JP2023092324A - Grass mower - Google Patents

Abstract

To provide a grass mower capable of travelling on a slope surface while mowing grass, while suppressing an engine stall.SOLUTION: A grass mower includes: an engine control unit 51 for driving an engine at a predetermined speed; an engine speed detection unit for detecting an engine speed; a travelling device having a left travelling unit and a right travelling unit; a transmission having a left transmission for shifting power from the engine and transmitting the power to the left travelling unit and a right transmission for transmitting the power to the right travelling unit on the basis of operation of a speed change operation tool; a speed change control unit 60 for adjusting a speed change ratio of the transmission; and an anti-stall unit 65 for outputting, to the speed change control unit, a load reduction command for adjusting the speed change ratio so as to reduce an engine load in response to decrease in the engine speed due to the engine load.SELECTED DRAWING: Figure 7

Description

The present invention relates to a lawn mower capable of running on a slope.

In the vehicle according to Patent Document 1, the degree of partial load is calculated based on the correlation between the amount of engine speed drop from the reference speed and the torque change, and the engine load factor obtained from the degree of partial load and the degree of maximum load. Based on this, the driver is notified of a request for engine speed adjustment, work device speed adjustment, traveling gear stage adjustment, and the like.

Patent Literature 2 discloses a lawn mower capable of running on a slope. This lawn mower includes an engine, wheels, a lawn mower, and a control unit in its body, and is capable of automatic and manual travel. In manual driving, the mower is operated using a remote control.

Patent Literature 3 discloses an electric lawn mower that is restrained from shifting to the lower side of the slope when traveling across the slope. The control unit that controls the left motor that drives the left rear wheel and the right motor that drives the right rear wheel of this electric lawn mower has a compensating torque that eliminates the downward movement of the slope that occurs during crossing. is calculated and added to the torque required for normal running.

JP 2011-144735 A JP 2019-016942 A JP 2013-001229 A

When mowing on the slope of a field, the slope slope becomes steeper and the height and density of the grass growing on the slope suddenly change. It often grows rapidly. Therefore, if the engine load is not reduced instantaneously, the engine stalls. As shown in Patent Document 1, it is difficult to properly prevent engine stall by a method in which a driver receives information for proper driving from a control unit and takes some kind of prescription.

Patent Literature 2 discloses a mowing machine that cuts grass while traveling on a slope, but does not disclose travel control that takes into consideration the engine load of the mower. Patent Document 3 discloses a running control for smooth running on a slope, but since it is an electric lawn mower whose wheels are driven by an electric motor, it is not applicable to running control considering the engine load. Have difficulty.

In view of the above circumstances, an object of the present invention is to provide a lawn mower that can cut grass on a slope while suppressing engine stall.

A lawn mower capable of traveling on a slope according to the present invention includes a machine body, an engine, an engine control unit for driving the engine at a predetermined number of revolutions, an engine speed detection section for detecting the number of revolutions of the engine, a traveling device having a left traveling unit and a right traveling unit; a left transmission that shifts power from the engine and transmits it to the left traveling unit based on operation of a gear shift operation device; and operation of the gear shift operation device. a transmission having a right speed change device for transmitting power from the engine to the right traveling unit according to a speed change, a speed change control unit for adjusting the speed change ratio of the transmission, and a speed change control unit that responds to a decrease in engine speed due to an engine load. and an anti-stall unit that outputs a load reduction command for adjusting the gear ratio so as to reduce the engine load to the shift control unit.

According to this configuration, when the engine load suddenly increases due to driving on a slope with a large slope or a slope with high grass and high density, the driver reduces the vehicle speed. The gear ratios of the left and right transmissions for the left and right travel units are adjusted so that the engine load is reduced without any operation to cause the left and right travel units to be driven. As a result, the vehicle speed is reduced, the engine load is reduced, and engine stall is suppressed.

In one preferred embodiment of the present invention, the anti-stall section calculates the adjustment amount of the gear ratio in accordance with the degree of decrease in the engine speed. Even if the engine load increases and the engine speed drops sharply from the set predetermined speed, this configuration increases the gear ratio adjustment amount as the engine speed decreases. Engine stall is suppressed.

The greater the inclination of the slope and the greater the inclination of the fuselage, the greater the engine load. Therefore, in one of the preferred embodiments of the present invention, an inclination determination section for determining the inclination of the aircraft is provided, and the anti-stall section adjusts the gear ratio based on the inclination. Calculate quantity. In this configuration, based on the determination result of the tilt attitude determination unit, the greater the inclination of the aircraft in the tilt attitude that greatly affects the engine load, the greater the adjustment amount of the gear ratio can be, so the engine stall is suppressed. be done.

In one preferred embodiment of the present invention, an anti-stall management section is provided for prohibiting the output of the load reduction command by the anti-stall section. With this configuration, the anti-stall management section can prohibit the output of the load reduction command by the anti-stall section according to the traveling state of the aircraft. For example, when the vehicle speed or the engine speed is adjusted according to the driver's intention, it is possible to prohibit the output of the load reduction command.

In one preferred embodiment of the present invention, the anti-stall management section prohibits the output of the load reduction command when the speed change operation tool is operated to the fastest position. When the driver deems the anti-stall control unnecessary and operates the speed change operation tool to the fastest position, the anti-stall control by the anti-stall management unit is stopped and the output of the load reduction command is prohibited. In other words, the shift operation tool can function as an ON/OFF switch for antistall control.

It is a right side view of a lawn mower. It is a top view of a lawn mower. Fig. 2 is a plan view showing the power transmission system of the lawn mower; FIG. 4 is a schematic diagram showing various running situations of the mower on a slope using a remote controller; It is a front view of a remote control. FIG. 3 is a functional block diagram showing a control system of the lawn mower; It is a functional block diagram showing each functional part in a control unit.

1 and 2 show a remote controlled lawn mower. 1 and 2, "F" indicates the forward direction with respect to the longitudinal direction of the aircraft (running direction), "B" indicates the rearward direction, and in FIG. 1, "U" indicates the vertical direction of the aircraft. ) indicates the upward direction, "D" indicates the downward direction, and in FIG. 2, "R" indicates the right direction with respect to the transverse direction of the fuselage (body width direction) perpendicular to the longitudinal direction of the fuselage, and "L" indicates the left direction. is shown.

[Overall configuration of lawn mower]
As shown in FIGS. 1 and 2, the lawn mower includes a body 1, a crawler-type traveling device 2 consisting of a left traveling unit 2a and a right traveling unit 2b for supporting the body 1 on the ground, and a a supported mowing device 3;

The fuselage 1 is constructed like a ladder frame and has right and left support frames connected by cross frames.

[Configuration of traveling device]
As shown in FIGS. 1 and 2, the left traveling unit 2a and the right traveling unit 2b each include a driving wheel 10, a plurality of rollers 11, a guide wheel 12, a track frame 13, a guide member, and a crawler. belt 14; A track frame 13 is arranged along the front-rear direction, a plurality of rollers 11 are supported on the track frame 13 , and a guide wheel 12 is supported on the rear portion of the track frame 13 . Right and left drive wheels 10 are supported by transmission 20 . The right drive wheel 10 is arranged above the front-rear intermediate portion of the right track frame 13 in side view, and the left drive wheel 10 is arranged above the front-rear intermediate portion of the left track frame 13 in side view. are placed in

As shown in FIG. 2, the aircraft 1 is equipped with an engine 4 and a transmission 20 . An output shaft 4a of the engine 4 and an input shaft 23 of the transmission 20 are connected. As shown in FIGS. 2 and 3, a PTO shaft 24 extends from the front portion of the transmission 20 in the longitudinal direction of the vehicle body. The PTO shaft 24 transmits power to the mower 3 .

As shown in FIG. 3, the transmission 20 includes a left transmission that transmits gear shifting power to the left traveling unit 2a and a right transmission that transmits gear shifting power to the right traveling unit 2b. The output shaft of the left transmission is connected to the axle 10a of the driving wheel 10 of the left traveling unit 2a, and the output shaft of the right transmission is connected to the axle 10a of the driving wheel 10 of the right traveling unit 2b. Since the left transmission and the right transmission are composed of HSTs (hydrostatic transmissions), the left transmission is hereinafter referred to as the left HST 21 and the right transmission is referred to as the right HST 22 . However, the left and right transmissions are not only composed of HSTs, but also have gear transmission mechanisms. Further, the left HST 21 and right HST 22 may be omitted by configuring this gear transmission mechanism with a clutch-switching gear transmission mechanism, or both the left HST 21 and right HST 22 and the clutch-switching gear transmission mechanism may be used. may be

[Configuration of lawn mower]
As shown in FIG. 2, the mowing device 3 includes a mowing body 40 having a rotatably driven cutting blade 41, and a grounded and slidable mowing body 40 that is lifted from the ground to a predetermined height and supported. A pair of left and right ground supports 30 are provided.

The reaping main body 40 is configured as a fuller mower type in which a rotary drum 42 supporting a large number of reaping blades 41 is rotationally driven about an axis extending in the left-right direction. In other words, a rotary cutting blade is constructed in which the cutting blade 41 is provided on the outer periphery of the drive shaft. The rotary cutting blade (cutting blade 41 and rotary drum portion 42 ) is housed in a cutting blade housing 43 .

The cutting main body 40 is provided with a transmission section 44 that transmits the power input to the grass cutting device 3 to the rotating drum section 42 . The transmission portion 44 includes an input transmission case portion 45 that receives power input from the machine body 1 and a belt transmission mechanism 46 that transmits the power input from the input transmission case portion 45 to the rotating drum portion 42 .

As shown in FIGS. 1 and 2 , longitudinal right and left brackets 35 are connected to the left and right support frames of the fuselage 1 . The right and left support arms 31 are supported by the lower part of the bracket 35 so as to be vertically swingable about an axis P1 extending in the left-right direction, and extend forward.

Right and left elevating cylinders 33 capable of swinging the support arm 31 up and down are connected across the upper part of the bracket 35 and the support arm 31, and the elevating cylinders 33 are connected to the support frame via the bracket 35. It is

[Running form on slope]
FIG. 4 shows the mowing machine described above performing mowing work on a slope formed around a field. Here, the lawn mower is controlled by a wireless control remote controller 9 . In Fig. 4, the mower's running modes are contour line running along the contour lines of the slope, U-turn running connecting the contour lines, vertical climbing running vertically up the slope (uphill running), and slope running. A vertical descent run is shown vertically down the .

[pilot remote control]
As shown in FIG. 5, the operation remote controller 9 includes a shift operation tool 91 for adjusting forward speed including neutral and reverse speed, a turn operation tool 92 for selecting left turn or right turn, and a travel mode selection. A driving mode selection switch 93 is provided. The shift operation tool 91 can be displaced between a forward position, a neutral position, and a reverse position, and the turning operation tool 92 can be displaced between a left turning position, a neutral position (straight ahead position), and a right turning position. is. If a joystick type operation tool is used, it is possible to instruct the mower to move forward and backward and to turn left and right with a single joystick. The running mode selection switch 93 sets ON/OFF of each running mode (an anti-stall running mode, a contour line assist running mode, a stick running mode, etc.), which will be described later. The operation remote controller 9 is also provided with other operation tools (regulation of the engine speed, start/stop of the engine 4, etc.) related to operation, but they are omitted in FIG.

[Control system]
6 and 7 are functional block diagrams showing functional units constituting the control system of the lawn mower and data flow between the functional units. This control system includes a control unit 100 that controls various operations of the mower, an operation remote controller 9 that can be wirelessly connected to the control unit 100, and a wired connection (in-vehicle LAN, etc.) to the control unit 100. An attitude detection unit 8 is included.

The posture detection unit 8 includes an IMU (Inertial Measurement Unit) 81, which includes an acceleration sensor, a rotational angular acceleration sensor, a gyro sensor, a magnetic field sensor, and the like. The attitude detection unit 8 calculates the roll angle, pitch angle, yaw angle, etc. of the aircraft 1 and sends them to the control unit 100 as attitude detection data.

A control unit 100 substantially configured as a computer unit is connected to an engine adjustment mechanism 4A for adjusting the engine speed, accessories of the engine 4, a transmission 20, and the mower 3 in order to control the mower. there is The control unit 100 sends engine control signals to the engine adjuster 4A and the engine 4 accessories. Also, the engine speed is detected by a speed sensor 82 functioning as an engine speed detection section and sent to the control unit 100 .

The control unit 100 is connected to various operating devices and various sensors attached to the transmission 20 in order to control travel. For example, control unit 100 sends shift control signals to transmission 20 to swashplate actuators that change the swashplate angle of left HST 21 and right HST 22 . By this shift control signal, the gear ratio of the transmission 20, that is, the gear ratio of the left HST 21 and the right HST 22 is adjusted, and as a result, the machine body 1 can move forward, neutral (stationary), reverse, or turn. changed to The vehicle speed in the forward state, reverse state, and turning state is also determined by the shift control signal. A ground speed sensor 83 is provided for detecting the ground speed of the left traveling unit 2a and the ground speed of the right traveling unit 2b, and detects data related to the ground speed. The detected ground speed data is sent to control unit 100 . For example, the ground speed can be calculated from the rotation speed of the axle 10a of the drive wheel 10. In that case, the ground speed sensor 83 also functions as an output speed sensor for the left traveling unit 2a and the right traveling unit 2b. . It is also possible to calculate ground speed using a camera.

FIG. 7 shows a functional block diagram showing functional parts of the control unit 100. As shown in FIG. The control unit 100 includes an engine control unit 51 , a work control unit 52 , a travel control unit 6 , a traveling body posture determination unit 7 , a ground speed calculation section 74 and a body movement detection section 75 .

The engine control unit 51 generates an engine control command based on the execution result of the engine control program stored therein, the control command from the control remote control 9, and the command generated by the functional unit of the control unit 100, and the engine It is sent to the adjustment mechanism 4A and accessories of the engine 4. The engine control command is used to start or stop the engine 4, increase or decrease the engine speed, and the like.

The work control unit 52 also generates a work control command based on the execution result of the work control program stored therein, the operation command from the operation remote controller 9, and the command generated by the functional part of the control unit 100, and mowing. Send to device 3. The mowing device 3 is started and stopped, and the mowing device 3 is raised and lowered according to the work control command.

The traveling body posture determination unit 7 determines various posture states of the body 1 based on the posture detection data from the posture detection unit 8 . In this embodiment, the traveling body attitude determination unit 7 includes an inclination angle calculation section 71 , an inclination attitude determination section 72 and a running state determination section 73 . The inclination angle calculator 71 calculates the inclination angle of the airframe 1 with respect to the contour line of the slope from the yaw angle, the pitch angle, and the like. The tilted posture determination unit 72 determines the tilted posture of the airframe 1 . This tilt attitude indicates the tilt angle of the airframe 1, which is strongly related to the shear motion acting on the airframe 1 on the slope due to gravity, and can be obtained from the roll angle, pitch angle, yaw angle, magnetic azimuth angle, or the like. can be done. The running state determination unit 73 determines whether the machine body 1 running on a slope is in a straight running state, an unstable straight running state deviated from the straight running state, or a turning running state. This driving state can be determined substantially by monitoring the yaw angle over time.

Various data generated by the traveling body posture determination unit 7 are used for travel control. For example, in the anti-stall running mode, the tilted posture determined by the tilted posture determination unit 72 is used. Then, the tilted posture determined by the tilted posture determination unit 72 is used.

The ground speed calculator 74 calculates the ground speed of the traveling device 2 . In this embodiment, the ground speed calculator 74 calculates the ground speed of the left traveling unit 2a and the right traveling unit 2b based on the detection value from the ground speed sensor 83 that detects the ground speed of the left traveling unit 2a and the right traveling unit 2b. The speed is calculated, and the ground speed of the traveling device 2 is calculated.

The body movement detection section 75 cooperates with the ground speed calculation section 74 and detects the movement of the body 1 based on the ground speed monitoring of the left traveling unit 2a and the right traveling unit 2b.

The travel control unit 6 has a function of controlling travel of the body 1 . In this embodiment, the travel control unit 6 includes a shift control section 60 , an antistall section 65 , an antistall management section 66 and a travel mode management section 67 .

The shift control unit 60 includes a left shift signal generation unit 61 , a right shift signal generation unit 62 , a contour line assist unit 63 , and a stick shift unit 64 . The left shift signal generator 61 generates a left shift signal that adjusts the gear ratio (swash plate angle) of the left HST 21, and the right shift signal generator 62 adjusts the gear ratio (swash plate angle) of the right HST 22. Generate a shift signal.

(Contour assist driving mode)
The contour line assist section 63 operates in the contour line assist travel mode, cooperates with the inclination angle calculation section 71 and the travel state determination section 73, and assists the machine body 1 to travel straight along the contour lines of the slope. Specifically, the contour line assist unit 63 does not perform assistance in a straight running state in which the inclination angle of the aircraft body 1 with respect to the contour lines of the slope is within a predetermined range, but does not perform assistance when the inclination angle of the aircraft body 1 with respect to the contour lines is within a predetermined range. When the range is exceeded and an unstable straight running state occurs, the inclination angle of the fuselage 1 with respect to the contour line is reduced, and the amount of adjustment of the gear ratios of the left HST 21 and the right HST 22 necessary for the inclination angle to fall within a predetermined range is determined by the fuselage. It is calculated based on the tilt angle of 1. Further, the contour line assist section 63 gives an adjustment command including this adjustment amount to the left shift signal generation section 61 and the right shift signal generation section 62 . By this adjustment, the machine body 1 returns from the unstable straight-running state to the straight-running state. In practice, when the machine body 1 runs along the contour line of the slope, the machine body 1 tilts toward the valley side. By reducing the rotation speed of the transmission (right HST 22 or left HST 21) for the running unit on the mountain side based on the rotation speed of (left HST 21 or right HST 22), the machine body 1 is assisted to face the mountain side.

If the slope is more slippery than usual, and if the contour line assist control (straight line holding function) by the contour line assist section 63 does not eliminate the unstable straight running state, the assist amount needs to be increased. For this reason, the running state determination unit 73 determines that the unstable straight running state in which the deflection is in the same direction for a predetermined time is the peculiar unstable straight running state. When the peculiar unstable straight running state is determined, the contour line assist section 63 adjusts the gear ratio of the left HST 21 and the gear ratio of the right HST 22 so that the speed of the traveling unit on the valley side becomes faster than the speed of the traveling unit on the mountain side. and increase the difference.

The contour line assist control described above may cause unnecessary turning when driving along the diagonal of the slope, especially when driving up or down at an angle perpendicular to the contour line of the slope. . Therefore, when the traveling state determination unit 73 determines that the machine body 1 is traveling in an uphill traveling state (including a downhill traveling state) in which the machine body 1 travels in a direction orthogonal to contour lines, the contour line assisting unit 63 performs contour line assist control (straight traveling). hold function).

(Standing driving mode)
The stick shift part 64 is a functional part that realizes a stick shift function, operates in a stick run mode, and when the vehicle stops on a slope or starts at a slow speed from a stop on a slope, the machine body 1 unexpectedly moves to the valley side. This is prevented by using the driving force of the travel device 2 . In other words, the hold speed change section 64 detects the displacement of the machine body 1 on the slope detected by the machine body movement detection section 75 when the swash plate angle between the left HST 21 and the right HST 22 is substantially at the neutral position. In order to stop the vehicle, the left traveling unit 2a and the right traveling unit 2b are brought into a driving state. That is, the swash plate angles of the left HST 21 and the right HST 22 are adjusted by driving the left traveling unit 2a and the right traveling unit 2b so as to prevent this deviation. More specifically, although the left HST 21 and the right HST 22 are operated to the stop gear shift position by the operator's operation, the body motion detector 75 detects that the body 1 is moving on the slope. When detected, the hold shift unit 64 displaces the shift positions of the left HST 21 and the right HST 22 from the stop shift position toward the maximum forward position or toward the maximum reverse position until the movement of the machine body 1 disappears. The shift position where the movement of the machine body 1 disappears is the hold shift position. Since the stop shift position is substantially the neutral position of the HST, the stick shift section 64 performs the stick hold control with the neutral position as the stop shift position. However, on a slope with a large inclination angle or on a slippery slope covered with grass, the stop shift position, which is the reference shift position for the sticking control, deviates from the neutral position. In order to cope with such a case, it is also possible to set the stop shift position according to the tilted posture of the machine body 1 determined by the tilted posture determination section 72 and other states of the lawn mower.

As an optional function, the hold-down shift portion 64 has a function that, when the hold-down shift position is changed to the forward position or the reverse position based on the operation of the shift operation tool 91, the shift amount according to the shift position by the operation is changed to the shift amount according to the hold-down shift position. A shift amount addition function is provided to add the shift amount. This is because the hold shift position is a shift position to which a predetermined shift amount (offset amount) is added from the stop shift position in a controlled manner. If the shift position is changed to the shift position of , there is a possibility that the machine body 1 will shift unexpectedly. In order to avoid this, when the shift position operated by the operator is below the sustained shift position, the shift amount addition function automatically maintains the shift position equal to or higher than the sustained shift position. When the shift position operated by the operator exceeds the holding shift position, the shift amount addition function is stopped. Further, when the tilted attitude of the machine body 1 determined by the tilted attitude determination unit 72 becomes equal to or less than a predetermined level at which no deviation movement occurs, the shift amount adding function is automatically stopped.

(Anti-stall driving mode)
The anti-stall section 65 operates in the anti-stall running mode, and is linked to the engine control unit 51 and the inclination determination section 72 so that the machine body 1 can run along the contour lines of the slope without the engine 4 stalling. to assist. The anti-stall unit 65 instructs the shift control unit 60 to reduce the engine load when the number of rotations of the engine 4 drops below a predetermined number of rotations set by a throttle adjuster (not shown) or the like due to the engine load. and output a load reduction command for adjusting the gear ratio (swash plate angle) of the right HST 22 to the gear shift control unit 60 to reduce the vehicle speed.

The anti-stall unit 65 includes a transmission ratio adjustment amount calculation unit 651 that calculates the adjustment amount of the transmission ratio according to the running state of the machine body 1 . The greater the degree of decrease in engine speed, the greater the engine load and the higher the possibility of engine stall. Enlarge. Further, the greater the inclination of the slope and the greater the inclination of the fuselage 1, the greater the engine load. Therefore, based on the determination result of the tilting attitude determination unit 72 that determines the tilting attitude of the machine body 1, the parameters of the antistall control (the engine speed at which the antistall control is started and the gain constant in the HST swash plate angle control circuit) are changed. Be changed. For example, the gear ratio adjustment amount calculation unit 651 increases the adjustment amount of the gear ratio based on the determination result of the tilt attitude determination unit 72 as the tilt attitude of the machine body 1 greatly affects the engine load. do.

The antistall management unit 66 prohibits the output of the load reduction command by the antistall unit 65 according to the running state of the machine body 1 . When the vehicle speed or engine speed is adjusted by the driver's intention, the output of the load reduction command is prohibited. Further, when the operator deems that the anti-stall control is unnecessary and operates the speed change operation tool 91 to the fastest position, the anti-stall control by the anti-stall management unit 66 is stopped and the output of the load reduction command is prohibited. In other words, the shift operation tool 91 functions as an ON/OFF switch for anti-stall control.

The running mode management unit 67 sets an anti-stall running mode, a contour line assist running mode, and a stick running mode based on a running mode setting command from the steering remote controller 9 or a command generated by the function unit of the control unit 100, Also cancel the setting.

[Another embodiment]
(1) In the above-described embodiment, the mower was a front mower type in which the mowing device 3 was arranged in front of the machine body 1. type may be used. Furthermore, any type such as a blade type or a reel type may be employed for the grass cutting device 3 as well.

(2) In the above-described embodiment, the traveling device 2 was of the crawler type, but instead of this, a wheel type may be adopted, or a type combining a crawler and a wheel may be adopted.

(3) In the above-described embodiments, HSTs are used for the left transmission and the right transmission. may be used.

(4) The functional units in the functional block diagrams of FIGS. 6 and 7 are for the purpose of explanation, and can be freely integrated or divided. Also, the control unit 100 may be divided into a plurality of units connected by an in-vehicle LAN. The traveling body posture determination unit 7 may be incorporated in the posture detection unit 8 . Furthermore, although the attitude detection unit 8 has been mounted on the mower, it may be arranged outside the mower, detect the attitude of the machine body 1 using a camera or laser, and transmit the detected attitude data to the mower. can be

(5) In the above-described embodiment, the aircraft 1 is operated by the wireless remote controller 9, but a wired remote controller 9 may be used. Alternatively, the administrator may operate using a control device provided on the aircraft 1 instead of using the control remote controller 9 .

It should be noted that the configurations disclosed in the above embodiments (including other embodiments, the same shall apply hereinafter) can be applied in combination with configurations disclosed in other embodiments as long as there is no contradiction. The embodiments disclosed in this specification are exemplifications, and the embodiments of the present invention are not limited thereto, and can be modified as appropriate without departing from the object of the present invention.

INDUSTRIAL APPLICABILITY The present invention is applied to a lawn mower capable of traveling on a slope.

1: Machine body 2: Travel device 2a: Left travel unit 2b: Right travel unit 3: Lawn mower 4: Engine 20: Transmission 21: Left HST (left transmission)
22: Right HST (right transmission)
51 : Engine control unit 63 : Contour line assist unit 64 : Tension shift unit 65 : Anti-stall unit 66 : Anti-stall management unit 67 : Running mode management unit 7 : Traveling body attitude determination unit 71 : Inclination angle calculation unit 72 : Inclination attitude determination Unit 73 : Driving state determination unit 74 : Ground speed calculation unit 75 : Aircraft movement detection unit 8 : Attitude detection unit 82 : Rotation speed sensor (engine speed detection unit)
83: Ground speed sensor 9: Control remote control 91: Shift operation tool 100: Control unit

Claims (5)

A lawn mower capable of running on a slope,
Airframe and
engine and
an engine control unit that drives the engine at a predetermined number of revolutions;
an engine speed detection unit that detects the speed of the engine;
a traveling device having a left traveling unit and a right traveling unit;
A left transmission that shifts the power from the engine based on the operation of the shift operation tool and transmits it to the left traveling unit, and a shift of the power from the engine based on the operation of the shift operation tool for the right travel. a transmission having a right transmission that communicates with the unit;
a shift control unit that adjusts the gear ratio of the transmission;
an anti-stall unit that responds to a decrease in engine speed due to an engine load and outputs a load reduction command for adjusting the gear ratio to reduce the engine load, to the shift control unit;
lawn mower with. 2. The lawn mower according to claim 1, wherein the anti-stall unit calculates the amount of adjustment of the gear ratio according to the degree of reduction in the rotational speed of the engine. A tilt attitude determination unit that determines the tilt attitude of the airframe is provided,
The lawn mower according to claim 1 or 2, wherein the anti-stall section calculates the amount of adjustment of the gear ratio based on the tilted posture. The lawn mower according to any one of claims 1 to 3, further comprising an antistall management unit that prohibits output of the load reduction command by the antistall unit. 5. The lawn mower according to claim 4, wherein the anti-stall management section prohibits the output of the load reduction command when the speed change operation tool is operated to the fastest position.

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