JP5699509B2 - Riding lawn mower vehicle and control method thereof - Google Patents

Description

  The present invention relates to a riding lawnmower vehicle that allows an operator to ride and drive a lawn while mowing and driving, and a control method therefor.

  Riding lawn mower vehicles are equipped with a vehicle body with wheels attached and a lawn mowing unit (reel) that can be raised and lowered provided on the vehicle body. Is possible. For this reason, the riding lawn mowing vehicle cuts grass in a wider area such as a green field or a stadium than a push-type (walk-behind type) lawn mowing vehicle operated by an operator from the rear side of the vehicle. Suitable for

A conventional riding lawn mower vehicle includes an internal combustion engine such as an engine as a power generation source and the like, and drives wheels and hydraulic cylinders (hydraulic cylinders that raise and lower the lawn mowing unit) using the power generated by the internal combustion engine. There were many things. However, in recent years, in order to reduce the amount of carbon dioxide (CO ₂ ), which is a kind of greenhouse gas, a hybrid type or an electric type that drives (including raising and lowering) a lawn mowing unit using the power of a motor. Research and development of passenger-type lawn mowing vehicles is actively underway.

  Patent Document 1 below discloses a technique for preventing turf damage at the time of stopping in a vehicle such as a riding lawn mowing vehicle or a tractor equipped with an engine as a power generation source. Specifically, in Patent Document 1 below, when the speed change operation unit is operated to the neutral position to stop the vehicle, the brake device is switched to the brake braking state after the stop of the vehicle is detected. A technique for preventing a wheel from being suddenly braked and being locked is disclosed.

JP-A-6-191327

  By the way, in general, an engine has a small torque in a low rotation range (for example, a rotation range of about 1000 rpm), whereas a motor can obtain a large torque even in a low rotation range. For this reason, a riding lawn mower vehicle that travels using the power of the motor (for example, the above-described hybrid or electric riding lawn mower vehicle) includes an engine when an operator misoperates the pedal. It is considered that the wheels are more likely to slip (idle) than a riding lawn mower.

  Here, the wheel slip described above is not only caused by an erroneous operation of the pedal at the start of traveling, but can also be caused by an erroneous operation of the pedal during traveling. For this reason, it is necessary for the operator to operate the pedal with great care while driving the riding lawn mowing vehicle, which may increase the burden on the operator. When such wheel slip occurs, for example, there may be a situation where damaged turf is scattered at the place where turf mowing has been performed, and as a result, the turf mowing quality deteriorates. There is.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a riding-type lawn mowing vehicle that can prevent wheel damage by suppressing wheel slip and a control method therefor.

In order to solve the above-described problems, the riding lawn mowing vehicle of the present invention includes a motor (41) that generates a driving force for rotating wheels (11a, 11b). Based on the detection result of at least one of the first sensor (Q1) for detecting the number of rotations, the second sensor (Q2) for detecting the current value of the current flowing through the motor, and the first and second sensors. A determination unit (38a) that determines whether or not the wheel is in a slip state, and a control unit (38c) that performs control to reduce the torque of the motor when the determination unit determines that the wheel is in a slip state. It is characterized by comprising.
In the riding-type lawn mower vehicle of the present invention, the determination unit determines that the wheel is in a slip state when the rate of change of the detection result of the first sensor is equal to or greater than a preset limit value. When the current value detected by the 1 determination unit (J1) and the second sensor is equal to or less than the minimum drive current value that is the minimum value of the current that should flow to the motor according to the running state of the vehicle, A second determination unit (J2) that determines that the vehicle is in the slip state is provided.
The riding lawn mowing vehicle of the present invention uses a speed sensor (36) for detecting the speed of the vehicle, an attitude sensor (37) for detecting the attitude of the vehicle, and detection results of the speed sensor and the attitude sensor. And a calculation unit (38b) for calculating the minimum drive current value.
In the riding lawn mower vehicle of the present invention, the calculation unit obtains a running resistance from the detection results of the speed sensor and the attitude sensor and the road surface resistance, and the detection result of the running resistance and the first sensor The minimum drive current value is calculated.
In the riding lawn mower vehicle of the present invention, the control unit performs control to intermittently stop the torque of the motor.
The method for controlling a riding lawn mower vehicle of the present invention is a method for controlling a riding lawn mower vehicle (1) including a motor (41) that generates a driving force for rotating wheels (11a, 11b). Based on the detection result of at least one of the first step (S11) for detecting the rotational speed of the motor, the second step (S19) for detecting the current value of the current flowing through the motor, and the first and second steps. A third step (S13, S19) for determining whether or not the wheel is in a slip state, and a control for reducing the torque of the motor when it is determined in the third step that the wheel is in a slip state. And a fourth step (S22) to be performed.

  According to the present invention, whether or not the wheel is in a slip state based on the detection result of at least one of the first sensor that detects the rotation speed of the motor and the second sensor that detects the current value of the current flowing through the motor. When the determination unit determines that the wheel is in the slip state, control is performed to reduce the torque of the motor, so that the slip of the wheel is suppressed and turf damage can be prevented. is there.

1 is a perspective view showing an external appearance of a riding lawn mowing vehicle according to an embodiment of the present invention. It is a block diagram which shows the principal part structure of the control system of the riding type lawn mower vehicle by one Embodiment of this invention. It is a figure which shows the example of a change of the rotation speed of a motor and the electric current which flows into a motor when the front wheel of a riding-type lawn mower vehicle will be in a slip state. It is a flowchart which shows the control method of the riding-type lawn mower vehicle by one Embodiment of this invention.

  Hereinafter, a riding lawnmower vehicle and a control method thereof according to an embodiment of the present invention will be described in detail with reference to the drawings. FIG. 1 is a perspective view showing an appearance of a riding lawn mower according to an embodiment of the present invention. As shown in FIG. 1, the riding lawnmower vehicle 1 of this embodiment includes two front wheels 11a and 11b (wheels) and one rear wheel 12 supported by a frame 10, and two front lawn mowing units 13a and 13b. And one rear lawn mowing unit 14, while traveling by the front wheels 11 a and 11 b and the rear wheel 12, the front lawn mowing units 13 a and 13 b and the rear lawn mowing unit 14 along the traveling path Mowing.

  A riding-type lawn mowing vehicle 1 shown in FIG. 1 is an electric riding-type lawn mowing vehicle that travels using power generated by a motor and cuts grass using power generated by the motor. Note that each of the front lawn mowing units 13a and 13b and the rear lawn mowing unit 14 provided in the riding type lawn mower vehicle 1 is provided with a bucket for accommodating the cut lawn (mowing lawn). The figure which has been removed is shown.

  A seat 15 on which an operator is seated is disposed substantially at the upper center of the frame 10. A steering wheel 16 is provided at the upper front portion of the seat 15, and a reverse accelerator pedal 17, a forward accelerator pedal 18, and a brake pedal 19 are provided at the lower front portion. By operating the steering wheel 16 by an operator seated on the seat 15, the traveling direction of the riding lawn mowing vehicle 1 is determined, and the reverse accelerator pedal 17, the forward accelerator pedal 18, and the brake pedal 19 are operated. The reverse, forward, stop and travel speed of the riding lawn mowing vehicle 1 are determined.

  The front wheels 11a and 11b are respectively disposed on the right front lower portion and the left front lower portion of the frame 10, and are drive wheels driven by power generated by a motor 41 (not shown in FIG. 1, see FIG. 2). It is supported by the frame 10 so as to be rotatable around a rotation axis along the left-right direction of the vehicle. The rear wheel 12 is disposed at the lower center rear portion of the frame 10 and is configured to be swingable in the left-right direction in accordance with the rotation amount of the steering wheel 16 and functions as a steering wheel. As the rear wheel 12 swings in the left-right direction, the rotating shaft of the rear wheel 12 also swings. Therefore, the traveling direction of the riding lawn mowing vehicle 1 is changed by rotating the steering wheel 16.

  The front lawn mowing units 13a and 13b are supported so as to be movable up and down in front of each of the front wheels 11a and 11b, and move down to cut the lawn while in contact with the ground in front of the front wheels 11a and 11b. Each of these front lawn mowing units 13 a and 13 b includes a front roller 21, an electric reel 22 (rotary blade), a rear roller (not shown), and a motor 24. The front roller 21 and a rear roller (not shown) are provided to support the front lawn mowing units 13a and 13b in a lowered state on the ground.

  The electric reel 22 is a substantially cylindrical member in which a plurality of spiral blades for mowing the lawn are formed on the side surface, the rotation axis is set in the left-right direction of the vehicle, and is driven by the motor 24. The electric reel 22 is disposed between the front roller 21 and a rear roller (not shown), and is disposed above the front roller 21 and the rear roller (not shown) by the height of the grass after cutting. Has been. The height position of the electric reel 22 relative to the front roller 21 and the rear roller (not shown) can be finely adjusted within a range of, for example, about several mm to several tens of mm.

  A support arm 25a extending in the right direction from the central portion and a support arm 25b extending in the left direction from the central portion are provided at the front portion of the frame 10. The support arm 25a supports the front lawn mowing unit 13a so as to be swingable around the rotation axis in the front-rear direction of the vehicle at the right end thereof, and the support arm 25b rotates at the left end of the rotation axis in the front-rear direction of the vehicle. The front lawn mowing unit 13b is supported so as to be swingable. For this reason, even if the ground is inclined in the left-right direction of the vehicle, the front lawn mowing units 13a and 13b can be inclined in accordance with the inclination.

  Electric cylinders 26a and 26b as electric actuators are attached to the support arms 25a and 25b. When the electric cylinder 26a expands and contracts, the right end of the support arm 25a moves up and down, and the front lawn mowing unit 13a moves up and down. Similarly, when the electric cylinder 26b expands and contracts, the left end portion of the support arm 25b moves in the vertical direction, whereby the front lawn mowing unit 13b moves up and down. That is, the support arms 25a and 25b and the electric cylinders 26a and 26b constitute an elevating mechanism that elevates and lowers the front lawn mowing units 13a and 13b. In FIG. 1, the front lawn mowing unit 13a is raised, and the front lawn mowing unit 13b is lowered.

  The rear lawn mowing unit 14 is supported between the front wheels 11a and 11b and the rear wheel 12 so as to be able to move up and down, and cuts the lawn while being lowered and in contact with the ground in front of the rear wheel 12. Similar to the front lawn mowing units 13a and 13b, the rear lawn mowing unit 14 includes a front roller 21, an electric reel 22 (rotary blade), a rear roller (not shown), and a motor 24, and an electric cylinder 26a. , 26b is lifted and lowered by a lifting mechanism (not shown) including an electric cylinder (electric actuator) and the like. As with the front lawn mowing units 13a and 13b, the rear lawn mowing unit 14 is also supported so as to be able to swing around a rotation axis in the front-rear direction of the vehicle, and matches the inclination of the ground in the left-right direction of the vehicle. Can be tilted.

  Further, a touch panel display device (for example, a liquid crystal display device) 27 is provided in front of the right side of the seat 15 (on the right side of the steering wheel 16). This display device 27 is for inputting various instructions such as information indicating the current state of the riding lawn mowing vehicle 1 as well as inputting instructions from the operator. The raising / lowering of the front lawn mowing units 13a, 13b and the rear lawn mowing unit 14 and the starting / stopping of the electric reels 22 provided thereto are in accordance with instructions input by the operator operating the display device 27. Be controlled. The information displayed on the display device 27 includes the traveling speed of the riding lawn mowing vehicle 1, the rotational speed of the electric reels 22 provided in each of the front lawn mowing units 13a and 13b and the rear lawn mowing unit 14, and the lawn. It is information such as information indicating the development status of the child.

  An illumination device 28 that illuminates the front of the riding lawnmower vehicle 1 is provided below the steering wheel 16 and between the forward accelerator pedal 18 and the brake pedal 19. Further, a battery B for supplying electric power for operating the riding lawn mower 1 is provided on the frame 10 behind the seat 15. Specifically, the electric power supplied from the battery B includes a motor 41 (see FIG. 2) that drives the front wheels 11a and 11b, and a motor 42 (built in an electric cylinder 45 that generates a driving force that swings the rear wheels 12. 2), motors 24a, 43b (see FIG. 2) for generating power for driving the motor 24 and the electric cylinders 26a, 26b provided in the front lawn mowing units 13a, 13b and the rear lawn mowing unit 14, respectively. Used to drive the etc.

  FIG. 2 is a block diagram showing a main configuration of the control system of the riding lawn mower vehicle according to one embodiment of the present invention. In FIG. 2, components corresponding to those shown in FIG. As shown in FIG. 2, the riding lawn mowing vehicle 1 includes a DC / DC converter 31, an AC motor driver 32, an electric cylinder driver 33, electric cylinder drivers 34a and 34b, AC motor drivers 35a and 35b, a speed sensor 36, A 3D gyro sensor 37 (attitude sensor) and a control device 38 are provided. In FIG. 2, a path through which power is transmitted is indicated by a solid line, and a signal path related to the control system is indicated by a broken line.

  The DC / DC converter 31 is provided between the battery B and various drivers (AC motor driver 32 to AC motor driver 35b), and is supplied with DC power from the battery B to various drivers under the control of the control device 38. Voltage conversion of the regenerative electric power generated by the motor 41 that drives the front wheels 11a and 11b and recovered by the battery B is performed. Specifically, the output voltage of the battery B is boosted and applied to various drivers, or the electromotive force generated by the motor 41 is stepped down and applied to the battery B.

  The AC motor driver 32 uses direct current power supplied from the battery B via the DC / DC converter 31 and drives a motor 41 that generates power for driving the front wheels 11 a and 11 b under the control of the control device 38. . In FIG. 2, a block (a block denoted by reference numeral 44) provided between the motor 41 and the front wheels 11 a and 11 b reduces the rotational speed of the power (rotational power) generated by the motor 41. The reduction gear (reduction gear) transmitted to the front wheels 11a and 11b is shown. Further, the AC motor driver 32 operates the motor 41 as a generator under the control of the control device 38, and causes the battery B to recover the regenerative power generated by the motor 41 via the DC / DC converter 31.

  Further, the motor 41 is provided with a motor rotation speed sensor Q1 (first sensor) such as an encoder or a resolver for detecting the rotation speed of the motor 41, and a rotation speed signal indicating a detection result of the motor rotation speed sensor Q1. S <b> 1 is input to the AC motor driver 32. The AC motor driver 32 is provided with a motor current sensor Q2 (second sensor) that detects a current value of a current flowing through the motor 41. The AC motor driver 32 communicates with the control device 38, such as the rotational speed of the motor 41 indicated by the rotational speed signal S1, the current flowing through the motor 41, the torque generated in the motor 41, and the like. Send information.

  The electric cylinder driver 33 uses direct-current power supplied from the battery B via the DC / DC converter 31 to drive power for driving the electric cylinder 45 that swings the rear wheel 12 under the control of the control device 38. The generated motor 42 is driven. The motor 42 is provided with an encoder (not shown) for detecting the drive amount of the electric cylinder 45 (that is, the swing angle of the rear wheel 12), and a swing angle signal S2 indicating the detection result of the encoder is provided. This is input to the electric cylinder driver 33. The electric cylinder driver 33 communicates with the control device 38 to transmit information such as the swing angle of the rear wheel 12 indicated by the swing angle signal S2.

  The electric cylinder drivers 34a and 34b use direct current power supplied from the battery B via the DC / DC converter 31 and are motors that generate power for driving the electric cylinders 26a and 26b under the control of the control device 38. 43a and 43b are driven. The AC motor drivers 35a and 35b use DC power supplied from the battery B via the DC / DC converter 31 and are controlled by the control device 38, and the front lawn mowing units 13a and 13b and the rear lawn mowing unit 14 are used. The motor 24 provided in is driven.

  Here, each of the motors 24 provided in the front lawn mowing units 13a and 13b and the rear lawn mowing unit 14 is provided with an encoder or a resolver (not shown) for detecting the respective rotation speeds. The rotation speed signals S3 and S4 indicating the detection results are input to the AC motor drivers 35a and 35b, respectively. 2, the AC motor driver 35a includes a driver for driving the motor 24 provided in the front lawn mowing unit 13a and a driver for driving the motor 24 provided in the front lawn mowing unit 13b. Is included. The rotation speed signal S3 is a signal including a signal indicating the rotation speed of the motor 24 provided in the front lawn mowing unit 13a and a signal indicating the rotation speed of the motor 24 provided in the front lawn mowing unit 13b.

  The speed sensor 36 is a sensor that detects the vehicle speed of the riding lawn mower vehicle 1. The speed sensor 36 is generated, for example, by rotation of a detection gear (gear) having several tens to hundreds of teeth attached to a drive shaft (shaft) between the reduction gear 44 and the front wheels 11a and 11b. It is a sensor that counts pulses at regular intervals and detects the vehicle speed of the riding lawn mowing vehicle 1 from the count result. A sensor that detects the vehicle speed from the pulse interval (interval time) may be used.

  The 3D gyro sensor 37 is a sensor that detects the posture of the riding lawnmower vehicle 1. Specifically, a rotation angle (θX, θY) around two axes (X axis, Y axis) perpendicular to each other in the horizontal plane and a rotation angle around a vertical axis (Z axis) orthogonal to the horizontal plane (Z axis) θZ), and a sensor that detects the acceleration of each of the X, Y, and Z axes. For this reason, acceleration / deceleration of the vehicle speed and ascending / descending of the slope can be determined. Here, an example in which the 3D gyro sensor 37 is used to detect the attitude of the riding lawn mower vehicle 1 will be described. However, instead of the 3D gyro sensor 37, only the inclination in the front-rear direction of the riding lawn mower vehicle 1 is detected. It is also possible to use a sensor. The detection results of the speed sensor 36 and the 3D gyro sensor 37 are output to the control device 38.

  The control device 38 controls the riding lawn mowing vehicle 1 in an integrated manner. Specifically, the control device 38 receives various input operation signals (operation angle signal S5 and pedal operation signals S6 to S8) and signals transmitted from various drivers (AC motor driver 32 to AC motor driver 35b). While referencing, the drive amount of various motors (motors 24, 41 to 43b) is controlled by various drivers. In addition, the control device 38 monitors the state of charge (SOC) of the battery B, controls the power consumption by the DC / DC converter 31, and uses the regenerative power generated by the motor 41. Perform charging control.

  The operation angle signal S5 is a signal indicating the operation angle (steering angle) of the steering wheel 16, and is output from the encoder E1 that detects the operation angle of the steering wheel 16. The pedal operation signals S6 to S8 are signals indicating the operation amounts (depression amounts) of the reverse accelerator pedal 17, the forward accelerator pedal 18, and the brake pedal 19.

  Here, as illustrated in FIG. 2, the control device 38 includes a slip state determination unit 38 a (determination unit), a minimum drive current value calculation unit 38 b (calculation unit), and a motor control unit 38 c (control unit). It is determined whether or not the front wheels 11a and 11b are in the slip state. When it is determined that the front wheels 11a and 11b are in the slip state, control is performed to reduce the torque of the motor 41. This control is performed in order to prevent the front wheels 11a and 11b from slipping (idling) and to prevent turf damage (so-called turf cut).

  The slip state determination unit 38a is configured based on the detection result of at least one of the motor rotation speed sensor Q1 that detects the rotation speed of the motor 41 and the motor current sensor Q2 that detects the current value of the current flowing through the motor 41. It is determined whether 11b is in a slip state. Specifically, the slip state determination unit 38a includes a first determination unit J1 that determines a slip state using a detection result of the motor rotation speed sensor Q1, a detection result of the motor current sensor Q2, and a maximum drive current value calculation unit 38b. And a second determination unit J2 that determines the slip state using the maximum drive current value calculated in (1).

  The first determination unit J1 determines that the front wheels 11a and 11b are in the slip state when the rate of change of the detection result of the motor rotation speed sensor Q1 is equal to or greater than a preset limit value. On the other hand, the second determination unit J2 has a minimum drive current value in which the current value detected by the motor current sensor Q2 is the minimum value of the current that should flow to the motor 41 according to the traveling state of the riding lawn mowing vehicle 1. When it is below, it determines with the front wheels 11a and 11b being a slip state.

  FIG. 3 is a diagram illustrating a change example of the motor rotation speed and the current flowing through the motor when the front wheels of the riding lawn mower vehicle are in a slip state. In FIG. 3, the front wheels 11a and 11b begin to slip at time t1, and the slip state of the front wheels 11a and 11b is eliminated at time t2. As shown in FIG. 3, when the front wheels 11a and 11b begin to slip, the rotational speed of the front wheels 11a and 11b rapidly increases, and the rotational speed of the motor 41 also increases rapidly. For this reason, the first determination unit J1 causes the front wheels 11a and 11b to slip when a sudden increase in the rotational speed of the motor 41 occurs that exceeds the limit value (Δr) within a preset time Δt. It is determined that the state is present.

  Here, when the front wheels 11a and 11b are not in the slip state, the running resistance of the riding lawn mower 1 according to the speed, acceleration, posture, road surface resistance, and the like is generated. On the other hand, when the front wheels 11a and 11b are in the slip state, the front wheels 11a and 11b are idle, so that the running resistance is smaller than when the front wheels 11a and 11b are not in the slip state. In general, the current flowing through the motor 41 is the smallest when there is no load, and tends to increase as the load increases. Since the traveling resistance is a load for the motor 41, when the front wheels 11a and 11b are slipped, the traveling resistance is decreased and the current value of the current flowing through the motor is decreased as shown in FIG. For this reason, the second determination unit J2 determines that the front wheels 11a and 11b are in the slip state when the current value of the current flowing through the motor 41 is equal to or less than the maximum drive current value.

  The minimum drive current value calculation unit 38 b calculates the minimum drive current value using the detection results of the speed sensor 36 and the 3D gyro sensor 37. Specifically, the running resistance is obtained from the speed of the riding lawn mower 1 detected by the speed sensor 36, the attitude and acceleration of the riding lawn mower 1 detected by the 3D gyro sensor 37, and the road resistance. The minimum drive current value is calculated from the running resistance and the detection result of the motor rotation speed sensor Q1.

  Here, the running resistance includes air resistance, rolling resistance, gradient resistance, and acceleration resistance. The air resistance refers to a resistance generated by friction between the riding lawn mowing vehicle 1 and air, and is a resistance that increases in proportion to the square of the vehicle speed. The rolling resistance refers to resistance generated when the front wheels 11 a and 11 b and the rear wheel 12 are in contact with the road surface, and is resistance proportional to the weight of the riding lawn mowing vehicle 1. Gradient resistance refers to resistance that occurs during climbing, and is proportional to the sine value of the total weight of the riding lawn mowing vehicle 1 and the gradient angle. The acceleration resistance refers to resistance generated when accelerating and is proportional to the acceleration and the weight of the riding lawn mowing vehicle 1.

  The minimum drive current value calculation unit 38b obtains the air resistance using the detection result of the speed sensor 36, and obtains the rolling resistance using the road surface resistance. Further, the gradient resistance and the acceleration resistance are obtained using the detection result of the 3D gyro sensor 37. The minimum drive current value calculation unit 38b adds the air resistance, rolling resistance, gradient resistance, and acceleration resistance to obtain a running resistance, and the minimum driving current is calculated from the running resistance and the detection result of the motor rotation speed sensor Q1. Calculate the value.

  Here, the road surface resistance changes variously according to the road surface on which the riding lawn mowing vehicle 1 travels, and the road surface resistance of the road surface on which the riding lawn mowing vehicle 1 actually travels is sequentially detected. It is difficult. Since the riding-type lawn mowing vehicle 1 of the present embodiment is mainly intended to prevent turf damage, when calculating the above-mentioned running resistance, for example, an average obtained when running on the lawn in advance. A typical road resistance may be used. Alternatively, the road surface condition may be selected according to the operator's instruction, and the road surface resistance in the road surface condition selected by the worker may be used.

  The motor control unit 38 c controls the motor 41 according to the operation amount of the reverse accelerator pedal 17 and the forward accelerator pedal 18. However, when the slip state determination unit 38a determines that the front wheels 11a and 12b are in the slip state, control is performed to reduce the torque of the motor 41. Specifically, the AC motor driver 32 is controlled to stop the torque of the motor 41 intermittently. That is, when the front wheels 11a and 11b are in a slip state, the torque of the motor 41 is intermittently weakened (or made zero), thereby reducing the rotational speed of the front wheels 11a and 11b and increasing the frictional resistance to the road surface. To prevent slip damage by quickly eliminating the slip condition.

  Next, a method for controlling the riding lawnmower vehicle 1 having the above configuration will be described. FIG. 4 is a flowchart illustrating a method for controlling a riding lawn mower according to an embodiment of the present invention. In the flowchart shown in FIG. 4, the key operation by the operator is performed after the key operation is performed by the operator who is seated on the seat 15 on the riding-type lawn mowing vehicle 1 and the riding-type lawn mowing vehicle 1 is started. It is executed at regular time intervals until the riding-type lawn mowing vehicle 1 is stopped.

  When the riding-type lawn mowing vehicle 1 is powered on and starts control, the control device 38 first acquires the rotational speed of the motor 41 from the motor rotational speed sensor Q1 (step S11: first step). Next, the first determination unit J1 of the slip state determination unit 38a provided in the control device 38 obtains a difference between the rotation speed of the motor 41 acquired last time by the control device 38 and the rotation speed of the motor 41 acquired this time. The rate of change in the rotational speed of the motor 41 is calculated (step S12). And the 1st determination part J1 determines whether the change rate of the rotation speed calculated by step S12 is more than the preset limit value ((DELTA) r in FIG. 3) (step S13: 3rd step) ).

In parallel with the processes in steps S11 to S13 described above, the minimum drive current value calculation unit 38b provided in the control device 38 acquires the vehicle attitude and acceleration from the 3D gyro sensor 37 (steps S14 and S15). Then, the vehicle speed is acquired from the speed sensor 36 (step S16). Then, the minimum drive current value calculation unit 38b calculates the running resistance from the vehicle attitude and acceleration acquired from the 3D gyro sensor 37, the speed acquired from the speed sensor 36, and the road surface resistance (step S17). In addition, as above-mentioned, the average road surface resistance calculated | required when drive | working on the grass previously can be used for road surface resistance.

  Next, the minimum drive current value calculation unit 38b calculates the minimum drive current value from the rotational speed of the motor 41 acquired by the control device 38 in step S11 and the running resistance calculated in step S17 (step S18). Thereby, the minimum drive current value which is the minimum value of the current that should flow to the motor 41 according to the traveling state of the riding lawnmower vehicle 1 is obtained. Note that the minimum drive current value is larger when, for example, the riding lawnmower vehicle 1 is climbing uphill at the same constant speed than when traveling on a flat ground at a constant speed.

  In parallel with the above-described processing (steps S14 to S18) of the minimum drive current value calculation unit 38b, the second determination unit J2 of the slip state determination unit 38a provided in the control device 38 receives the motor current sensor Q2 to the motor. The current value (motor drive current value) of the current flowing through 41 is acquired (step S19: second step). Then, the second determination unit J2 compares the minimum drive current value calculated by the minimum drive current value calculation unit 38b with the motor drive current value acquired in step S19 (step S20), and the motor drive current value is the lowest drive. It is determined whether or not it is equal to or less than the current value (step S21: third step).

  Here, when it is determined in step S13 described above that the rate of change in the rotational speed is greater than or equal to the limit value (Δr in FIG. 3) (when the determination result is “YES”), or in step S21, the motor drive current When it is determined that the value is equal to or less than the minimum drive current value (when the determination result is “YES”), the motor control unit 38 c performs control to reduce the torque of the motor 41. Specifically, the motor control unit 38c controls the AC motor driver 32 to intermittently stop the torque of the motor 41 (step S22: fourth step).

  That is, when the slip state determination unit 38a determines that the front wheels 11a and 11b are in the slip state, the motor control unit 38c performs control to intermittently weaken (or zero) the torque of the motor 41. Yes. By performing such control, the rotational speed of the front wheels 11a, 11b is reduced, the frictional resistance against the road surface is increased, and the slip state is quickly eliminated. When it is determined that the front wheels 11a and 11b are not in the slip state (when the determination result of steps S13 and S21 is “NO”), step S22 is omitted.

  As described above, in the present embodiment, it is determined whether or not the front wheels 11a and 11b are in the slip state based on the detection result of the motor rotation speed sensor Q1 or the detection result of the motor current sensor Q2. If it is determined that there is, control is performed to reduce the torque of the motor 41. For this reason, the slip state of the front wheels 11a and 11b is quickly eliminated, and as a result, damage to the turf can be prevented.

  As mentioned above, although the riding-type lawn mower vehicle and its control method by one Embodiment of this invention were demonstrated, this invention is not restrict | limited to the said embodiment, It can change freely within the scope of the present invention. For example, in the above-described embodiment, the rate of change of the rotation speed of the motor 41 detected by the motor rotation speed sensor Q1 is equal to or higher than a preset limit value, or the current detected by the motor current sensor Q2 is the lowest drive. It has been determined whether or not a slip state has been reached depending on whether or not the current value has been reached. However, when both of these are established, it may be determined that the front wheels 11a and 11b are in a slip state.

  In the above-described embodiment, an electric riding lawn mowing vehicle that travels using the power generated by the motor and cuts the lawn using the power generated by the motor has been described as an example. However, the present invention includes an engine and a motor as power generation sources, and can also be applied to a hybrid riding lawn mower vehicle that travels using power generated by these power generation sources. .

DESCRIPTION OF SYMBOLS 1 Riding lawn mower vehicle 11a, 11b Front wheel 36 Speed sensor 37 3D gyro sensor 38a Slip state determination part 38b Minimum drive current value calculation part 38c Motor control part 41 Motor J1 1st determination part J2 2nd determination part Q1 Motor rotation speed sensor Q2 Motor current sensor

Claims (4)

In a riding-type lawn mower vehicle equipped with a motor that generates a driving force for rotating wheels,
A first sensor for detecting the rotational speed of the motor;
A second sensor for detecting a current value of a current flowing through the motor;
A determination unit that determines whether or not the wheel is in a slip state based on a detection result of at least one of the first and second sensors;
Every time the wheel is Ru is determined by the determination unit that the slip state, weakening the torque of the motor intermittently, or intermittently riding, characterized in that it comprises a control unit for controlling to zero Lawn mowing vehicle. The determination unit is configured to determine that the wheel is in a slip state when a change rate of a detection result of the first sensor is equal to or greater than a preset limit value;
When the current value detected by the second sensor is equal to or less than the minimum drive current value that is the minimum value of the current that should flow to the motor according to the running state of the vehicle, the wheel is judged to be in the slip state. The riding lawn mowing vehicle according to claim 1, further comprising: 2 determination unit. A speed sensor for detecting the speed of the vehicle;
An attitude sensor for detecting the attitude of the vehicle;
Air resistance is obtained using the detection result of the speed sensor , gradient resistance and acceleration resistance are obtained using the detection result of the attitude sensor, rolling resistance is obtained using road resistance, the air resistance, the gradient resistance, 3. A calculation unit that obtains a running resistance by adding an acceleration resistance and the rolling resistance, and calculates the minimum driving current value from the running resistance and a detection result of the first sensor. The described riding lawn mower vehicle. A method for controlling a riding lawnmower vehicle including a motor that generates a driving force for rotating wheels,
A first step of detecting the rotational speed of the motor;
A second step of detecting a current value of a current flowing through the motor;
A third step of determining whether or not the wheel is in a slip state based on a detection result of at least one of the first and second steps;
Every time the wheel is Ru is determined by the third step to be slip state, and having a fourth step of performing intermittently weakened, or intermittently controlled to zero torque of the motor Control method for riding lawn mower.

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