CN114451150B - Emergency stop control method for hybrid mower - Google Patents

Abstract

The invention discloses a method for controlling the emergency stop of a hybrid mower, wherein when the hybrid mower receives an emergency stop signal of a remote control device, a brake control part arranged on the hybrid mower executes an emergency stop command of the hybrid mower; the brake control part comprises a driving part, the driving part comprises a push rod used for contacting and pushing the manual control device, the driving part drives the manual control device to move through the push rod, so that the manual control device moves to a position where the brake device is started, and the control method comprises the following steps: A. the hybrid mower is started to enter initialization, and the driving piece controls the push rod to return to an initial position S0; B. the driving piece controls the push rod to move to the S1 position, and at the moment, the end part of the push rod just contacts the manual control device; C. when the hybrid mower receives the scram signal transmitted by the remote control device, the driving piece controls the push rod to move from the S1 position to the S2 position, and the scram operation is completed.

Description

Emergency stop control method for hybrid mower

Technical Field

The invention relates to a remote control emergency stop control method of remote control equipment, in particular to an emergency stop control method of a hybrid mower.

Background

The power part of the hybrid mowing robot consists of a gasoline engine and a battery, wherein the gasoline engine not only provides the mechanical force required by a generator, but also is responsible for driving a mowing blade.

The gasoline engine is used as a power unit of the mowing element, has higher working efficiency, improves mowing effect, but also brings safety risks, such as mechanical damage of the gasoline engine to drive the blade. So the related safety standards all have requirements on the emergency stop time of the blade at present, and the requirements are generally within 3 seconds, and refer to the safety requirements of the lawn mower with the internal combustion engine as power for the GB/T38364.1-2019 garden machine. At present, most mowers mainly using gasoline engines as mowing elements are riding or hand-held mowers, control elements of emergency braking systems of the gasoline engines are directly arranged on control positions of the riding mowers or armrests of the hand-held mowers, and when accidents occur, a user can manually operate a braking handle or a rocking bar to realize emergency stop. In a remote control type or remote control mode mower, a sudden stop button and other elements are also usually arranged on a machine body, so that a user cannot easily perform sudden stop action when using the mower remotely. In addition, due to remote control, a certain delay exists when the machine executes a remote instruction, so that the time required for stopping the remote control machine can be prolonged, and the safety is reduced.

In the current hybrid mower, a sudden stop device is often directly arranged on the mower, and a user needs to approach the mower to operate when the sudden stop motion is performed. In general, the fuel engine itself has a braking system which is usually operated by a lever, when the machine is not operated, a user is required to toggle the lever to a specified starting position to start the fuel engine, when the lever is toggled to a stopping position, the fuel engine stops to achieve a braking effect, but in an emergency state, the braking system is not easy to operate quickly, some machines are operated quickly by adding other braking systems (such as electromagnetic clutches and the like), but the adding system increases the complexity of the machine, increases the volume of the machine to a certain extent, increases the cost and increases the fault risk. Meanwhile, when remote operation is needed, the machine braking time can be increased due to factors such as data transmission, circuit delay and the like.

Disclosure of Invention

Aiming at the technical problems, the invention provides a method for controlling the emergency stop of a hybrid mower, wherein the electric control delay t1 is a relatively fixed value after the machine is produced in mass (after hardware is shaped) and can be obtained through a detection means. The mechanical braking time t3 is actually determined by the structural design of the manual pull rod and the fixed stop block, and is also a fixed value, so the technical purpose of the invention is to reduce the push rod action time t2 as much as possible, and finally ensure that the whole braking time is controlled within 3 seconds.

In order to achieve the technical purpose, the invention adopts the following technical scheme:

a mixed mower scram control method, when the mixed mower receives the scram signal of the remote control device, a brake control part arranged on the mixed mower executes the mixed mower scram command;

the brake control part comprises a driving part, the driving part comprises a push rod used for contacting and pushing the manual control device, the driving part drives the manual control device to move through the push rod so as to enable the manual control device to move to a position where the brake device is started,

the control method comprises the following steps:

A. the hybrid mower is started to enter initialization, and the driving piece controls the push rod to return to an initial position S0;

B. the driving piece controls the push rod to move to the S1 position, and at the moment, the end part of the push rod just contacts the manual control device;

C. when the hybrid mower receives the scram signal transmitted by the remote control device, the driving piece controls the push rod to move from the S1 position to the S2 position, and the scram operation is completed.

In step B, the distance between the position S0 and the position S1 of the push rod is determined by calculating the distance between the position S1 and the position S0 of the manual control device, and the time t2 required for the push rod to travel from the position S0 to the position S1 is obtained in combination with the push rod running speed according to the distance, and the time t2 required for the push rod to travel from the position S0 to the position S1 is reached during the machine running.

In step B, the S1 position is calculated by pulse, comprising the following steps:

B1. setting an initial position of the end part of the push rod, namely a position S0 of the end part of the push rod in a completely retracted state of the push rod;

B2. through pulse calculation, when the pulse signal of the driving piece stops outputting, judging that the end part of the push rod is positioned at a position S0; when the push rod moves from the position S0 to the position S1, the end of the push rod reaches the position S1 by calculating the direction and the pulse number of the pulse signal of the driving piece.

In step B, the S1 position is determined by detecting the working parameters of the driving piece, and the method comprises the following steps:

B3. setting an initial position of the end part of the push rod, namely a position S0 of the end part of the push rod in a completely retracted state of the push rod;

B4. when the driver operating parameter jump is detected when the push rod starts to move from the position S0, it is determined that the push rod end has reached the position S1.

And B4, adding a position correction step, namely stopping driving the push rod to move by the driving piece when the jump of the working parameters of the driving piece is detected when the push rod starts to move from the position S0, starting the driving piece to drive the push rod to retreat by the retreating distance which is the correction distance, and judging that the push rod reaches the position S1 after the retreating is finished.

6. The method for controlling the emergency stop of a hybrid mower according to claim 5, wherein,

the correction distance is the product of the electronic delay and the push rod running speed.

The working parameter is one or more of working voltage, working current, working load, working power and pressure indication of the driving piece.

The operating parameter jump is an increase in operating parameter to more than 110% of the operating parameter under the unloaded condition of the drive member.

The manual control device is connected to the mower body, and is connected with the braking device through a connecting piece, and the manual control device controls whether the braking device operates or not through physical displacement.

The brake control section further includes:

the track component is used for limiting a displacement path of the manual control device and comprises a starting gear, a stopping gear and a track groove for connecting the starting gear and the stopping gear, wherein a limiting blocking part for limiting the position of the manual control device is arranged on the starting gear, and the manual control device can be limited in the starting gear;

a reset part which always provides potential energy for the manual control device to run from the starting gear to the stopping gear;

when the manual control device is positioned at the starting gear position, the braking device stops,

when the manual control device is positioned at the stop gear position, the braking device is started to stop the operation of the power output device or cut off the energy supply of the power output device.

The beneficial effects are that:

the invention improves the structure of the emergency stop mechanism on the basis of the traditional hybrid mower, can finish emergency braking by utilizing the braking system of the fuel engine, does not need to add other braking devices, and has the advantage of lower cost.

The second step of the invention provides a push rod position determining method, which gives a pre-extension amount to the push rod in advance, so that the end part of the push rod can just contact with the manual pull rod in a push-out preparation state, the idle stroke distance of the push rod is shortened to the maximum extent, the action time of the push rod is shortened, and the scram time of a blade is controlled within 3 seconds.

Drawings

FIG. 1 is a schematic diagram of the overall structure of a hybrid mower;

FIG. 2 is a schematic diagram of the overall structure of the hybrid mower;

FIG. 3 is a schematic diagram of a brake control unit;

FIG. 4 is a second schematic illustration of a brake control assembly configuration;

FIG. 5 is a schematic diagram showing a first configuration of the brake control member in a braking state;

FIG. 6 is a second schematic structural view of the brake control member in a braking state;

fig. 7 shows a connection structure of the manual lever 4 and the main body 100;

FIG. 8 is an enlarged view at B of FIG. 7;

fig. 9 is a specific structure of the eccentric rotary shaft 10;

FIG. 10 shows the structure of the cooperation of the manual pull rod 4 and the track member 5;

FIG. 11 is an enlarged view of FIG. 10 at C;

FIG. 12 is a relative position of the push rod motor and the track groove;

FIG. 13 is a logic diagram of a pushrod control according to the present invention;

FIG. 14 is a logic diagram of brake time calculation;

reference numerals: 1. a hybrid mower; 100. a body; 2. an oil burner; 3. a brake control part; 4, a step of; a manual pull rod; 5. a track member; 501. starting a gear; 502. a brake gear; 503. a track groove; 504. a mounting notch; 505. an arc-shaped groove; 6. a rotating shaft; 7. a wire rope; 8. a guide plate; 9. a push rod motor; 901. a push rod. 10. An eccentric rotating shaft; 11. a fixing member; 12. a first gasket; 13. a shaft sleeve; 14. a spring; 15. a second gasket; 1301. a through hole; 1302. an annular groove.

Detailed Description

As shown in fig. 1-2, the hybrid mowing robot comprises a machine body and a fuel engine arranged on the machine body, wherein the output end of the fuel engine is connected with a cutting component, and a fuel engine braking system is controlled by a braking control component.

The brake control unit package is shown in fig. 4-6.

The brake control component comprises a push rod motor, a track component, a manual pull rod and a steel cable, wherein the steel cable is specifically a fuel oil engine brake cable, and the functions of the components are as follows:

the brake cable of the fuel oil engine is a main part of an external control part of a brake device of the fuel oil engine, and is used for controlling the starting and braking of the gasoline engine. The fuel oil engine braking device is a mature device, the key point of the scheme is the control of the manual pull rod, and the structure of the fuel oil engine braking device is not described in detail here.

The push rod motor is used for pushing the manual pull rod out of the starting gear by using the push rod when the emergency stop occurs.

The track component is provided with a starting gear and a braking gear, the starting gear is connected with the braking gear through a track groove, the track component is used for fixing the manual pull rod, the braking gear is used for enabling the manual pull rod to be in a braking state, and the starting gear is used for enabling the manual pull rod to be in a starting state. The starting gear is specifically a semicircular r groove, and when the push rod motor pushes the manual pull rod out of the groove, the manual pull rod can return to the braking gear along the track groove under the action of the power of the reset of the inhaul cable, so that the state is maintained. The track component is also provided with a mounting notch, and the manual pull rod can be embedded into the track groove through the mounting notch, so that the installation is convenient.

The manual pull rod provides a manual function, and can be moved in a starting gear and a braking gear by pulling the pull rod.

To ensure that the push rod motor can fully push the manual pull rod, as shown in fig. 6, the track line of the push rod motor runs through the axis where the center of the starting gear is located. The radius of the starting gear groove is the same as that of the manual pull rod, and a clearance fit tolerance can be selected to determine specific machining parameters.

As shown in fig. 7, B is a connection structure of the manual lever 4 and the body 100. The structure at position b is specially designed to ensure that the manual lever 4 is stably moved to the track groove 503 to the brake gear 502 after being pushed out of the starting gear 501.

Fig. 8 is an enlarged view of a position B in fig. 7, as shown in fig. 8, a rotating shaft 6 protrudes from the machine body 100, a shaft sleeve 13 is connected to the root of the manual pull rod 4, the shaft sleeve 13 is sleeved on the rotating shaft 6, the center of the shaft sleeve is a through hole 1301, an annular groove 1302 is arranged on the periphery of the through hole 1301, and the annular groove 1302 is arranged at one end of the shaft sleeve 13 towards the machine body 100. During installation, the through hole 1301 of the shaft sleeve 13 is sleeved on the rotating shaft 6, the spring 14 is sleeved in the annular groove 1302, two ends of the spring 14 respectively abut against the bottom of the annular groove 1302 and the machine body 100, and the shaft sleeve 13 and the manual pull rod 4 move away from the machine body 100 under the action of the spring. The axial position of the shaft sleeve 13 is determined by the machine body 100 and a positioning element 11 connected to the rotating shaft 6, and the positioning element 11 can be a part fixed on the rotating shaft such as a positioning pin or a clamping ring. The shaft sleeve 13 has a certain axial movable space on the rotating shaft.

Based on the above structure, after the manual pull rod 4 is pushed out by the push rod, the manual pull rod can be deflected towards the track groove 503 under the action of the spring 14, so that the manual pull rod can enter the track groove.

Further, the rotating shaft 6 can be sleeved with the first gasket 12 and the second gasket 15, the first gasket 12 is located between the positioning piece 11 and the shaft sleeve 13, the second gasket 15 is located between the shaft sleeve 13 and the machine body 100, and the first gasket 12 and the second gasket 15 play a protective role, wherein the first gasket 12 is unstable in structure due to contact of two sides, and can be provided with a plurality of gaskets, so that the shaping is promoted. The second gasket 15 may be movably sleeved on the rotating shaft or fixed on the machine body 100.

Fig. 9 shows a specific structure of the eccentric rotary shaft 10, and as can be seen from fig. 9, the eccentric rotary shaft 10 deviates downwards from the horizontal axis, which has the effect that after the manual pull rod 4 is pushed out by the push rod, the manual pull rod 4 deviates towards the track groove 503 under the action of the spring 14, meanwhile, due to the downwards deviation of the axis of the eccentric rotary shaft 10, the manual pull rod 4 deviates towards the direction away from the machine body 100, and the manual pull rod can further enter the track groove.

The position c in fig. 10 is the structure where the manual pull rod 4 is matched with the track component 5. The enlarged view of the C position is shown in fig. 11, and as can be seen from fig. 11, the brake gear is provided with an arc-shaped groove, so that the brake gear can be positioned conveniently.

Fig. 12 shows the relative position of the push rod motor 9 and the track groove 503, wherein the axis of the push rod motor 9 is parallel to the axis of the track groove 503, and the push rod does not cover the track groove at all, so that the push rod is prevented from being rubbed during the sliding process of the manual pull rod. By the arrangement mode, the distance between the push rod motor and the track component is smaller, the structure is more compact, and occupied space is reduced.

The emergency stop system of the invention comprises the following working steps:

and 5-6, the emergency stop system is in a braking state, and the fuel engine cannot be started. The manual pull rod is stopped at a brake gear under the action of the spring. The gasoline engine brake cable is also in a braking state because the gasoline engine brake cable is fixed on the manual pull rod.

And the brake is started, at the moment, the manual operation pulls the manual pull rod to enter the starting gear, and the system enters the starting state, as shown in figures 3-4.

And 3-4, the emergency stop system is in a starting state, and the gasoline engine can be started. Wherein the push rod motor is in a ready-to-push state. The manual pull rod is stopped at the starting gear under the action of the spring. The gasoline engine brake cable is also in a starting state because the gasoline engine brake cable is pulled out by the manual pull rod.

The emergency stop (start-brake), namely, the state is changed from the start to the brake state, at the moment, the push rod of the push rod motor pushes the manual pull rod to be separated from the fixed start gear, the manual pull rod automatically returns to the brake gear along the track grass under the action of the spring force, the steel cable is reset, the fuel oil engine brake system brakes, and the emergency stop action is completed.

Parameter selection of the emergency stop system:

the stroke L1 and the pulling force F1 of the known gasoline engine brake cable are converted into the stroke L2 and the pulling force F2 through the manual pull rod, and then the size of the groove r of the gear 2.2 is determined according to the structure of the manual pull rod.

The stroke of the manual pull rod from sudden stop to start is L2, the stroke of the push rod motor to work is r, the thrust is F2, and therefore the proper push rod motor type can be selected according to the r and F2 values.

Software control logic of the scram system:

the kick-out speed v of the tappet motor and the pulse signal n output during the kick-out of the fixed distance are known

Firstly, setting the position of the push rod motor when the push rod is completely retracted as 0, and marking the push rod position of the push rod motor before sudden stop (in a push-out preparation state) as S1; the push rod has just pushed the pull rod out of the start gear position, labeled S2, see fig. 13 control logic.

The reliability and rapidity of the emergency stop system are mainly determined by three positions of 0, S1 and S2,

firstly, whether the push rod returns to the position 0 needs to be judged, and three methods are adopted, namely a power detection method, wherein the power of a motor is greatly reduced after the push rod reaches the position 0. And secondly, according to the time calculation method, the total stroke of the push rod is fixed, the speed is fixed, the movement time is also fixed, and the return-to-0 time is set to be longer than the full stroke time. And thirdly, according to the pulse calculation method, a corresponding pulse signal is output in a unit stroke, so that when the pulse signal is returned to 0, the return to 0 can be judged without the pulse signal.

The S1 position can be accurately positioned only after the position returns to 0, and there are three methods, namely a power detection method or a power detection method are suggested

The "pulse calculation method" considers that the positioning accuracy has the following priority, namely "power detection method" > "pulse calculation method" > "time calculation method"

The method for determining the S1 position comprises the following steps:

the method comprises the following steps: through distance calculation, when the manual pull rod is positioned at a starting gear, the distance between the position 0 and the position where the end part of the push rod just contacts the manual pull rod is determined, and according to the distance, the time t2 required by the push rod to travel from the position 0 to the position where the end part of the push rod just contacts the manual pull rod (namely the S1 position) can be obtained by combining the self parameters of the push rod motor, namely the push rod running speed, and the travel time t2 reaches the S1 position after the push rod position returns to 0 in the running process of the machine.

The method is most simple, the time t2 can be obtained through theoretical calculation, but the method is subject to the problem of consistency of machine production, and the precision of different products cannot be completely ensured.

The second method is as follows: by pulse calculation

Some motors are designed with pulse signals, and the state (direction and stroke) of the push rod can be displayed by the pulse signals, so that the moving distance of the push rod can be calculated by detecting and recording the pulse signals. When the push rod is retracted to the position 0, the pulse signal stops being output, whereby the position 0 of the push rod can be judged. When the push rod extends from the position 0 to the position S1, the push rod can be judged to reach the position S1 by only calculating the direction and the pulse number of the pulse signal due to the fixed distance between the positions 0 and S1. The position of S2 can be judged similarly. Since the pulse signal has a transmission period, theoretically, the shorter the pulse signal period is, the more accurate the calculated distance value is, but the shorter the pulse signal is, the more elements are required, the more the motor structure is complicated, and the cost is high.

And a third method: by power detection

The power of the push rod motor is detected to judge the position of the push rod, and in the moving process of the push rod, the push rod can cause the change of the load of the push rod due to the change of the stress of the push rod, so that the push rod motor is affected to generate the change of the power. Under the condition that more sensors can be configured, a pressure sensor and the like can be arranged at the end part of the push rod, and the load change of the push rod is obtained by detecting the numerical value change of the pressure sensor, so that the power of the push rod is judged.

The following will specifically describe a current value as an example.

Assuming that the current value of the push rod is i during no-load movement, when the push rod is retracted to the position 0, the push rod motor is stopped, the current of the push rod motor is changed from i to 0, and when the push rod moves to contact with the manual pull rod, the manual pull rod blocks the movement of the push rod, the load of the push rod is increased, and the current value of the push rod is changed from i to i ', i' with a value larger than i.

Specific examples: assuming that the current value of the push rod is 0.5A in the process of no-load movement, the current value is 1.2A when the push rod pushes the manual pull rod to travel. When the push rod is retracted to the position 0, the push rod motor is stopped, and the current thereof is changed from 0.5A to 0A, so that the position 0 of the push rod can be judged. When the push rod is extended from the position 0 to the position S1, the push rod motor starts to push the manual pull rod, the current of the push rod motor is changed from 0.5A to 1.2A, and when the current just reaches 1.2A, the push rod reaches the position S1. When the push rod is moved from the position S1 to the position S2, the push rod motor pushes the manual pull rod, the current of the push rod motor is changed from 1.2A to 0.5A, and when the current just changes to 0.5A, the push rod reaches the position S2.

Based on the above variations, we can determine the positions 0, s1 and s2 by detecting the operating current of the push rod motor.

In the actual use, the push rod motor is stable in current under the condition of no-load operation, and can be detected better, but when the push rod motor is operated under the condition of load, certain fluctuation exists in current, when the push rod contacts with the manual pull rod, the current jumps, and the current is not necessarily directly stabilized at a certain current value, so that the specific s1 position can be judged by detecting the current jumps. That is, when the current jump (increasing direction) of the push rod motor is detected to be larger than a certain percentage (for example, 10%) when the push rod starts to move from the position 0, the push rod is judged to reach the position s1, the push rod motor stops driving the push rod to move, and the push rod is in a push-out preparation state.

Because the current detects that the circuit activity exists between the stop of the push rod motor and a certain delay inevitably exists, after the push rod motor stops, the push rod can be contacted and pushed to move the manual pull rod for a certain distance, which can lead the manual pull rod to be partially out of the starting gear, and potential safety hazards exist. Thus, the step of adding position correction, namely: when the push rod starts to move from the position 0, when the current jump (increasing direction) amplitude of the push rod motor is detected to exceed a certain percentage (for example, 10%), the push rod motor stops driving the push rod to move, then the push rod motor starts to drive the push rod to move backwards, the backward distance is a correction distance, after the backward is finished, the push rod is judged to reach the position s1, the push rod motor stops driving the push rod to move, and at the moment, the push rod is in a push-out preparation state. The correction distance is the product of the electronic delay and the push rod running speed. The electronic delay is a relatively fixed value in mass production of the machine (after the hardware has been set), and can be obtained by detection means. The correction distance can also be selected as the radius of the starting gear groove, which is a relatively safe and reliable value.

Finally, the S2 position is determined, wherein the S2 position is actually determined by the structural design of the manual pull rod and the fixed stop block, and the position when the push rod just can push the manual push rod out of the fixed stop block is S2. The position s2 only has significance when checking the braking time, and no influence on the specific operation process of the machine exists in the actual operation process of the machine.

And (3) calculating an emergency stop time theory of an emergency stop system:

referring to fig. 14, the braking time calculation logic, known as t1 time is about 0.2S, t3 time is about 1S, calculates t2 time, t2= (S2-S1)/V, and total time t=t1+t2+t3, needs to satisfy the requirement of less than 3S.

Claims (7)

1. A mixed mower emergency stop control method is characterized in that when the mixed mower receives an emergency stop signal of a remote control device, a brake control component arranged on the mixed mower executes a mixed mower emergency stop command;

the brake control part comprises a driving part, the driving part comprises a push rod used for contacting and pushing the manual control device, the driving part drives the manual control device to move through the push rod so as to enable the manual control device to move to a position where the brake device is started,

the manual control device is connected with the mower body, is connected with the braking device through a connecting piece, and controls whether the braking device operates or not through physical displacement;

the brake control section further includes:

the track component is used for limiting a displacement path of the manual control device and comprises a starting gear, a stopping gear and a track groove for connecting the starting gear and the stopping gear, wherein a limiting blocking part for limiting the position of the manual control device is arranged on the starting gear, and the manual control device can be limited in the starting gear;

a reset part which always provides potential energy for the manual control device to run from the starting gear to the stopping gear;

when the manual control device is positioned at the starting gear position, the braking device stops,

when the manual control device is positioned at the stop gear position, the braking device is started to stop the operation of the power output device or cut off the energy supply of the power output device;

the starting gear is a semicircular groove;

the manual control device is a manual pull rod;

the driving piece is a push rod motor;

the track line of the push rod motor runs through the axis where the circle center of the starting gear is positioned;

the machine body is provided with a rotating shaft in a protruding mode, the root of the manual pull rod is connected with a shaft sleeve, the shaft sleeve is sleeved on the rotating shaft, the center of the shaft sleeve is provided with a through hole, an annular groove is formed in the periphery of the through hole, the annular groove is formed in one end of the shaft sleeve, which faces the machine body, of the machine body, when the machine is installed, the through hole of the shaft sleeve is sleeved on the rotating shaft, a spring is sleeved in the annular groove, two ends of the spring respectively abut against the bottom of the annular groove and the machine body, and the shaft sleeve and the manual pull rod move away from the machine body under the action of the spring;

the rotating shaft is an eccentric rotating shaft;

the eccentric rotating shaft deviates downwards from the horizontal axis, the manual pull rod is pushed out by the push rod and then deviates towards the track groove under the action of the spring, and meanwhile, the manual pull rod deviates towards a direction away from the machine body due to the downwards deviation of the axis of the eccentric rotating shaft;

the control method comprises the following steps:

A. the hybrid mower is started to enter initialization, and the driving piece controls the push rod to return to an initial position S0;

B. the driving piece controls the push rod to move to the S1 position, and at the moment, the end part of the push rod just contacts the manual control device;

C. when the hybrid mower receives an emergency stop signal transmitted by the remote control device, the driving piece controls the push rod to move from the S1 position to the S2 position, so that emergency stop operation is completed;

in step B, the S1 position is determined by detecting the working parameters of the driving piece, and the method comprises the following steps:

B3. setting an initial position of the end part of the push rod, namely a position S0 of the end part of the push rod in a completely retracted state of the push rod;

B4. when the driver operating parameter jump is detected when the push rod starts to move from the position S0, it is determined that the push rod end has reached the position S1.

2. The method according to claim 1, wherein the step of adding position correction after the step B4 is performed, when the push rod starts to move from the position S0, the driving member stops driving the push rod to move when detecting the jump of the operating parameter of the driving member, and then the driving member starts to drive the push rod to retract, the retracting distance is the correction distance, and after the retracting is completed, the push rod is determined to reach the position S1.

3. The method for controlling the emergency stop of a hybrid mower according to claim 2, wherein,

the correction distance is the product of the electronic delay and the push rod running speed.

4. The method for controlling the scram of a hybrid mower according to any one of claims 1 to 3, wherein the operation parameter is one or more of an operation voltage, an operation current, an operation load, an operation power, and a pressure indication of the driving member.

5. The method of claim 4, wherein the operating parameter jump is an increase in operating parameter to more than 110% of the operating parameter under the drive member idle condition.

6. A mixed mower emergency stop control method is characterized in that when the mixed mower receives an emergency stop signal of a remote control device, a brake control component arranged on the mixed mower executes a mixed mower emergency stop command;

the brake control part comprises a driving part, the driving part comprises a push rod used for contacting and pushing the manual control device, the driving part drives the manual control device to move through the push rod so as to enable the manual control device to move to a position where the brake device is started,

the manual control device is connected with the mower body, is connected with the braking device through a connecting piece, and controls whether the braking device operates or not through physical displacement;

the brake control section further includes:

the track component is used for limiting a displacement path of the manual control device and comprises a starting gear, a stopping gear and a track groove for connecting the starting gear and the stopping gear, wherein a limiting blocking part for limiting the position of the manual control device is arranged on the starting gear, and the manual control device can be limited in the starting gear;

a reset part which always provides potential energy for the manual control device to run from the starting gear to the stopping gear;

when the manual control device is positioned at the starting gear position, the braking device stops,

when the manual control device is positioned at the stop gear position, the braking device is started to stop the operation of the power output device or cut off the energy supply of the power output device;

the starting gear is a semicircular groove;

the manual control device is a manual pull rod;

the driving piece is a push rod motor;

the track line of the push rod motor runs through the axis where the circle center of the starting gear is positioned;

the machine body is provided with a rotating shaft in a protruding mode, the root of the manual pull rod is connected with a shaft sleeve, the shaft sleeve is sleeved on the rotating shaft, the center of the shaft sleeve is provided with a through hole, an annular groove is formed in the periphery of the through hole, the annular groove is formed in one end of the shaft sleeve, which faces the machine body, of the machine body, when the machine is installed, the through hole of the shaft sleeve is sleeved on the rotating shaft, a spring is sleeved in the annular groove, two ends of the spring respectively abut against the bottom of the annular groove and the machine body, and the shaft sleeve and the manual pull rod move away from the machine body under the action of the spring;

the rotating shaft is an eccentric rotating shaft;

the eccentric rotating shaft deviates downwards from the horizontal axis, the manual pull rod is pushed out by the push rod and then deviates towards the track groove under the action of the spring, and meanwhile, the manual pull rod deviates towards a direction away from the machine body due to the downwards deviation of the axis of the eccentric rotating shaft;

the control method comprises the following steps:

A. the hybrid mower is started to enter initialization, and the driving piece controls the push rod to return to an initial position S0;

B. the driving piece controls the push rod to move to the S1 position, and at the moment, the end part of the push rod just contacts the manual control device;

C. when the hybrid mower receives an emergency stop signal transmitted by the remote control device, the driving piece controls the push rod to move from the S1 position to the S2 position, so that emergency stop operation is completed;

in step B, the distance between the push rod at the position S0 and the push rod at the position S1 is determined by calculating the distance between the position S1 and the position S0 when the manual control device is at the start gear, and according to the distance, the time t required for the push rod to travel from the position S0 to the position S1 is obtained in combination with the push rod running speed, and the travel time t of the push rod from the position S0 to the position S1 is obtained during the running process of the machine.

7. A mixed mower emergency stop control method is characterized in that when the mixed mower receives an emergency stop signal of a remote control device, a brake control component arranged on the mixed mower executes a mixed mower emergency stop command;

the brake control part comprises a driving part, the driving part comprises a push rod used for contacting and pushing the manual control device, the driving part drives the manual control device to move through the push rod so as to enable the manual control device to move to a position where the brake device is started,

the manual control device is connected with the mower body, is connected with the braking device through a connecting piece, and controls whether the braking device operates or not through physical displacement;

the brake control section further includes:

the track component is used for limiting a displacement path of the manual control device and comprises a starting gear, a stopping gear and a track groove for connecting the starting gear and the stopping gear, wherein a limiting blocking part for limiting the position of the manual control device is arranged on the starting gear, and the manual control device can be limited in the starting gear;

a reset part which always provides potential energy for the manual control device to run from the starting gear to the stopping gear;

when the manual control device is positioned at the starting gear position, the braking device stops,

when the manual control device is positioned at the stop gear position, the braking device is started to stop the operation of the power output device or cut off the energy supply of the power output device;

the starting gear is a semicircular groove;

the manual control device is a manual pull rod;

the driving piece is a push rod motor;

the track line of the push rod motor runs through the axis where the circle center of the starting gear is positioned;

the machine body is provided with a rotating shaft in a protruding mode, the root of the manual pull rod is connected with a shaft sleeve, the shaft sleeve is sleeved on the rotating shaft, the center of the shaft sleeve is provided with a through hole, an annular groove is formed in the periphery of the through hole, the annular groove is formed in one end of the shaft sleeve, which faces the machine body, of the machine body, when the machine is installed, the through hole of the shaft sleeve is sleeved on the rotating shaft, a spring is sleeved in the annular groove, two ends of the spring respectively abut against the bottom of the annular groove and the machine body, and the shaft sleeve and the manual pull rod move away from the machine body under the action of the spring;

the rotating shaft is an eccentric rotating shaft;

the eccentric rotating shaft deviates downwards from the horizontal axis, the manual pull rod is pushed out by the push rod and then deviates towards the track groove under the action of the spring, and meanwhile, the manual pull rod deviates towards a direction away from the machine body due to the downwards deviation of the axis of the eccentric rotating shaft;

the control method comprises the following steps:

A. the hybrid mower is started to enter initialization, and the driving piece controls the push rod to return to an initial position S0;

B. the driving piece controls the push rod to move to the S1 position, and at the moment, the end part of the push rod just contacts the manual control device;

C. when the hybrid mower receives an emergency stop signal transmitted by the remote control device, the driving piece controls the push rod to move from the S1 position to the S2 position, so that emergency stop operation is completed;

in step B, the S1 position is calculated by pulse, comprising the following steps:

B1. setting an initial position of the end part of the push rod, namely a position S0 of the end part of the push rod in a completely retracted state of the push rod;

B2. through pulse calculation, when the pulse signal of the driving piece stops outputting, judging that the end part of the push rod is positioned at a position S0; when the push rod moves from the position S0 to the position S1, the end of the push rod reaches the position S1 by calculating the direction and the pulse number of the pulse signal of the driving piece.

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