the first bidirectional converters 110 corresponding to the battery packs 101, 102, and 103 those voltages have matched are switched to bidirectionally conductive.
According to the configuration of the present example, by switching the first bidirectional converters 110 to bidirectionally conductive, power can be supplied to the battery packs 101, 102, and 103 from the load section side by power regeneration or the like to charge the battery 82.
Furthermore, in a case where voltages of two or more of the battery packs 101, 102, and 103 match, the first bidirectional converters 110 corresponding to the battery packs 101, 102, and 103 whose voltages have matched are switched to bidirectionally conductive. Accordingly, in a case where power can be supplied to the battery packs 101, 102, and 103 from the load section side, it is possible to prevent power from being input or output among the battery packs 101, 102, and 103. Accordingly, the voltage of the battery 82 can be more stabilized.
In
Next, in a case where the voltages of the two battery packs 101 and 102 are equal to each other (Vbat_1=Vbat_2), both of the first bidirectional converters 110 corresponding to the two battery packs 101 and 102 are switched to bidirectionally conductive. Here, power is supplied to the load section side from both of the two battery packs 101 and 102. Accordingly, the voltages of the two battery packs 101 and 102 decrease.
Furthermore, in a case where the voltages of the three battery packs 101, 102, and 103 are equal to each other (Vbat_1=Vbat_2=Vbat_3), all of the first bidirectional converters 110 corresponding to the three battery packs 101, 102, and 103 are switched to bidirectionally conductive. Here, power is supplied to the load section side from all of the three battery packs 101, 102, and 103.
In the present example, the other configurations and functions are the same as those of
In
The control device 40 determines whether or not voltages of two or more of the multiple battery packs 101, 102, and 103 match, based on the detected values of the respective current sensors 115, 116, and 117. Further, in a case where it is determined by the control device 40 that voltages of two or more of the battery packs 101, 102, and 103 match, the control device 40 outputs the control signals, which are for switching to bidirectionally conductive, to the first bidirectional converters 110 corresponding to the battery packs 101, 102, and 103 whose voltages have matched. Accordingly, the first bidirectional converters 110 corresponding to the battery packs 101, 102, and 103 those voltages have matched are switched to bidirectionally conductive.
According to the configuration of the present example, as with the configuration of
In
The second bidirectional converters 118 are configured of electric field effect transistors (FET) with parasitic diodes. The second bidirectional converters 118 are controlled to switch conduction by control signals that are output from the control device 40. By switching, each of the second bidirectional converters 118 can flow current in both of the direction of outputs from the corresponding battery packs 101, 102, and 103 and direction of inputs to the corresponding battery packs 101, 102, and 103.
In
Next, in a case where the voltages of the two battery packs 101 and 102 are equal to each other (Vbat_1=Vbat_2), both of the second bidirectional converters 118 corresponding to the two battery packs 101 and 102 are switched to bidirectionally conductive. Here, power is supplied to the load section side from both of the two battery packs 101 and 102. Accordingly, the voltages of the two battery packs 101 and 102 decrease.
Furthermore, in a case where the voltages of the three battery packs 101, 102, and 103 are equal to each other (Vbat_1=Vbat_2=Vbat_3), all of the second bidirectional converters 118 corresponding to the three battery packs 101, 102, and 103 are switched to bidirectionally conductive. Here, power is supplied to the load section side from all of the three battery packs 101, 102, and 103.
In the present example, the other configurations and functions are the same as those of
At least one of the above-described respective embodiments has the configuration of the first electric work vehicle according to the present disclosure. Accordingly, since the load on the battery can be reduced by decreasing the upper limit of rotational speed of a motor in a case where the load on the battery becomes high, such as in a case where the change amount in voltage of the battery that supplies power to the motor becomes large, it is possible to achieve both protection of the battery and improvement of work efficiency.
Regarding the first electric work vehicle, it is also possible to have such a configuration wherein, in a case where a change amount in voltage of the battery from a reference voltage or a magnitude of a change rate of voltage of the battery to the reference voltage is a first threshold or higher, the control section decreases the upper limit of rotational speed of the motor to a set first rotational speed limit.
Regarding the first electric work vehicle, it is also possible to have such a configuration wherein, each time a change in voltage of the battery occurs, the control section adjusts the upper limit of rotational speed of the motor according to a change amount from a reference voltage or a magnitude of a change rate to the reference voltage.
According to the above-described configuration, it is possible to protect the battery while suppressing a decrease in work efficiency, as compared to a case in which the target rotational speed is decreased significantly all at once.
Regarding the first electric work vehicle, it is also possible to have such a configuration wherein the battery condition includes a remaining charge amount of the battery, and wherein, each time a change in voltage of the battery occurs, the control section adjusts the upper limit of rotational speed of the motor according to a change amount from a reference voltage or a change rate to the reference voltage, and the remaining charge amount.
According to the above-described configuration, it is possible to achieve both protection of the battery and improvement of work efficiency with higher precision.
Regarding the first electric work vehicle, it is also possible to have such a configuration further including a battery monitoring device configured to monitor the battery condition, wherein the control section decreases an upper limit of target rotational speed of the motor so as to decrease an upper limit of actual rotational speed, based on a detected result with regard to the battery condition from the battery monitoring device.
Regarding the first electric work vehicle, it is also possible to have such a configuration wherein the at least one motor is a travel motor which drives the at least one travelling device and a work motor which drives the at least one working device.
At least one of the above-described respective embodiments has the configuration of the second electric work vehicle according to the present disclosure. Accordingly, since the load on the battery can be reduced by decreasing the upper limit of torque of a motor in a case where the load on the battery becomes high, such as in a case where the change amount in voltage of the battery that supplies power to the motor becomes large, it is possible to achieve both protection of the battery and improvement of work efficiency.
At least one of the above-described respective embodiments has the configuration of the third electric work vehicle according to the present disclosure. Accordingly, by controlling the rotational speed of the travel motor, it is possible to prevent the discharge current of the battery from exceeding the maximum discharge current during driving of the work motor. Thus, it is possible to prevent the vehicle from stopping abruptly even in a case where the process of cutting off the current flowing from the battery to each motor is performed for the purpose of protecting the battery. Accordingly, both protection of the battery and improvement of work efficiency can be achieved.
Regarding the third electric work vehicle, it is also possible to have such a configuration further including a battery monitoring device configured to monitor a condition of the battery, wherein the control section obtains the maximum discharge current from the battery monitoring device via a communication unit.
According to the above-described configuration, in a case where the type of battery is changed, it is only necessary to change the setting of the battery monitoring device to set the maximum discharge current according to the type of battery, and thus there is no need to change the setting of the control section.
Regarding the third electric work vehicle, it is also possible to have such a configuration wherein the travel motor is driven by a travel inverter, wherein the work motor is driven by a work inverter, and wherein the control section calculates the discharge current from a sum of a detected value of a discharge current from the battery to the travel inverter, which is obtained by the travel inverter, and a detected value of a discharge current from the battery to the work inverter, which is obtained by the work inverter.
According to the above-described configuration, in order for the control section to obtain the discharge current of the battery, it is not necessary that the current sensor that detects the discharge current of the battery and the control section are connected only with a signal line dedicated to send detected values of the actual discharge current of the battery.
Regarding the third electric work vehicle, it is also possible to have such a configuration further including a battery monitoring device configured to monitor a condition of the battery, wherein the control section obtains the discharge current from the battery monitoring device via a communication unit.
According to the above-described configuration, in order for the control section to obtain the actual discharge current of the battery, it is not necessary that the current sensor that detects the discharge current of the battery and the control section are connected only with a signal line dedicated to send detected values of the actual discharge current of the battery.
Regarding the third electric work vehicle, it is also possible to have such a configuration further including a sensor configured to measure the discharge current of the battery, wherein the control section obtains the discharge current from the sensor via a communication unit.
Regarding any one of the first electric work vehicle, the second electric work vehicle, and the third electric work vehicle, it is also possible to have such a configuration wherein, regarding the battery, a plurality of battery packs are removably connected to a plurality of pack connection sections, so that the plurality of battery packs can be electrically connected in parallel, and wherein forward directional converters that can flow current only in a direction of an output from the corresponding battery packs are connected to the plurality of pack connection sections, respectively.
According to the above-described configuration, in a case of outputting power from the multiple battery packs to the load sections, current can be output to the load sections in order from the battery pack with the highest voltage among the multiple battery packs. Accordingly, there is no need to align the voltages of the multiple battery packs in advance before outputting current from the battery to the load sections. Thus, it is possible to charge the battery without excessively adjusting the voltages or charge amounts of the multiple battery packs.
Regarding any one of the first electric work vehicle, the second electric work vehicle, and the third electric work vehicle, it is also possible to have such a first configuration wherein, regarding the battery, a plurality of battery packs are removably connected to a plurality of pack connection sections, so that the plurality of battery packs can be electrically connected in parallel, and wherein bidirectional converters that can flow current in both of a direction of an output from the corresponding battery packs and a direction of an input to the corresponding battery packs by switching therebetween are connected to the plurality of pack connection sections, respectively.
According to the above-described first configuration, by switching the bidirectional converters to bidirectionally conductive, power can be supplied to the battery packs from the load side by power regeneration or the like, in order to charge the battery.
Regarding the above-described first configuration, it is also possible to have such a configuration further including a voltage sensor configured to detect voltages of the plurality of battery packs, respectively, wherein, based on a detected value of the voltage sensor, whether or not voltages of two or more of the plurality of battery packs match is determined.
According to the above-described configuration, if the voltages of two or more battery packs match, in a case where the bidirectional converters corresponding to the battery packs whose voltages has matched are configured to be switched to bidirectionally conductive, wherein power can be supplied to the battery packs from the load section side, it is possible to prevent input and output of power among the battery packs.
Regarding the above-described first configuration, it is also possible to have such a configuration including a current sensor configured to detect current values that are output from the plurality of battery packs, respectively, wherein, based on a detected value of the current sensor, whether or not voltages of two or more of the plurality of battery packs match is determined.
According to the above-described configuration, if the voltages of two or more battery packs match, in a case where the bidirectional converters corresponding to the battery packs whose voltages match are configured to be switched to bidirectionally conductive, wherein power can be supplied to the battery packs from the load section side, it is possible to prevent input and output of power among the battery packs.
According to an electric work vehicle of the present disclosure, it is possible to achieve both protection of a battery and improvement of work efficiency.
Number | Date | Country | Kind |
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2022-058489 | Mar 2022 | JP | national |
2023-025024 | Feb 2023 | JP | national |