JPH0518900Y2 - - Google Patents

Description

[Detailed explanation of the idea] [Industrial application field]

This invention relates to a mower blade attachment device for a brush cutter, and more specifically, a attachment device that securely attaches the mower blade to the output shaft of the gear case of the brush cutter and also functions as a safety device in the event of overload. Regarding.

[Conventional technology]

In most of the conventionally known brush cutters, a small engine is attached to one end of the main operating rod as a power source, and the output of this engine is transmitted through a transmission shaft that passes through the inside of the main operating rod. is input to the gear case provided at the other end of the main operating rod.
The cutting blade is configured to be fastened and fixed by a cutting blade retainer attached to the output shaft of the gear case and a fastening washer for the cutting blade. More specifically, a disk-shaped cutting blade holder is integrally fixed to the output shaft, and the cutting blade that comes into close contact with the cutting blade holder is fitted into the output shaft, and a male threaded portion formed on the output shaft is formed. The cutting blade is tightened to the output shaft by screwing in a fixing nut to the output shaft.

[Problem that the idea aims to solve]

By the way, mower blades can rotate at high speeds of several thousand revolutions per minute, so if the mower blades fall off while rotating at high speeds, the mower blades may fly around while rotating and cause an unexpected accident. will occur. Therefore, the cutting blade is often fastened to the output shaft with a double nut for safety. Therefore, when installing or replacing the cutting blade, it is necessary to tighten and loosen the double nuts, which is very troublesome, and women and girls with little knowledge of machines may not be able to replace the cutting blade. Since the output shaft is rotated to the left, it is fastened with a left-hand thread, so if an inexperienced operator replaces the cutting blade, the fastening may not be done reliably, which is extremely dangerous. Therefore, with this invention, it is possible to attach and detach the cutting blade with a relatively simple operation.Moreover, the faster the cutting blade rotates, the tighter the cutting blade can be tightened, and in the case of overload, it can be used as a safety device. The purpose of this invention is to provide a mounting device having the following functions.

[Means to solve the problem]

In order to achieve the above objectives, this invention has an engine at one end of the main operating rod, a gear case at the other end, a cutting blade retainer attached to the output shaft of this gear case, and an output A mower blade attachment device for a brush cutter, which includes a mower blade clamping base attached to a shaft and attaching the mower blade between the mower blade retainer, the clamping base having an attachment portion for the output shaft;
A movable element that is housed in a storage space formed inside and moves by centrifugal force, and a friction plate that presses the cutting blade against the cutting blade retainer by the movement of the moving element,
The inner peripheral edge of the friction plate is fixed to a bearing that is fitted and fixed to the boss portion of the fastening table, and the friction plate is configured to frictionally fix the cutting blade when the rotation speed exceeds a predetermined number between the friction plate and the cutting blade restraint. It is characterized by the following structure.

[Effect]

In the mower blade mounting device of this invention, the slider housed in the internal space of the clamping base moves in the radial direction due to the centrifugal force generated by the high-speed rotation of the output shaft, and the friction plate rises due to this movement. When the cutting blade is strongly tightened against the cutting blade retainer and the rotation of the output shaft decreases, the tightening force also decreases as the centrifugal force decreases, and the relationship between the output shaft and the cutting blade becomes Become free.

【Example】

Embodiments of this invention will be described below with reference to the attached drawings. First, FIG. 1 is a partial cross-sectional view showing the cutting blade of a brush cutter and the output shaft portion of a gear case to which it is attached. Reference numeral 1 indicates a gear case that includes, for example, a reduction mechanism, and the lower surface of the gear case 1 has a A stepped output shaft 2 is protruded, and the output shaft 2 has a large diameter portion 2A near the gear case 1, and a small diameter portion 2B near the lower end thereof, and a spline groove is formed in the large diameter portion 2A. A left-handed male thread is formed in the small diameter portion 2B. Further, on the lower surface of the gear case 1, a disc-shaped cutting blade retainer 3 is fitted into a spline groove of the large diameter portion 2A and is placed in a closed state.
has a stepped portion 3 at the center of the flange portion 3A on its periphery.
It connects to the boss portion 3C via B. The diameter of this boss portion 3C is determined to fit into the center hole _X1 of the cutting blade X. A fastening table 4 is provided on the small diameter portion 2B of the output shaft 2.
The female threaded hole 4A serving as a mounting portion provided at the center is screwed into the threaded hole 4A. This fastening base 4
has a container shape with a gently curved lower surface 41, and a donut-shaped boss portion 42 is formed in the center, and the outer diameter of this boss portion 42 is equal to that of the cutting blade retainer 3. The outer diameter of the stepped portion 3B is slightly smaller than that of the stepped portion 3B, and the outer circumferential portion has a stepped portion 42A. Furthermore, a donut-shaped space is formed on the outer periphery of the boss portion 42, and the bottom surface becomes gradually shallower toward the outer periphery to form a tapered surface 43.
The outer periphery of the slider accommodating space 44 is a rim 45, and the fastening table 4 is attached to the output shaft 2 on the outer periphery of the rim 45.
An unevenness 45A is provided as a finger rest for screwing in and loosening. A donut-shaped leaf spring 5 as a friction plate is placed on the open surface of the slider housing space 44, and the inner peripheral edge 5A of this leaf spring 5 is the outer periphery of the bearing 6 fitted into the stepped portion 42A of the boss portion 42. The outer peripheral edge of the leaf spring 5 is in a free state, and is constantly trying to return to a flat state due to elasticity so as to fit into the stepped part 45B of the rim 45 of the fastening base 4, and , the rotation transmission of the output shaft 2 is insulated. In addition, a plurality of balls 7, rolls, wedges, etc. (not shown) as movers are accommodated in the mover accommodation space 44, and the diameter of the balls 7 is closer to the center of the mover accommodation space 44. The portion of the bearing 6 is dimensioned so that it hits the leaf spring 5 when moved in the outer circumferential direction along the tapered surface 43 without contacting the leaf spring 5, and a wedge effect can be expected. can be lined up in a line along the outer circumferential portion 6A. When the cutting blade X is attached to the output shaft ₂ , the center hole
C, and screw the female threaded hole 4A of the fastening base 4 into the small diameter part 2B of the output shaft 2, so that the flange part 3A of the cutting blade retainer 3 and the leaf spring 5 are in a fastened state. do. Since the rotational speed of the engine is not very high when the engine is started, even when the output shaft 2 rotates, no large centrifugal force is applied to the ball 7. It is in a floating state in proportion to the magnitude of the force. In this state, even if the output shaft 2 and the clamping base 4 are rotated, no rotational force is applied to the outer peripheral portion 6A of the bearing 6, and the cutting blade The plate spring 5 fixed to the outer circumference 6A of the bearing 6 is not in direct integral connection with the ball 7, but is in sliding contact with the plate spring 5, which is fixed to the outer circumference 6A of the bearing 6. No coupling force is generated between the spring 5 and the cutting blade X, and the spring 5 functions as a clutch. As the engine speed increases, the output shaft 2 also rotates at high speed, and the centrifugal force acting on the ball 7 increases, causing the ball 7 to move along the tapered surface 43 to the outer periphery of the slider housing space 44. Moving. The ball 7 is located between the tapered surface 43 and the leaf spring 5 and moves toward the outer circumference in proportion to the magnitude of the centrifugal force, so if a centrifugal force that exceeds the elasticity of the leaf spring 5 acts, in other words, the engine When the blade rotates at high speed, the leaf spring 5 is pushed up by the ball 7 against its own elasticity, and a strong frictional force is generated between the leaf spring 5 and the cutting blade X. This frictional force causes the output shaft 2 to ,
The cutting blade X is rotated integrally with the cutting blade retainer 3 and the fastening base 4. In the low rotational range of the engine, there is no centrifugal force acting on the ball 7 that strongly presses the leaf spring 5 against the cutting blade X, so there is a kind of centrifugal clutch between the cutting blade X and the output shaft 2. Due to the presence of the mechanism, the cutting blade X is in a low rotation state. Conversely, when the cutting blade As a result, the engine suddenly stops or the output drops to low rotation, so the centrifugal force disappears and the ball 7 moves in the direction of eliminating friction, locking only the cutting blade X and causing the engine to suddenly stop. It can prevent stoppages and absorb sudden increases in load. In particular, in the embodiment of this invention, an example of mounting the clamping base 4 to the output shaft 2 using screws was given, but it is of course possible to adopt a mounting method other than screws, and it is possible to securely mount the cutting blade X. The format does not matter as long as it can be obtained. The bottom surface of the slider housing space 44 of the fastening table 4, that is, the tape surface 43, is provided with a tape so that the ball 7 as a slider is stabilized inside the rim 45, as shown in FIGS. 4 and 5. It is also preferable to form small protrusions 45X along the inner surface of the rim 45 in accordance with the number of balls, so that each ball can stand independently when centrifugal force is acting on the balls 7. Further, as shown in FIGS. 6 to 8, small protrusions 43X for preventing the balls 7 from rolling are formed along the circumferential direction on the bottom surface of the slider housing space 44 in correspondence with the number of balls 7, It is also good to prevent the ball 7 from straying in the circumferential direction.

[Effect of the idea]

As is clear from the above explanation, the mowing blade attachment device of the brush cutter of this invention is attached to the output shaft to fasten the mower blade to the mower blade retainer. The periphery is fixed, and the space inside the clamping table is provided with a slider that expands to the outer periphery due to the action of centrifugal force.The movement of this slider due to centrifugal force causes the friction plate provided on the clamping table to move against the cutting blade. Since it is constructed so that it can be integrated with the output shaft and the fastening base by the frictional force generated by pressing, the following effects can be obtained. (a) Since the frictional force that fixes the cutting blade increases in proportion to the increase in engine output, the cutting blade can be fixed securely. (b) When the engine output is low, for example in an idling state, direct power transmission is cut off between the cutting blade and the output shaft by the bearing and friction plate, and the cutting blade is not in a forced drive state, so the cutting blade rotates together. The cutting blade does not rotate in the same way as the engine rotates when the engine starts, making it safe. (c) When the cutting blade is in the locked position, the cutting blade and
Even if the outer circumference of the bearing stops, the engine can maintain a low rotational speed, so this is an effective measure against engine overload. (d) The bearing has a cut function for transmitting rotational force between the output shaft and the cutting blade, making it easy to stop the rotation of the cutting blade.

[Brief explanation of drawings]

The attached drawings show an embodiment of this invention, in which Figure 1 is a side sectional view of the main part, Figure 2 is a sectional view of the fastening base, and Figure 3 is a sectional view of the fastening base.
4 is a plan view of another embodiment of the fastening base, FIG. 5 is a sectional view taken along the line 4--FIG. 6, and FIG. A plan view of the mounting base, FIG. 7 is a sectional view taken along the line of FIG. 6,
FIG. 8 is a sectional view taken along the line of FIG. 6. 1...Gear case, 2...Output shaft, 24...Large diameter section, 2B...Small diameter section, 3...Mower blade retainer, 3A...
...Flange part, 3B...Step part, 3C...Boss part,
4...Tightening base, 4A...Female screw hole, 41...Bottom surface, 42...Boss portion, 43...Tapered surface, 44...
...Mover housing space, 45...Rim, 45A...Irregularities, 5...Leaf spring, 6...Bearing, 6A...
Outer periphery, 7...Ball.

Claims (1)

[Scope of utility model registration request] The main operating rod has an engine at one end, a gear case at the other end, and a cutting blade holder attached to the output shaft of this gear case. A mower blade attachment device for a brush cutter, which includes a mower blade clamping base for attaching a mower blade, wherein the clamping base includes a mounting portion for the output shaft;
A movable element that is housed in a storage space formed inside and moves by centrifugal force, and a friction plate that presses the cutting blade against the cutting blade retainer by the movement of the moving element,
The inner peripheral edge of the friction plate is fixed to a bearing that is fitted and fixed to the boss portion of the fastening table, and the friction plate is configured to frictionally fix the cutting blade when the rotation speed exceeds a predetermined number between the friction plate and the cutting blade restraint. A mower blade attachment device for a brush cutter, characterized by the following configuration.