JP5114171B2 - Electric mower - Google Patents

Description

  The present invention relates to an electric mower that rotates a rotary blade and a blade with a motor.

Mowers are widely used as devices for mowing grass such as tunnels and parks. Traditional mowers rotate a rotary blade or the like with a small engine. However, mowers using an engine are noisy and are difficult to use in urban areas or for general household use. Therefore, in consideration of applications used in general households, electric mowers equipped with a motor instead of an engine are commercially available.
There are two types of electric mowers: one that feeds power from a commercial power source and rotates the motor (Patent Document 1), and one that mounts a storage battery and feeds power from the storage battery to the motor (Patent Document 2).
JP 2007-20588 A JP 2006-288296 A

  Electric mowers are not only less noise than engine-equipped mowers, but they are also safer. That is, the engine-mounted mower cannot brake the rotation of the rotary blade or the like, but the electric mower can forcibly stop the rotation of the rotary blade or the like by electrically braking the motor. Therefore, the rotation of the rotary blade can be forcibly stopped when the rotary blade hits the garden stone or when the rotary blade is missing.

By the way, in an electric mower, supply of electric power may be interrupted during operation. For example, in an electric mower of a type in which power is supplied from a commercial power source and the motor is rotated, the power supply line may be cut by a rotary blade during mowing work, and when the power supply line is cut, the electric mower is supplied to the motor. Power is cut off.
In addition, in an electric mower with a structure that supplies power to the motor from the storage battery (Patent Document 2), the storage battery may fall off during mowing, or the power supply line connecting the storage battery and the motor may be disconnected. The supplied power is cut off.
When the electric power supplied to the motor is cut off, the driving of the motor is stopped. However, since the rotary blade has a considerable inertia, the rotary blade continues to rotate for a considerable time due to the inertial force.

In the electric mower of the prior art, when the power supply line is cut or the storage battery is dropped, the electric power supplied to the control device of the electric mower is also cut off. Cannot be braked.
Therefore, for example, when the worker falls over during mowing work and the storage battery is detached, there is a problem that the rotation of the rotary blade or the like cannot be braked.
In addition, the electric mower of the prior art does not apply the brake in the situation where the storage battery is detached, even though the rotary blade can be braked during normal mowing work. There was a risk of an unexpected accident.

  Therefore, the present invention pays attention to the above-mentioned problems of the prior art, and provides a safer electric mower that can forcibly stop a rotary blade and the like even when the power supplied to the motor is cut off. It is to be an issue.

  The invention provided to solve the above-described problems includes a power source unit composed of a battery or a commercial power source, a rotating unit, a motor for rotating the rotating unit, and a control device having a function of electrically braking the motor. In the electric mower provided, the electric mower is provided with a standby power source that discharges when energization from the power supply unit is interrupted to make the control device operable.

  The electric mower according to the present invention includes a standby power supply that discharges when the power supply from the power supply unit is interrupted to enable the control device to operate, so that the control device functions even when the power supply from the power supply unit is interrupted. Yes. Therefore, a signal can be transmitted to the transistor or the like so that a known electric braking (for example, short-circuit braking) is performed even when the power supply from the power source is interrupted, and the rotary blade or the like can be forcibly stopped.

Another invention is an electric mowing machine including a power source unit including a battery or a commercial power source, a rotating unit, a motor for rotating the rotating unit, and a control device having a function of electrically braking the motor. An electric mower characterized by comprising a reserve power source consisting of a storage battery or a capacitor that is charged by energization from a power supply unit and is discharged when the energization from the power supply unit is interrupted to make the control device operable. .

  The electric mower according to the present invention also includes a standby power source that discharges when the power supply from the power supply unit is interrupted to enable the control device to operate. For example, a signal can be transmitted to a transistor or the like so that short-circuit braking is performed, and the rotary blade or the like can be forcibly stopped.

In addition , the electric power mower is characterized in that the power supply unit is a battery and is detachable, and includes power supply monitoring means for detecting that the battery is dropped or energized from the battery is cut off.

  In the present invention, since the power supply monitoring means for detecting that the battery has been dropped or the power supply from the battery has been interrupted is provided, it is possible to know that the battery has dropped.

According to the present invention, the rotation of the motor is forcibly stopped when the power supply monitoring means detects that the battery is dropped or the power supply from the battery is cut off .

  In the present invention, the motor is forcibly stopped when the power supply monitoring means detects that the battery has been dropped or the power supply from the battery has been cut off, so the safety is high.

  The power supply monitoring unit is a circuit that detects that the voltage supplied from the power supply unit is a certain level or higher.

According to the first aspect of the present invention having the above-described features, the power supply unit, the rotation unit, the motor that rotates the rotation unit, the forced stop switch, and the power supply unit are connected to the power supply unit to supply power. In an electric mower having a control device having a function of electrically braking the motor, the power supply unit is a battery and is detachable, and a voltage supplied from the power supply unit is greater than a certain level Power supply monitoring means capable of detecting whether or not the battery has dropped out or has been de-energized by detecting whether or not, and the control device includes a motor drive unit, a control operation unit, and the power supply monitor And the motor drive unit switches the energization status of the motor drive coil, and the control operation unit generates a switching signal for switching the energization status of the drive coil. A circuit for, is charged by the current from the power source unit, a standby power supply comprising a battery or a capacitor to maintain an operable state the control operation of the discharge to the controller when the current is supplied from the power supply unit interrupted When the voltage of the power supply section drops, a stop signal is transmitted from the power monitoring means to the control operation section, the drive coil is short-circuited, the motor is forcibly stopped, and the signal of the forced stop switch is further input to the control operation section The electric mower is characterized in that the drive coil is short-circuited even when the forced stop switch is operated.
According to a second aspect of the present invention, the control device includes a control power supply unit, the control power supply unit is a circuit that generates a signal voltage for causing the control operation unit to function, and the standby power supply includes the control power supply unit. The electric mower according to claim 1, wherein the control operation unit is maintained in an operable state by being in an operable state.

According to a third aspect of the present invention, there is provided a motor drive unit for supplying electric power to the motor, a diode is provided between the standby power supply and the motor drive unit, and the diode causes the standby power supply side to move to the motor drive unit side. The electric mower according to claim 1 or 2 , wherein a current is prevented from flowing.

  In the electric mower of the present invention, the diode prevents the current from flowing from the standby power source side to the motor drive unit side, so that the power of the standby power source is prevented from being consumed by the motor, and the time during which the control device can operate Can be extended.

  In the electric mower of the present invention, a brake such as a rotary blade functions even when the storage battery has fallen off. Therefore, the operator can stop the rotation of the rotary blade or the like by a normal procedure, which is safe.

Embodiments of the present invention will be further described below.
FIG. 1 is a perspective view showing an electric mower according to an embodiment of the present invention.
The electric mower 1 of this embodiment operates using the motor 2 as a power source. The electric mower 1 incorporates a motor system including a control device 20 described later. As shown in FIG. 1, the electric mower 1 has a main part that has a long outer shape formed by connecting a front operation rod 3 and a rear operation rod 5. The electric mower 1 has a rotating unit 6 on the front end side of the front operation rod 3 and a power supply unit 7 and a control unit 8 on the end side of the rear operation rod 5. The electric mower 1 is provided with a motor unit 10 at a substantially central portion of its entire length.

  The front operation rod 3 is configured by a hollow cylinder and has a built-in power transmission shaft (not shown). A rotating part 6 is provided on the front end side of the front operation rod 3. The rotating unit 6 has a bevel gear train (not shown), as in a conventionally known electric mower, and a power transmission shaft built in the front operation rod 3 is connected to the input side of the bevel gear train. Moreover, the rotary part 6 is provided with a rotary blade 11, which is connected to the bevel gear described above.

The motor unit 10 has a built-in motor 2. FIG. 2 is a schematic diagram showing an internal structure of a motor employed in the electric mower shown in FIG.
The motor 2 is a known brushless motor, and includes a rotor 25, a stator 26, a Hall element (not shown), and the like. The rotor 25 includes a magnet. In the present embodiment, a magnet having a pair of N and S (two poles) magnetic poles is employed as the rotor 25. A rotating shaft (not shown) is attached to the rotor 25 so as to be integrally rotatable. The stator 26 includes a multi-phase (n-phase) drive coil 27. As shown in FIG. 2, in the present embodiment, the stator 26 includes a three-phase drive coil 27 (hereinafter also referred to as drive coils 27U, 27V, and 27W).

  The hall element (not shown) can detect a magnetic pole of the rotor 25 and transmit a pulse signal, and is provided to detect the rotational position of the rotor 25. In the present embodiment, three Hall elements are arranged at an interval of 120 degrees with respect to the central axis of the rotor 25, and a rotational position detecting means is formed by these three Hall elements.

  The motor 2 can rotate the rotor 25 and the rotation shaft integrated therein in a predetermined direction by sequentially energizing the drive coil 27 based on each motor pulse signal transmitted from each hall element. . When the drive coil 27 is short-circuited, the rotor 25 and the rotating shaft are braked.

  As described above, a power transmission shaft (not shown) is built in the front operation rod 3, and this power transmission shaft is connected to be rotatable in conjunction with the rotor 26 of the motor 2. Therefore, the electric mower 1 operates the motor 2 to transmit the rotational power generated in the motor 2 to the rotary blade 11 via a power transmission shaft and a bevel gear (not shown) provided on the rotary unit 6. Can be rotated.

  An operation handle 15 is provided on the rear operation rod 5. The operation handle 15 is provided with an operation lever 16, a changeover switch 17 for adjusting the rotation speed of the rotary blade 11, a forced stop switch 18 for forcibly stopping the rotary blade, and the like. Further, a control unit 8 is provided at the end portion of the rear operation rod 5. The control unit 8 includes a control device 20 described later. The control device 20 constituting the control unit 8 is electrically connected to the motor 2 and the power supply unit 7. The control device 20 is connected to a changeover switch 17, a forced stop switch 18, and the like.

  A power supply unit 7 is provided at the rear end of the rear operation rod 5. The power supply unit 7 incorporates a storage battery 21 that constitutes the power supply of the motor system. The storage battery 21 is electrically connected to the motor 2 provided in the motor unit 10.

Next, the control device 20 of the electric mower 1 of the present embodiment will be described. FIG. 3 is a circuit diagram of the control device for the electric mower in FIG.
The control device 20 of the electric mower 1 is roughly composed of a motor drive unit 30, a control operation unit 31, a control power supply unit 32, and a power connection detection unit 33.
The motor drive unit 30 includes six FETs 35, and switches the energization state of the stator 26 to the drive coils 27U, 27V, and 27W by switching the FETs 35.

The control operation unit 31 is a circuit that mainly generates a switching signal for the FET 35, and receives signals from a hall element (not shown), a forced stop switch 18, and the like, and transmits a signal to the FET 35.
That is, when the mowing operation is performed, the motor 2 is rotated by switching the signal to the FET 35 based on each motor pulse signal transmitted from each Hall element and sequentially energizing the drive coil 27.
On the other hand, when the forced stop switch 18 is operated, a signal is sent to the FET 35 so that the drive coil 27 is short-circuited.
The same applies when a stop signal is received from the power connection detection unit 33, and a signal is sent to the FET 35 so that the drive coil 27 is short-circuited.

The control power supply unit 32 is a circuit that generates a signal voltage (5 V) for causing the control operation unit 31 to function, and includes a three-terminal regulator 37.
Further, as a configuration unique to the present embodiment, an electrolytic capacitor 40 and a diode 41 are provided on the input side of the three-terminal regulator 37.
The diode 41 is connected in a direction that allows energization from the power supply unit 7 to the three-terminal regulator 37 side and prevents the reverse. The electrolytic capacitor 40 is between the diode 41 and the three-terminal regulator 37 and is connected in parallel to the three-terminal regulator 37.

  The electrolytic capacitor 40 functions as a standby power source and has a large capacity. Specifically, it is about 470 μF to 1000 μF (microfarad).

  The control power supply unit 32 is additionally provided with a capacitor 43. The capacitor 43 is provided only for removing high frequency noise of the power supply circuit, and a circuit provided with the capacitor 43 is well known.

The power connection detection unit 33 detects that the voltage supplied from the power supply unit 7 is equal to or higher than a certain level, and is a circuit that functions as a power supply monitoring unit.
The power supply connection detection unit 33 has a comparator 50, and the comparator 50 has a resistance obtained by dividing the voltage of the power supply unit 7 by the resistors R 1 and R 4 and the signal voltage (5 V) generated by the control power supply unit 32. A voltage divided by R2 and R3 is input. When the voltage divided by the resistors R1 and R4 is higher than the voltage divided by the resistors R2 and R3, a signal is output from the comparator 50.
When a normal voltage is applied from the power supply unit 7, a signal is output from the comparator 50, and the output stops when the voltage of the power supply unit 7 decreases.
In addition, power is supplied to the motor drive unit 30 on the condition that a signal is output from the comparator 50. When the signal is stopped from the comparator 50, the circuit that supplies power to the motor drive unit 30 is shut off and the control is performed. A stop signal is sent to the operation unit 31. Specifically, the “power in” signal is stopped.
As described above, when a stop signal (stop of “power-in” signal) is transmitted from the power connection detection unit 33 to the control operation unit 31, the control operation unit 31 causes the FET 35 to short-circuit the drive coil 27. A signal is sent to forcibly stop the motor 2.

  The power connection detection unit 33 also serves as a power supply circuit 45 that supplies power from the power supply unit 7 to the motor drive unit 30, and the power supply circuit 45 is connected in parallel with the comparator 50. A diode 51 is provided between the drive unit 30. The diode 51 allows energization from the power supply unit 7 toward the motor drive unit 30 and prevents the reverse. The diode 51 prevents, for example, the electricity generated by the motor coil when the motor is braked from being applied to the comparator 50 side, so that the power supply fluctuation accompanying the fluctuation of the motor load returns to the power supply section 7 side. This prevents the detection accuracy of the power connection detection unit 33 from being maintained.

The control device 20 of the electric mower 1 is connected to the power supply unit 7 as shown in FIG. 3, and the control power supply unit 32 and the power supply connection detection unit 33 are connected in parallel to the positive electrode side of the power supply unit 7. Further, as described above, the output side of the control power supply unit 32 is connected to the control operation unit 31.
A power supply circuit 45 in the power connection detection unit 33 is connected to the motor drive unit 30. Further, the FET 35 of the motor drive unit 30 is connected to each coil of the motor 2.

Since the electric mower 1 of the present embodiment includes the control device 20 described above, if the storage battery 21 is dropped during mowing work, the rotation of the rotary blade 11 is forcibly braked.
More specifically, when the storage battery 21 of the power supply unit 7 is removed, the voltage applied to the control power supply unit 32 of the control device 20 disappears as shown in FIG. 4, but the electrolytic capacitor (standby power supply) 40 of the control device 20 disappears. The electric charge stored in is discharged, and the electric charge is supplied to the input side of the three-terminal regulator 37. That is, since the voltage of the storage battery 21 is constantly applied to the electrolytic capacitor 40, a predetermined amount of electric charge is always stored in the electrolytic capacitor 40. Therefore, when the storage battery 21 is dropped, the charge accumulated in the electrolytic capacitor 40 is released.
On the other hand, the electrolytic capacitor 40 is also connected to the power connection detection unit 33 and the motor drive unit 30 through the common wiring 60. However, since the diode 41 is provided between the electrolytic capacitor 40 and the common wiring 60, the electrolytic capacitor 40 is The electric charge of the capacitor 40 is prevented from flowing out to the motor drive unit 30.

Therefore, the electric charge stored in the electrolytic capacitor 40 is supplied only to the three-terminal regulator 37 side, and a predetermined signal voltage is continuously output from the three-terminal regulator 37.
That is, the voltage input to the three-terminal regulator 37 decreases with time as shown in FIG. 4, but a signal voltage of a predetermined level or higher is maintained for a certain time.
Therefore, a voltage is continuously applied to the control operation unit 31, and the control operation unit 31 maintains a functioning state.

At the same time, when the storage battery 21 of the power supply unit 7 is dropped, the power connection detection unit 33 of the control device 20 immediately detects this fact, shuts off the circuit that supplies power to the motor, and controls from the power connection detection unit 33. A stop signal (stop of the “power-in” signal) is transmitted to the unit 31. In response to this stop signal, the control operation unit 31 sends a signal to the FET 35 so that the drive coil 27 is short-circuited, and the motor 2 is forcibly stopped.
That is, when the storage battery 21 is dropped, the voltage applied to the resistors R1 and R4 of the power connection detection unit 33 decreases. On the other hand, since the signal voltage (5 V) generated by the control power supply unit 32 does not decrease, the voltage divided by the resistors R2 and R3 exceeds the voltage divided by the resistors R1 and R4, and the signal from the comparator 50 (Power-in signal) stops. As a result, the circuit that supplies power to the motor drive unit 30 is shut off and a stop signal is transmitted to the control operation unit 31.
As a result, the motor 2 stops and is safe.

In the embodiment described above, the power connection detection unit 33 is provided, and the power connection detection unit 33 confirms the voltage supplied from the storage battery 21. A configuration is adopted in which the motor 2 is forcibly stopped by short-circuiting 27 . Here, the power connection detection unit 33 is indispensable as a constituent requirement of the invention described in claim 1, but is not necessarily indispensable for forcibly stopping the motor 2 .
That is, even if the storage battery 21 of the power supply unit 7 is dropped, the electric charge stored in the electrolytic capacitor (preliminary power supply) 40 of the control device 20 is released, and a predetermined signal voltage is continuously output from the three-terminal regulator 37, and the control operation is performed. The state where the unit 31 can function is maintained.
Therefore, even if the storage battery 21 is dropped, the forced stop switch 18 functions. Therefore, even if the storage battery 21 is dropped, when the forced stop switch 18 is operated, the drive coil 27 is short-circuited, and the motor 2 can be forcibly stopped.

When the power connection detection unit 33 detects the detachment of the storage battery 21, a circuit that switches the power source to a spare power source such as a capacitor may be employed (reference technique) .
Further, when it is found that the storage battery 21 is detached, a warning sound may be generated using a spare power source such as a capacitor.
As a measure for determining that the storage battery 21 has been detached, it is also conceivable to make a determination based on the intermittent connection between the circuit on the storage battery 21 side and the circuit on the control device side (reference technique) .
For example, as shown in FIG. 5, the storage battery may incorporate the thermistor 55. When such a storage battery 21 is employed, the thermistor 55 and the control device 20 are connected by a connection connector (connection means) 56. Then, the thermistor 55 is energized from the control device 20 and the conduction of the thermistor 55 is monitored. When the storage battery 21 is dropped, the conduction of the thermistor 55 is interrupted. Therefore, when the conduction of the thermistor 55 is lost, it is determined that the storage battery 21 has dropped.

In the embodiment described above, electric charge is accumulated in the electrolytic capacitor 40, and the voltage for operating the control operation unit 31 is maintained by this electric charge. Therefore, the time during which the control operation unit 31 can be maintained is determined by the capacity of the electrolytic capacitor 40.
The time for maintaining the voltage at which the control operation unit 31 can operate is preferably about 5 to 10 seconds. In the present embodiment, when a situation such as dropping of the storage battery 21 occurs, the motor 2 is automatically short-circuited and braked. However, until the drive coil 27 of the motor 2 is short-circuited and the rotation of the rotary blade 11 is stopped. Is about 5 seconds. That is, when the brake is electrically operated with the power supply properly connected, the motor 2 stops in about 5 seconds and the rotation of the rotary blade 11 stops. Therefore, the time for maintaining the voltage at which the control operation unit 31 can operate is preferably equal to or longer than the time required until the motor 2 stops, and is preferably 5 seconds or longer. However, since it is necessary to increase the capacity of the electrolytic capacitor 40 in order to extend the time for maintaining the voltage, it is recommended to design the time for maintaining the voltage to be 10 seconds or less in order to avoid excessive quality. .

  It is also possible to adopt a measure that uses electricity generated by the rotation of the rotary blade 11 and accumulates electric charge in the electrolytic capacitor 40, and that the control operation unit 31 operates by adopting this measure. Can extend the time to maintain the voltage.

  Further, when the power connection detection unit 33 is omitted and the forced stop switch 18 is functioned to stop the rotation of the rotary blade 11 when the storage battery 21 is dropped, the voltage at which the control operation unit 31 can operate is maintained. It is desirable that the time for performing is about 10 to 30 seconds. That is, when a situation such as the storage battery 21 dropping out occurs, electric power is not supplied to the motor 2, so that the rotation of the rotary blade 11 naturally stops. Since the present invention is significant in that the rotation of the rotary blade 11 can be forcibly stopped before it naturally stops, the time during which the rotary blade 11 should maintain the voltage at which the control operation unit 31 can operate is determined. It is the time until it stops naturally. Since the rotary blade usually stops rotating normally around 20 seconds, the time for maintaining the voltage is suitably about 10 to 30 seconds.

  In the above-described embodiment, a capacitor is used as a standby power source. However, a storage battery such as a nickel cadmium battery or a lithium battery may be used as a standby power source.

It is a perspective view which shows the electric mower in embodiment of this invention. It is a schematic diagram which shows the internal structure of the motor employ | adopted in the electric mower shown in FIG. It is a circuit diagram of the control apparatus of the electric mower of FIG. It is a time chart which shows the connection condition of the storage battery of the electric mower of FIG. 1, and the attenuation condition of the voltage of each part. It is a conceptual diagram of the electric mower in other embodiment of this invention.

DESCRIPTION OF SYMBOLS 1 Electric mower 2 Motor 6 Rotating part 7 Power supply part 8 Control part 10 Motor part 11 Rotary blade 18 Forced stop switch 20 Control device 21 Storage battery 30 Motor drive part 31 Control action part 32 Control power supply part 33 Power supply detection part (Power supply monitoring means )
37 3-terminal regulator 40 Electrolytic capacitor (standby power supply)
41 diode

Claims (3)

A power supply unit, a rotation unit, a motor for rotating the rotation unit, a forcible stop switch, and a power supply unit connected to the power supply unit and receiving electric power from the power supply unit , and having a function of electrically braking the motor In an electric mower equipped with a control device,
The power supply unit is a storage battery and is detachable. By detecting whether or not the voltage supplied from the power supply unit is a certain level or more, it is possible to detect that the battery has dropped or the power supply from the battery has been interrupted. Power supply monitoring means,
The control device includes a motor drive unit, a control operation unit, and the power supply monitoring unit.
The motor drive unit switches the energization state to the drive coil of the motor,
The control operation unit is a circuit that generates a switching signal for switching the energization state of the drive coil ,
It is charged by energization from the power supply unit, and comprises a standby power source consisting of a storage battery or a capacitor that discharges when the energization from the power supply unit stops and maintains the control operation unit of the control device in an operable state,
When the voltage of the power supply unit drops, a stop signal is transmitted from the power supply monitoring means to the control operation unit, the drive coil is short-circuited, and the motor is forcibly stopped,
An electric mower characterized in that a signal of a forced stop switch is further input to the control operation unit, and the drive coil is short-circuited even when the forced stop switch is operated . The control device includes a control power supply unit,
The control power supply unit is a circuit that generates a signal voltage for causing the control operation unit to function,
2. The electric mower according to claim 1, wherein the standby power source maintains the control operation unit in an operable state by setting the control power source unit in an operable state . A motor drive unit that supplies power to the motor is provided, and a diode is provided between the standby power supply and the motor drive unit, and the diode prevents the current from flowing from the standby power supply side to the motor drive unit side. The electric mower according to claim 1 or 2, characterized in that

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