KR20110010079U - Electromotion Trim Scissors - Google Patents

Abstract

A fixed blade provided on the pruning shear body; A movable blade connected reciprocally with respect to said fixed blade; A drive motor capable of forward and reverse rotation; A first deceleration unit decelerating power of the driving motor in a primary manner; A second deceleration unit for decelerating power of the first deceleration unit to the second and transmitting the power to the movable blade; and a power control unit for selectively supplying power to the driving motor; A switching unit for selecting forward driving and reverse driving; And a motor controller configured to control an operation of the driving motor according to an operation signal of the switching unit, wherein the first reduction unit includes a planetary reducer, and the second reduction unit includes a first bevel gear provided on an output shaft of the planetary reducer. Wow; A second bevel gear rotatably installed on the body to be connected with a smaller gear ratio than the first bevel gear; A connection gear provided at a rotation center of the second bevel gear and integrally rotated; And a driven gear unit integrally provided at an outer circumference of the movable blade with a predetermined arc length and connected at a smaller gear ratio than the connecting gear, wherein the gear ratio of the first bevel gear and the second bevel gear is from 1: 2 to 2. 1: 4, the gear ratio of the connecting gear and the driven gear is characterized in that 1:30 to 1:40.
Thereby, the electric pruning shears which can rotate a machining blade with a smaller force can be provided.

Description

Electric pruning shears {Electromotion Trim Scissors}

The present invention relates to electric pruning shears, and more particularly to electric pruning shears that can automatically operate pruning shears.

Generally, in order to prun various crops or trees for fruit trees, landscaping, forests and flowers, tools such as pruning shears, saws, sickles and knives are used.

Conventional pruning shears are very time consuming because they rely solely on the manpower of the worker, and work capacity is inevitably deteriorated.

In consideration of this point, various electric pruning shears that are operated based on the power of the motor have been developed.

Accordingly, the present applicant has filed a patent application of the Korean Patent Application No. 2008-0014900 with automatic pruning shears that can provide a large cutting force with a small driving force by distributing the reduction load acting on the planetary reducer.

The automatic pruning shears previously applied are provided such that driven gears of the primary reduction portion and the secondary reduction portion that reduce the power of the driving motor are integrally formed inside the movable blade. Thus, there was a disadvantage in that the processing time increases when machining the movable blade equipped with the driven gear, and it was not easy to combine the connecting gear with the removable blade.

In addition, the rotation radius between the rotary shaft of the movable blade and the driven gear is short, there is an inconvenience that requires a large force to operate the movable blade.

It is an object of the present invention to provide automatic pruning shears with improved structure to reduce machining time by changing the position of the driven gear and to easily attach and detach the driven gear and the connecting gear in view of the above.

Electric pruning shears of the present invention for achieving the above object is fixed blade provided in the pruning shears body; A movable blade connected reciprocally with respect to said fixed blade; A drive motor capable of forward and reverse rotation; A first deceleration unit decelerating power of the driving motor in a primary manner; A second deceleration unit for decelerating power of the first deceleration unit to the second and transmitting the power to the movable blade; and a power control unit for selectively supplying power to the driving motor; A switching unit for selecting forward driving and reverse driving; And a motor controller configured to control an operation of the driving motor according to an operation signal of the switching unit, wherein the first reduction unit includes a planetary reducer, and the second reduction unit includes a first bevel gear provided on an output shaft of the planetary reducer. Wow; A second bevel gear rotatably installed on the body to be connected with a smaller gear ratio than the first bevel gear; A connection gear provided at a rotation center of the second bevel gear and integrally rotated; And a driven gear unit integrally provided at an outer circumference of the movable blade with a predetermined arc length and connected at a smaller gear ratio than the connecting gear, wherein the gear ratio of the first bevel gear and the second bevel gear is from 1: 2 to 2. 1: 4, the gear ratio of the connecting gear and the driven gear is characterized in that 1:30 to 1:40.

In the automatic pruning shears according to the embodiment of the present invention, since the driven gear is processed on the outer circumference of the movable blade, the processing time of the movable blade and the driven gear can be shortened.

In addition, since the driven gear is processed on the outer periphery of the movable blade, the coupling gear and the driven gear can be easily coupled, and the movable blade can be easily attached and detached.

In addition, since the radius of rotation from the rotary shaft of the movable blade to the driven gear is longer than that of the conventional movable blade, the movable blade can be driven with less force.

1 is a schematic diagram showing an electric pruning shears according to an embodiment of the present invention.
2 is a view showing a state in which the electric pruning shears of FIG. 1 operate in the forward direction.
3 is a front view of the electric pruning shears shown in FIG.
4 is a cutaway view of the electric pruning shears shown in FIG.
5 is a front view showing a state in which the cover member is removed in the state of FIG.
6 and 7 are views showing a state in which the movable blade is operated.
8 is a flow chart for explaining the operation of the electric pruning shears according to an embodiment of the present invention.

1, 2, 3, 4, 5, 6 and 7, automatic pruning shears according to an embodiment of the present invention, the fixed blade 20 is provided in the pruning shears body 10 And a driving blade 30 which is reciprocally connected to the fixed blade 20, a driving motor 40 capable of forward rotation and reverse rotation, and a power decelerating power of the driving motor 40. Power is supplied to the first reduction unit 50, the second reduction unit 60 to decelerate the power of the first reduction unit 50 to the movable blade 30, and to transfer the power to the movable blade 30. It includes a power supply control unit 70 for selectively supplying.

The body 10 may be formed of a metal material and may be divided into a first part 11 and a second part 13. The drive motor 40 and the first reduction unit 50 are connected to the first portion 11, and the second reduction unit 60 is installed at the second portion 13. The first part 11 and the second part 13 are integrally formed, and are formed to extend in a plate shape to the second part 13 in a vertical direction from one side of the first part 11 and the body 10. The cover member 80 is coupled to cover a portion of the body (10).

The fixed blade 20 is coupled to the end of the second portion 13 of the body 10 by screws or the like.

The movable blade 30 is coupled to the fixed blade 20 so as to be able to reciprocate a predetermined angle. The movable blade 30 is integrally formed on the outer periphery of the driven gear 67 is connected to the connection gear 65 of the second reduction portion 60 is driven and controlled by power. The movable blade 30 may be divided into a blade portion 31 and a body portion 33 based on the rotation shaft 35.

Body portion 33 is provided in a fan shape, the outer gear of the fan-shaped body portion 33, the driven gear 66 of the second reduction portion 60 is formed integrally with a predetermined length. In addition, a first positioning member 111 and a second positioning member 113 are provided at both end portions of the body portion 33 on which the driven gear 66 is formed.

The drive motor 40 is coupled to the first deceleration part 50. The drive motor 40 is preferably a stepping motor capable of forward or reverse driving in accordance with the control signal of the power control unit 70.

As the first reduction unit 50 is coupled to the drive motor 40, the power of the drive motor 40 is primarily decelerated in the first reduction unit 50.

Here, the exterior case 90 is coupled to the outside of the driving motor 40 and the first reduction gear 50. The exterior case 90 may be coupled to the first reduction unit 50 or coupled to the body 10. In addition, the exterior case 90 is provided with a switching unit 71 to be described later in the form of a button.

The first deceleration portion 50 preferably includes a planetary reducer. Therefore, the power of the driving motor 40 can be stably decelerated and transmitted to the second deceleration part 60. Here, since the configuration of the first reduction unit 50 can be easily understood through the configuration of the planetary reducer that is generally used, a detailed description thereof will be omitted.

The second deceleration unit 60 is for rotationally driving the movable blade 30 by secondly decelerating the power of the first deceleration unit 50.

The second deceleration part 60 is connected to the first bevel gear 61 provided on the output shaft 51 of the first deceleration part (wire reducer) 50 at a smaller gear ratio than the first bevel gear 61. A second bevel gear 63 rotatably installed at the second portion 13 of the body 10 and a connecting gear 65 integrally rotated at a rotation center of the second bevel gear 63. And a driven gear part 67 provided integrally with the outer circumference of the movable blade 30 and connected at a gear ratio smaller than that of the connecting gear 65.

The gear ratio of the first bevel gear 61 and the second bevel gear 63 is provided to be between 1: 2 to 1: 4, more preferably has a gear ratio of 1: 3.

The connecting gear 65 is installed at the center of rotation of the second bevel gear 63, and preferably formed integrally with the second bevel gear 63. Therefore, since the connecting gear 65 is rotated integrally with the second bevel gear 63, the rotation ratio with the second bevel gear 63 is 1: 1.

The driven gear part 67 is provided on the outer circumference of the movable blade 30 so as to be connected to the connection gear 65 and receive power. Preferably, the driven gear 67 is formed integrally with the body portion 33 of the movable blade (30). In particular, the driven gear 67 is formed on the outer periphery of the body portion 33, it can be easily attached and detached with the connecting gear (67).

At this time, the movable blade 30 can be driven by a relatively small force because the length of the rotating shaft 35 and the driven gear 67 is longer than in the prior art.

Here, the gear ratio between the connecting gear 65 and the driven gear part 67 is preferably 1:30 to 1:40.

As described above, by configuring the second deceleration part 60 in a structure in which a plurality of gears are connected, the deceleration load acting on the first deceleration part 50 can be distributed to the second deceleration part 60. Therefore, even when the first reduction unit 50 having a small capacity can be applied, the battery operation can be performed without failure or defect, thereby reducing the cost of employing an expensive planetary reducer.

In addition, the decelerating load is distributed through the second deceleration part 60, and the power is transmitted to the movable blade 30 at an operating point spaced apart from the first deceleration part 50, thereby providing a large load on the movable blade 30. Even if it is possible to easily overcome this and perform the battery operation.

The power controller 70 may include a switching unit 71 for selecting forward driving and reverse driving of the driving motor 40 and an operation of the driving motor according to an operation signal of the switching unit 71. And a motor control unit 73 for controlling the control unit.

The switching unit 71 has an operation button 71a provided in the exterior case 90. The switching signal generated during the pressing operation of the operation button 71a is transmitted to the motor controller 73.

The motor controller 73 may control forward driving and reverse driving of the driving motor 40 based on the switching signal transmitted from the switching unit 71.

That is, the motor controller 73 forwardly rotates the drive motor 40 to rotate the movable blade 30 in the forward direction A during the signal input operation of the switching unit 71 (when the operation button is pressed). When the signal input operation of the switching unit 71 is released (when the operation button is released), the driving motor 40 is rotated in reverse to control the movable blade 30 to be rotated in the reverse direction (B) to its original position. do. Therefore, the motor control unit 73 drives the drive motor 40 forward by the operation of the switching unit 71 so that the input signal of the switching unit 71 can be driven even when the movable blade 30 is not rotated to the end in the A direction. As soon as is released, the drive motor 40 can be reversed and driven in the reverse direction to return the movable blade 30 rotated in the A direction to the B direction. Therefore, even if the worker detects a dangerous situation or wrong operation at the moment of operating the switching unit 71 or hits another object or the like, the direction of the movable blade 30 is released immediately after the operation of the switching unit 71 is released. Since it can be reversed, problems caused by safety accidents or malfunctions can be solved.

In this case, the motor control unit 73 may automatically control the driving of the driving control signal of the driving motor 40 according to the operation of the switching unit 71 through a pre-programmed and stored motor driving driver.

In FIG. 1, reference numeral 100 denotes a power supply unit, that is, a battery, and is connected to the power control unit 70 through a cable.

In addition, the position detection sensor 110 for detecting each of the initial position and the movable limit position of the movable blade 30 is provided. The motor control unit 73 controls the stop operation of the driving motor 40 based on the information transmitted from the position sensor 110.

The position sensor 110, the first and second positioning member 111, 113 and the body 10 are provided on opposite sides symmetrical to each other on the outer periphery of the body portion 33 of the movable blade 30, the body 10 The first and second sensing parts 115 and 117 provided to cover the cover member 80 coupled to cover the first and second positioning members 111 and 113 so as to face each of the positioning members 111 and 113. ).

Here, the first and second positioning members 111 and 113 may include a magnet attached to the body portion 33 of the movable blade 30.

In addition, the first and second detection units 115 and 117 may include a magnetic monitoring sensor capable of detecting the magnet. The first and second detection units 115 and 117 are provided on the inner surface of the cover member 80, that is, the surface facing the body 10, in the form of a hall sensor, and as much as the maximum rotation angle of the movable blade 30. Each is provided at a spaced position.

The operation of the electric pruning shears of the present invention having the above configuration will be described in detail with reference to FIGS. 1 to 8.

First, the electric pruning shears are kept in an initial state as shown in FIG. 1 before use. In this state, the motor controller 73 confirms that a switch ON signal is input (S10). That is, when the user presses the operation button 71a of the switching unit 71, the motor control unit 73 receives the switch-on signal to drive the driving motor 40 forward rotation (S11). Then, the power of the drive motor 40 is transmitted to the movable blade 30 through the first and second reduction gears 50 and 60 in stages so that the movable blade 30 is shown in FIGS. 2 and 6. , The cutting operation can be performed while rotating in the A direction.

At this time, since the driven gear 67 is rotated according to the rotation of the connecting gear 65, the movable blade 30 is integrally formed with the driven gear 67 is rotated to perform a cutting operation.

When the user releases the state of pressing the operation button 71a in the middle of driving the driving motor 40 in the forward direction as described above, the motor controller 73 confirms that the switching is OFF (S12), and the driving motor ( 40 is driven in the reverse direction (S13). Therefore, even when the movable blade 30 moves in the A direction, if the hand held down the operation button 71a is released, it can return to the state of FIG.

In addition, the motor controller 73 checks whether the signal detected by the first position setting member 111 is input from the first detection unit 115 of the position sensor 110 while driving the driving motor 40 in reverse direction. S14), if the detection signal is confirmed, the driving of the driving motor 40 is stopped (S15). The movable blade 30 is then maintained in the initial state as shown in FIG.

On the other hand, if the switch off (OFF) signal is not input while performing the step (S11), it is determined whether the signal detected by the second sensing member 113 in the second sensing unit 117 is input When it is confirmed (S16) that the detection signal is input, the driving motor 40 is stopped (S17). Then, the movable blade 30 is completely rotated in the A direction to maintain the finished state of the battery operation, thereby bringing the state as shown in FIG.

When the user releases the operation button 71a in the step 17, the motor control unit 73 confirms that the switch OFF signal is input (S12), and the following steps (S13, S14, S15) ) Can be performed sequentially to return the movable blade 30 to the initial position.

As described above, in the automatic pruning shears according to the embodiment of the present invention, since the driven gear is processed on the outer circumference of the movable blade, the processing time of the movable blade and the driven gear can be shortened.

In addition, since the driven gear is processed on the outer periphery of the movable blade, the coupling gear and the driven gear can be easily coupled, and the movable blade can be easily attached and detached.

In addition, since the radius of rotation from the rotary shaft of the movable blade to the driven gear is longer than that of the conventional movable blade, the movable blade can be driven with less force.

10. pruning shears body 20. fixed blade
30. Operation day 40. Driving motor
50. 1st reduction gear 60. 2nd reduction gear
70. Power control 71. Switching part
73. Motor control part 80. Cover member
90. Exterior Case 100. Battery
110. Position sensor 111,113 First and second position setting member
115,117.1st and 2nd detection part

Claims (1)

A fixed blade provided on the pruning shear body;
A movable blade connected reciprocally with respect to said fixed blade;
A drive motor capable of forward and reverse rotation;
A first deceleration unit decelerating power of the driving motor in a primary manner;
A second deceleration unit for decelerating power of the first deceleration unit to the second and transmitting the power to the movable blade;
And a power controller selectively supplying power to the driving motor.
The power control unit,
A switching unit for selecting forward driving and reverse driving of the motor according to an operating state;
And a motor controller for controlling the operation of the driving motor according to the operation signal of the switching unit.
The first reduction gear includes a planetary reducer,
The second deceleration part,
A first bevel gear provided on the output shaft of the planetary reducer; A second bevel gear rotatably installed on the body to be connected with a smaller gear ratio than the first bevel gear; A connection gear provided at a rotation center of the second bevel gear and integrally rotated; And a driven gear part integrally provided at an outer circumference of the movable blade with a predetermined arc length and connected with a gear ratio smaller than that of the connecting gear.
The gear ratio between the first bevel gear and the second bevel gear is 1: 2 to 1: 4, and the gear ratio of the connecting gear and the driven gear is 1:30 to 1:40.

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