JP7502777B2 - Rotating body and brush cutter - Google Patents

Description

The present disclosure relates to a rotating body and a brush cutter .

Conventionally, mowing work has been performed using a linear cutter made of nylon or the like. To perform such mowing work, a rotating body to which the linear cutter is attached is connected to the drive shaft of the brush cutter body, and the rotating body is rotated together with the drive shaft. This allows the tip of the linear cutter, which is pulled out radially outward from the rotating body, to cut the surrounding grass (see, for example, International Publication No. WO 2015/037030).

In the above-mentioned rotating body, the tip of the linear cutter gradually wears away, so when the linear cutter wears out, it is necessary to remove it from the rotating body and attach a new linear cutter to the rotating body.

An object of the present disclosure is to provide a rotating body and a brush cutter that enable a linear cutter to be used for a long period of time and that allows the linear cutter to be easily replaced when it is time to replace it.

The rotating body according to one aspect of the present disclosure includes a support case and a bobbin. The support case is connected to a drive shaft of a brush cutter body and rotates together with the drive shaft. The bobbin is removably attached to the support case and rotates together with the drive shaft and the support case. The support case has a cylindrical portion into which the drive shaft is inserted, a flange portion extending radially outward from a lower portion of the cylindrical portion, and a plurality of pull-out holes formed through the flange portion. The bobbin has an inner peripheral surface that detachably abuts against the outer peripheral surface of the cylindrical portion, and an outer peripheral surface facing the opposite side to the inner peripheral surface and around which a flexible linear cutter is wound. The bobbin is configured such that, when the bobbin is attached to the cylindrical portion such that the inner peripheral surface abuts against the outer peripheral surface of the cylindrical portion, both ends of the linear cutter wound around the outer peripheral surface are pulled out radially outward through two of the plurality of pull-out holes.

A brush cutter according to one aspect of the present disclosure includes the rotating body and the brush cutter body having the drive shaft to which the rotating body is connected.

The bobbin according to one aspect of the present disclosure is a bobbin that is removably attached to a rotating body that rotates integrally with the drive shaft of the brush cutter body, and includes a cylindrical bobbin body, an inner peripheral surface of the bobbin body that is arranged to be removably in contact with the rotating body, and an outer peripheral surface of the bobbin body that faces the opposite side to the inner peripheral surface and is arranged so that a flexible linear cutter can be wound around it.

FIG. 1 is a top view of a rotating body having a linear cutter wound therearound according to an embodiment. FIG. 2 is a top view of a support case provided on the rotating body. FIG. 3 is a cross-sectional view taken along line AA of FIG. FIG. 4 is a top view of the rotary body having a bobbin wound with a linear cutter. FIG. 5 is a bottom view of the bobbin with a linear cutter wound thereon. FIG. 6 is a top view of the bobbin. FIG. 7 is a cross-sectional view taken along line BB in FIG. FIG. 8 is a view taken along the arrow C in FIG. FIG. 9 is a perspective view of a brush cutter equipped with the above-mentioned rotor. FIG. 10 is a perspective view of the brush cutter equipped with the above rotor and rotary blade. FIG. 11 is a top view of a modified example of the rotor of the above embodiment, in which a linear cutter is wound around the rotor.

(One embodiment)
The present disclosure will be described based on the embodiments shown in the accompanying drawings.

Figure 1 shows a rotating body 1 according to one embodiment. A linear cutter 8 is wound around the rotating body 1. The rotating body 1 is attached to the brush cutter body 90 and used for mowing grass (see Figure 9, etc.).

In one embodiment, the rotating body 1 is a grounding body 10 that is connected to the drive shaft 905 (see FIG. 3) of the brush cutter body 90. The brush cutter body 90 and the rotating body 1 (i.e., the grounding body 10) form the brush cutter 9.

The brush cutter body 90 includes a main shaft 902, a gear box 903 provided at the tip of the main shaft 902, and a drive shaft 905 (see FIG. 3) protruding from the gear box 903. A handle 907 is provided midway along the main shaft 902. An engine 908, which serves as a drive source, is mounted at the rear end of the main shaft 902. A battery may be mounted as a drive source instead of the engine 908.

The output of the drive source (i.e., engine 908) is transmitted to the drive shaft 905, and the rotor 1 is rotated integrally with the drive shaft 905. The rotor 1 can rotate stably while in contact with the ground surface, and grass is cut by both ends 81, 82 of a linear cutter 8 made of synthetic resin that is pulled out from the outer surface of the rotor 1. The linear cutter 8 is, for example, a nylon cord. It is preferable that the surface of the linear cutter 8 is formed with a spiral unevenness.

The rotating body 1 comprises a support case 2 (see Figures 2, 3, etc.) having a circular outer shape in a plan view, and a bobbin 3 (see Figures 4 to 8, etc.) having an annular outer shape in a plan view. A flexible linear cutter 8 is wound around the bobbin 3. The bobbin 3 is detachably attached to the support case 2, which opens upward, from above the support case 2. In other words, the bobbin 3 is a cartridge around which the linear cutter 8 is wound.

The plan view above refers to the rotor 1 as seen from above. The directions such as up and down used in this disclosure are based on the case where the central axis C1 (see Figures 3 and 9) of the rotor 1 is set to extend vertically during actual use.

First, we will explain the support case 2 in detail.

The support case 2 is connected to the drive shaft 905 of the brush cutter body 90 and is configured to rotate integrally with the drive shaft 905. The support case 2 has a cylindrical portion 21, a bowl-shaped flange portion 23 extending radially outward from the lower portion 212 of the cylindrical portion 21, and a metal fitting 28 connected to the upper portion 211 of the cylindrical portion 21. More specifically, the lower portion 212 of the cylindrical portion 21 is the lower end portion of the cylindrical portion 21. In this disclosure, the radial outer side and the opposite radial inner side are defined based on the central axis C1 of the rotating body 1. The central axis C1 of the rotating body 1 is, in other words, the central axis of the support case 2 and the bobbin 3. Furthermore, in this disclosure, the circumferential direction and the axial direction are defined based on the central axis C1 of the rotating body 1.

The cylindrical portion 21, flange portion 23, and metal fitting 28 will be described in order.

The tubular portion 21 is a cylindrical portion molded from a synthetic resin material, and has an inner circumferential surface 21A and an outer circumferential surface 21B. The inner circumferential surface 21A and the outer circumferential surface 21B face in opposite directions. The internal space of the tubular portion 21 is open downward. A metal fitting 28, which is annular in plan view, is firmly connected to the upper portion 211 of the tubular portion 21 by insert molding. More specifically, the upper portion 211 of the tubular portion 21 is the upper end portion of the tubular portion 21.

The outer peripheral surface 21B is formed with an annular step 214 on which the bobbin 3 can be placed, and multiple vertical grooves 218 that can guide the attachment and detachment of the bobbin 3.

The cylindrical portion 21 is divided by a step 214 into an upper cylindrical portion 213 and a lower cylindrical portion 215, which has a larger outer diameter. The outer peripheral surface of the upper cylindrical portion 213 forms the upper part of the outer peripheral surface 21B of the cylindrical portion 21, and the outer peripheral surface of the lower cylindrical portion 215 forms the lower part of the outer peripheral surface 21B of the cylindrical portion 21. The multiple vertical grooves 218 are four vertical grooves 218 formed at a distance apart in the circumferential direction on the outer peripheral surface of the upper cylindrical portion 213. Each vertical groove 218 has a semicircular opening cross-section.

The flange portion 23 is molded from a synthetic resin material so as to extend radially outward from the entire circumference of the lower portion 212 of the cylindrical portion 21. The flange portion 23 is molded integrally with the cylindrical portion 21. The flange portion 23 is molded in an overall bowl shape so that the radially outer portion is positioned higher.

The lower surface of the flange portion 23 is the ground contact surface 231 that rubs against the ground surface. The ground contact surface 231 is a smoothly curved convex surface. The surface 232 of the flange portion 23 facing the opposite side to the ground contact surface 231 is a smoothly curved concave surface. A number of recesses 233 are formed on the surface 232 to indicate that it is time to replace the flange portion 23. Each recess 233 is non-penetrating, but is configured to penetrate the flange portion 23 when the flange portion 23 has worn down to a certain extent.

A step 234 that is annular in plan view is formed in the upper and lower middle portions of the surface 232 of the flange portion 23. The upper surface of the step 234 is located higher than the upper surface of the step 214 of the tubular portion 21.

A plurality of pull-out holes 230 are formed through the upper portion of the flange portion 23 (specifically, the portion above the step portion 214). The plurality of pull-out holes 230 are four pull-out holes 230 formed at intervals in the circumferential direction. Each pull-out hole 230 penetrates the flange portion 23 in the radial direction so that the linear cutter 8 can be inserted therethrough.

A number of guide members 236 are provided on the surface 232 of the flange portion 23 above the step portion 234. The number of guide members 236 is four, which are provided radially inward of the four withdrawal holes 230. Each guide member 236 has a guide groove 237 that communicates with the corresponding withdrawal hole 230. The guide groove 237 has guide surfaces 238 that are curved in a convex shape on both circumferential sides. A portion of each guide member 236 protrudes radially inward from the step portion 234.

A groove 239 is formed around the entire circumference of the upper part of the outer periphery of the flange portion 23. The openings of the four pull-out holes 230 are located at the bottom of the groove 239. The groove 239 is a portion that guides the linear cutter 8 so that the linear cutter 8 is stably wound around the outer periphery of the flange portion 23 when the rotor 1 rotates at high speed.

The metal fitting 28 is configured so that the drive shaft 905 of the brush cutter body 90 is inserted therethrough and is connected to the drive shaft 905 using a fastening means. The metal fitting 28 has an insertion hole 285 in its central portion through which the drive shaft 905 is inserted, and has stepped through holes 286 at multiple locations surrounding the insertion hole 285. The through holes 286 are formed at multiple locations spaced apart in the circumferential direction on the upper surface of the metal fitting 28. The synthetic resin portion of the cylindrical portion 21 is filled into each through hole 286, thereby firmly connecting the metal fitting 28 to the cylindrical portion 21.

The means for connecting the cylindrical portion 21 and the metal fitting 28 is not limited to insert molding. The cylindrical portion 21 and the metal fitting 28 may be connected by other means such as press fitting or screw fixing as long as they are connected so that they rotate together.

Abutment ribs 282 that are higher than the others are formed on the upper surface of the metal fitting 28 between the circumferentially adjacent through holes 286. These abutment ribs 282 stably abut against the receiving metal fitting 906 (see FIG. 3) attached to the drive shaft 905.

The tip of the drive shaft 905 protrudes downward through the insertion hole 285 of the metal fitting 28 and is housed inside the cylindrical portion 21. A nut 909 is tightened from below the cylindrical portion 21 onto the portion of the drive shaft 905 housed inside the cylindrical portion 21. This connects the support case 2 and thus the entire rotating body 1 to the drive shaft 905.

Next, we will explain the bobbin 3 in detail.

The bobbin 3 is a synthetic resin member that is configured to rotate integrally with the drive shaft 905 and the support case 2 when attached to the support case 2. The bobbin 3 is a cylindrical member that has an inner peripheral surface 3A and an outer peripheral surface 3B that face in opposite directions. The inner peripheral surface 3A is a concave curved surface that faces radially inward, and the outer peripheral surface 3B is a convex curved surface that faces radially outward.

The bobbin 3 has a cylindrical bobbin body 30, a plurality of protrusions 31 extending radially outward from an upper portion 301 of the bobbin body 30, and a plurality of protrusions 32 extending radially outward from a lower portion 303 of the bobbin body 30. Hereinafter, the plurality of protrusions 31 will be referred to as upper protrusions 31, and the plurality of protrusions 32 will be referred to as lower protrusions 32.

The inner circumferential surface 3A of the bobbin body 30 is configured to detachably abut against the outer circumferential surface 21B of the cylindrical portion 21.

The bobbin body 30 is formed with a number of guide portions 36 that protrude radially inward, a number of elastic bodies 33 formed at locations in the circumferential direction different from the number of guide portions 36, and a number of grooves 34 formed on the radial outside of each of the number of elastic bodies 33. The number of elastic bodies 33 are a number of protrusions made of elastic synthetic resin. The number of elastic bodies 33 are molded integrally with the portion of the bobbin body 30 excluding the number of elastic bodies 33.

The guide portions 36 are a plurality of ridges 361 configured to guide the attachment of the bobbin 3 to the cylindrical portion 21. The plurality of ridges 361 are four ridges 361 spaced apart in the circumferential direction. The surfaces of the four ridges 361 facing radially inward form part of the inner peripheral surface 3A. The four ridges 361 are each formed in a straight line in the axial direction and are parallel to one another. Each ridge 361 is formed in a semicircular cross section so as to slidably fit into one of the four vertical grooves 218 of the cylindrical portion 21 in the axial direction.

The multiple elastic bodies 33 are four elastic bodies 33 positioned at a distance in the circumferential direction. In the bobbin 3, the four elastic bodies 33 and the four protrusions 361 are positioned alternately in the circumferential direction. Each elastic body 33 has a pressing surface 332 that elastically presses against the outer circumferential surface 21B of the tubular portion 21 when the bobbin 3 is attached to the tubular portion 21. The pressing surface 332 of each elastic body 33 constitutes a part of the inner circumferential surface 3A. In other words, a part of the inner circumferential surface 3A is configured to elastically press against the outer circumferential surface 21B of the tubular portion 21.

Each elastic body 33 is a protruding piece-like projection formed to stand upright (see FIG. 7). When the bobbin 3 is not attached to the cylindrical portion 21, a portion of each elastic body 33 (specifically, the upper portion) protrudes radially inward further than the other portions. The surface of this portion facing radially inward is the pressing surface 332 that elastically presses against the outer peripheral surface 21B. The pressing surface 332 is inclined so that the upper portion is positioned radially inward.

The multiple grooves 34 are four grooves 34 positioned at a distance in the circumferential direction. Each of the four grooves 34 is positioned radially outward of a corresponding one of the four elastic bodies 33, allowing the corresponding elastic body 33 to bend radially outward. Each elastic body 33 can bend radially outward because the groove 34 is formed on its own radially outward side.

The outer peripheral surface of the bobbin body 30 is the outer peripheral surface 3B configured to allow the flexible linear cutter 8 to be wound around it. In a plan view (in other words, when viewed along the central axis C1), the multiple upper protrusions 31 and the multiple lower protrusions 32 are positioned alternately in the circumferential direction.

The upper protrusions 31 are four upper protrusions 31 that are spaced apart in the circumferential direction. All four upper protrusions 31 are rectangular flat protrusions, but may have other shapes.

A hook groove 315 is formed at the radially outer end of each of the four upper protrusions 31. The hook groove 315 has an L-shaped notch cut out from the radially outer end of the upper protrusion 31. The hook groove 315 is configured so that one of the ends 81, 82 on both sides of the linear cutter 8 can be hooked onto it. Note that the hook groove 315 only needs to be formed in at least two of the four upper protrusions 31.

As shown in FIG. 6 etc., the elastic body 33 and the groove 34 are located on the radial inside of each of the four upper protrusions 31. In other words, the elastic body 33 and the groove 34 for deflecting it are located on the radial inside of the corresponding upper protrusion 31 among the four upper protrusions 31. In one embodiment of the rotating body 1, the elastic body 33 and the groove 34 are located on the radial inside of all four upper protrusions 31, but it is sufficient that the elastic body 33 and the groove 34 are located on the radial inside of at least one of the four upper protrusions 31.

The multiple lower protrusions 32 are four lower protrusions 32 formed at intervals in the circumferential direction. All four lower protrusions 32 are rectangular flat protrusions, but may have other shapes.

A pair of hook holes 325 are formed in two of the four lower protrusions 32. The pair of hook holes 325 are a pair of round holes formed through the radially inner end of the lower protrusion 32. The pair of hook holes 325 are positioned side by side in the circumferential direction. The pair of hook holes 325 are configured so that the linear cutter 8 can be inserted through them and the central portion 85 can be hooked. Note that it is sufficient that the pair of hook holes 325 is formed in at least one of the four lower protrusions 32.

In the rotating body 1 of the embodiment described above, the bobbin 3 before being attached to the support case 2 is provided in the state shown in Figures 4 and 5. That is, in the bobbin 3 before attachment, the central portion 85 of the linear cutter 8 is hooked on a pair of hook holes 325, and the remaining portion of the linear cutter 8 except for the central portion 85 is wound multiple times around the outer circumferential surface 3B of the bobbin 3. The direction in which the linear cutter 8 is wound is indicated, for example, by an arrow on the upper surface of at least one of the four upper protrusions 31 (in the bobbin 3 of the embodiment, the upper surfaces of the two upper protrusions 31 located on opposite sides of each other with respect to the central axis C1). Furthermore, both ends 81, 82 of the linear cutter 8 are respectively hooked on the hook grooves 315 of the two upper protrusions 31 located on opposite sides of each other with respect to the central axis C1.

When the bobbin 3 is inserted from above into the cylindrical portion 21 of the support case 2, each of the multiple elastic bodies 33 that the bobbin 3 has at intervals in the circumferential direction is elastically pushed outward in the radial direction while rubbing against the outer circumferential surface 21B of the cylindrical portion 21. Therefore, when the bobbin 3 is attached to the support case 2, the bobbin 3 is stably held in the support case 2 by the action of the frictional force acting between the multiple elastic bodies 33 and the cylindrical portion 21. In other words, each elastic body 33 elastically pressing against the outer circumferential surface 21B of the cylindrical portion 21 generates a biasing force for holding the bobbin 3 in the support case 2.

With the bobbin 3 attached to the support case 2, both ends 81, 82 of the linear cutter 8 are removed from the hook grooves 315. After that, both ends 81, 82 of the linear cutter 8 are pulled outward by an appropriate length through the corresponding pull-out holes 230. As a result, both ends 81, 82 of the linear cutter 8, which are wound multiple times around the outer circumferential surface 3B of the bobbin 3, are pulled outward in the radial direction through two of the four pull-out holes 230.

In this state, the drive shaft 905 of the brush cutter body 90 is inserted into the inside of the cylindrical portion 21 through the insertion hole 285 of the metal fitting 28. Inside the cylindrical portion 21, a nut 909 is tightened around the drive shaft 905, firmly connecting the drive shaft 905 to the support case 2. As shown in FIG. 3, the gear box 903 of the brush cutter body 90 is positioned so as to cover the top of a portion of the radially inner side of the bobbin 3 (specifically, at least a portion of the bobbin body 30). This prevents the bobbin 3 from coming off during operation.

According to the rotating body 1 of the embodiment described above, when the portion of the linear cutter 8 that is pulled out from the pull-out hole 230 becomes shorter due to wear, that portion can be pulled out from another pull-out hole 230. This allows a single linear cutter 8 wound around the bobbin 3 to be used for a long period of time without replacing the bobbin 3 itself.

In addition, according to one embodiment of the rotating body 1, when replacing the linear cutter 8 together with the bobbin 3, the replacement work can be easily performed. Specifically, after removing the nut 909 from the drive shaft 905 and pulling the drive shaft 905 out of the support case 2, the bobbin 3 can be grasped by hand and easily removed from the support case 2. At this time, the worker can insert his/her fingers into the space between the multiple upper protrusions 31 and grasp the bobbin body 30 together with the wound linear cutter 8. Next, another bobbin 3 with another wound linear cutter 8 can be easily attached to the support case 2.

During the replacement operation, regardless of the position of the support case 2 (for example, even if the support case 2 is upside down), the bobbin 3 is stably held to the support case 2 by the elastic holding force exerted by the multiple elastic bodies 33. This prevents the bobbin 3 from accidentally falling off the support case 2, and also makes it easy to remove the bobbin 3 from the support case 2.

In one embodiment, the rotor 1 is directly connected to the drive shaft 905, but it is also possible to sandwich the rotary blade 5 between the rotor 1 and the drive shaft 905 (see FIG. 10). In this case, the rotary blade 5 is sandwiched between a receiving metal fitting 906 attached to the drive shaft 905 and a metal fitting 28 of the support case 2. By rotating the drive shaft 905 in this state and rotating the rotor 1 and the rotary blade 5 together, it is possible to simultaneously perform grass cutting work with the linear cutter 8 and grass cutting work with the rotary blade 5.

(Modification)
While the present disclosure has been described above based on the embodiments shown in the accompanying drawings, the present disclosure is not limited to the above-described embodiments.

For example, as in the modified example shown in FIG. 11, the multiple guide portions 36 of the bobbin 3 can be formed in a concave shape rather than a convex shape. In this modified example, the multiple guide portions 36 are multiple vertical grooves 365 configured to guide the attachment of the bobbin 3 to the cylindrical portion 21. The multiple vertical grooves 365 are four vertical grooves 365 positioned at intervals in the circumferential direction, and each of them constitutes a part of the inner circumferential surface 3A. Each of the four vertical grooves 365 is formed in a straight line in the axial direction and is parallel to one another.

In this modified example, multiple ridges 219 are formed on the outer circumferential surface 21B of the cylindrical portion 21, and are configured to guide the attachment and detachment of the bobbin 3. The multiple ridges 219 are four ridges 219 formed at intervals in the circumferential direction on the outer circumferential surface of the upper cylindrical portion 213. Each ridge 219 fits axially slidably into one of the four vertical grooves 365, thereby guiding the attachment of the bobbin 3 to the cylindrical portion 21.

As for other configurations, appropriate design changes can be made within the scope of the intent of this disclosure. For example, the materials of each configuration described above are merely examples, and the bobbin 3 can be made of a material other than resin, such as paper, and the support case 2 can be made of a material other than resin, such as metal. It is also possible not to provide the metal fittings 28 on the support case 2, and it is also possible to use the support case 2 without contacting the ground.

(Aspects)
As described above based on the embodiment, the rotating body (1) of the first aspect has the following configuration. The rotating body (1) of the first aspect includes a support case (2) that is connected to a drive shaft (905) of a brush cutter body (90) and rotates integrally with the drive shaft (905), and a bobbin (3) that is detachably attached to the support case (2) and rotates integrally with the drive shaft (905) and the support case (2). The support case (2) has a cylindrical portion (21) through which the drive shaft (905) is inserted, a flange portion (23) that extends radially outward from a lower portion (212) of the cylindrical portion (21), and a plurality of pull-out holes (230) that are formed through the flange portion (23). The bobbin (3) has an inner peripheral surface (3A) that detachably abuts against the outer peripheral surface (21B) of the cylindrical portion (21), and an outer peripheral surface (3B) that faces the opposite side to the inner peripheral surface (3A) and around which a flexible linear cutter (8) is wound. The bobbin (3) is configured such that, when the bobbin (3) is attached to the cylindrical portion (21) such that the inner peripheral surface (3A) abuts against the outer peripheral surface (21B) of the cylindrical portion (21), both ends (81, 82) of the linear cutter (8) wound around the outer peripheral surface (3B) are pulled out radially outward through two of the multiple pull-out holes (230).

According to the first embodiment of the rotating body (1), the linear cutter (8) wound around the bobbin (3) can be used for a long period of time by appropriately selecting and changing which two of the multiple pull-out holes (230) the ends (81, 82) of the linear cutter (8) are pulled out from. Moreover, when replacing the linear cutter (8), the entire bobbin (3) can be easily removed from the support case (2), making it easy to replace the linear cutter (8).

The rotating body (1) of the second embodiment has the following configuration in addition to the configuration of the rotating body (1) of the first embodiment. In the rotating body (1) of the second embodiment, the bobbin (3) further has an elastic body (33) that elastically presses against the outer circumferential surface (21B) of the cylindrical portion (21) when attached to the cylindrical portion (21).

According to the second embodiment of the rotating body (1), the bobbin (3) is stably held to the support case (2) by the elastic holding force exerted by the multiple elastic bodies (33), regardless of the position of the support case (2). This prevents the bobbin (3) from accidentally falling off the support case (2). Moreover, the bobbin (3) can be easily removed from the support case (2).

The rotating body (1) of the third aspect has the following configuration in addition to the configuration of the rotating body (1) of the second aspect. In the rotating body (1) of the third aspect, the bobbin (3) further has a groove (34) that allows the elastic body (33) to bend radially outward.

According to the third aspect of the rotating body (1), the elastic body (33) can bend radially outward when it comes into contact with the outer circumferential surface (21B) of the cylindrical portion (21), so that the elastic body (33) can apply an appropriate elastic force to the cylindrical portion (21).

The rotating body (1) of the fourth aspect has the following configuration in addition to the configuration of the rotating body (1) of the second aspect. In the rotating body (1) of the fourth aspect, the bobbin (3) has multiple elastic bodies (33) spaced apart in the circumferential direction.

According to the fourth aspect of the rotating body (1), the multiple elastic bodies (33) come into contact with multiple points on the outer circumferential surface (21B) of the cylindrical portion (21) that are spaced apart in the circumferential direction, so that the bobbin (3) is stably held against the support case (2).

The rotating body (1) of the fifth aspect has the following configuration in addition to the configuration of the rotating body (1) of the fourth aspect. In the rotating body (1) of the fifth aspect, the bobbin (3) further has a plurality of grooves (34) that allow each of the plurality of elastic bodies (33) to bend radially outward.

According to the fifth aspect of the rotating body (1), each of the multiple elastic bodies (33) can bend radially outward when it comes into contact with the outer circumferential surface (21B) of the cylindrical portion (21), so that the multiple elastic bodies (33) can apply an appropriate elastic force to the cylindrical portion (21).

The sixth aspect of the rotating body (1) has the following configuration in addition to the configuration of the rotating body (1) of any one of the first to fifth aspects. In the sixth aspect of the rotating body (1), the inner peripheral surface (3A) of the bobbin (3) is provided with a plurality of convex or concave guide portions (36) that guide the attachment of the bobbin (3) to the cylindrical portion (21).

According to the sixth aspect of the rotating body (1), the bobbin (3) can be easily attached to the cylindrical portion (21), and when the bobbin (3) is attached to the cylindrical portion (21), the multiple guide portions (36) are hooked onto the outer peripheral surface (21B) of the cylindrical portion (21), thereby positioning the bobbin (3) circumferentially relative to the cylindrical portion (21).

The rotating body (1) of the seventh aspect has the following configuration in addition to the configuration of the rotating body (1) of the fourth or fifth aspect. In the rotating body (1) of the seventh aspect, the inner peripheral surface (3A) of the bobbin (3) is provided with a plurality of convex or concave guide portions (36) that guide the attachment of the bobbin (3) to the cylindrical portion (21). The plurality of elastic bodies (33) and the plurality of guide portions (36) are positioned alternately in the circumferential direction.

According to the seventh aspect of the rotating body (1), the bobbin (3) can be easily attached to the cylindrical portion (21), and when the bobbin (3) is attached to the cylindrical portion (21), the multiple guide portions (36) are hooked onto the outer peripheral surface (21B) of the cylindrical portion (21), thereby positioning the bobbin (3) in the circumferential direction relative to the cylindrical portion (21). In addition, the multiple elastic bodies (33) and multiple guide portions (36) can be efficiently arranged on the bobbin (3).

The rotating body (1) of the eighth aspect has the following configuration in addition to the configuration of the rotating body (1) of any one of the first to seventh aspects. In the rotating body (1) of the eighth aspect, the bobbin (3) further has a cylindrical bobbin body (30) having an inner peripheral surface (3A) and an outer peripheral surface (3B), a plurality of upper protrusions (31) extending radially outward from an upper portion (301) of the bobbin body (30), and a plurality of lower protrusions (32) extending radially outward from a lower portion (303) of the bobbin body (30).

According to the eighth aspect of the rotating body (1), the linear cutter (8) wound around the outer circumferential surface (3A) of the bobbin body (30) is effectively prevented from accidentally coming off the bobbin body (30) by the multiple upper protrusions (31) and multiple lower protrusions (32). In addition, when gripping the bobbin (3), the bobbin body (30) together with the wound linear cutter (8) can be gripped by inserting fingers into the spaces between the multiple upper protrusions (31), and the bobbin body (30) together with the wound linear cutter (8) can be gripped by inserting fingers into the spaces between the multiple lower protrusions (32).

The rotating body (1) of the ninth aspect has the following configuration in addition to the configuration of the rotating body (1) of the eighth aspect. In the rotating body (1) of the ninth aspect, when viewed along the central axis (C1) of the bobbin (3), the multiple upper protrusions (31) and the multiple lower protrusions (32) are positioned alternately in the circumferential direction.

According to the ninth aspect of the rotating body (1), the linear cutter (8) wound around the outer peripheral surface (3A) of the bobbin body (30) is effectively prevented from accidentally coming off the bobbin body (30) by the multiple upper protrusions (31) and multiple lower protrusions (32) that are alternately positioned in the circumferential direction. In addition, the number of upper protrusions (31) and the number of lower protrusions (32) can be reduced.

The rotating body (1) of the tenth aspect has the following configuration in addition to the configuration of the rotating body (1) of any one of the first to seventh aspects. In the rotating body (1) of the tenth aspect, the bobbin (3) further has a cylindrical bobbin body (30) having an inner peripheral surface (3A) and an outer peripheral surface (3B), and a plurality of upper protrusions (31) extending radially outward from an upper portion (301) of the bobbin body (30). At least two of the plurality of upper protrusions (31) are formed with hook grooves (315) for hooking the ends (81, 82) of the linear cutter (8).

According to the rotating body (1) of the tenth aspect, the linear cutter (8) wound around the outer circumferential surface (3A) of the bobbin body (30) is effectively prevented from accidentally coming off the bobbin body (30) by the multiple upper protrusions (31). In addition, when gripping the bobbin (3), the user can insert fingers into the space between the multiple upper protrusions (31) to grip the bobbin body (30) together with the wound linear cutter (8). Furthermore, in the rotating body (1) of the tenth aspect, when the bobbin (3) is not attached to the support case (2), both ends (81, 82) of the linear cutter (8) can be hooked into the hook grooves (315), respectively, to maintain the linear cutter (8) in a state in which it is difficult to come off the support case (2).

The rotating body (1) of the eleventh aspect has the following configuration in addition to the configuration of the rotating body (1) of any one of the first to seventh aspects. In the rotating body (1) of the eleventh aspect, the bobbin (3) further has a cylindrical bobbin body (30) having an inner peripheral surface (3A) and an outer peripheral surface (3B), and a plurality of lower protrusions (32) extending radially outward from a lower portion (303) of the bobbin body (30). At least one of the plurality of lower protrusions (32) is formed with a hook hole (325) for inserting the linear cutter (8) and hooking its central portion (85).

According to the 11th embodiment of the rotating body (1), the linear cutter (8) can be easily wound around the bobbin body (30) by hooking the central portion (85) of one linear cutter (8) into the hook hole (325) and winding the remaining portion of the linear cutter (8) around the bobbin body (30).

The rotating body (1) of the twelfth aspect has the following configuration in addition to the configuration of the rotating body (1) of any one of the first to eleventh aspects. In the rotating body (1) of the twelfth aspect, the support case (2) has a cylindrical portion (21) made of synthetic resin, a flange portion (23) made of synthetic resin, and a metal fitting (28) connected to the upper portion (211) of the cylindrical portion (21). The metal fitting (28) has an insertion hole (285) through which the drive shaft (905) is inserted.

According to the rotating body (1) of the twelfth aspect, the synthetic resin cylindrical portion (21) and the flange portion (23) can be integrally connected to the drive shaft (905) via the metal fitting (28).

The rotating body (1) of the thirteenth aspect has the following configuration in addition to the configuration of the rotating body (1) of the first aspect. In the rotating body (1) of the thirteenth aspect, the bobbin (3) further has a cylindrical bobbin body (30) having an inner peripheral surface (3A) and an outer peripheral surface (3B), a plurality of protrusions (31) extending radially outward from the bobbin body (30), an elastic body (33) that elastically presses against the outer peripheral surface (21B) of the cylindrical portion (21) when the bobbin body (30) is attached to the cylindrical portion (21), and a groove (34) that allows the elastic body (33) to bend radially outward. The elastic body (33) and the groove (34) are located radially inward of the corresponding protrusions (31) among the plurality of protrusions (31).

According to the rotating body (1) of the thirteenth aspect, the linear cutter (8) wound around the outer peripheral surface (3A) of the bobbin body (30) is prevented from accidentally coming off the bobbin body (30) by the multiple protrusions (31). In addition, since the elastic body (33) can bend radially outward when it comes into contact with the outer peripheral surface (21B) of the cylindrical portion (21), the elastic body (33) can apply an appropriate elastic force to the cylindrical portion (21). Furthermore, according to the rotating body (1) of the thirteenth aspect, the elastic body (33) and the groove (34) are located radially inward of the corresponding protrusions (31), so that the entire bobbin (3) can be formed compactly.

The first embodiment of the brush cutter (9) includes a rotating body (1) of any one of the first to thirteenth embodiments, and a brush cutter body (90) having a drive shaft (905) to which the rotating body (1) is connected.

According to the first embodiment of the brush cutter (9), the linear cutter (8) wound around the cylindrical portion (21) of the support case (2) of the rotating body (1) can be used for a long period of time. Moreover, when replacing the linear cutter (8), the bobbin (3) can be easily removed from the support case (2) with the rotating body (1) removed from the drive shaft (905), and the replacement of the linear cutter (8) can be easily performed.

The bobbin (3) of the first aspect is a bobbin (3) that is detachably attached to a support case (2) that rotates integrally with the drive shaft (905) of the brush cutter body (90), and includes a cylindrical bobbin body (30), an inner peripheral surface (3A) of the bobbin body (30), and an outer peripheral surface (3B) of the bobbin body (30). The inner peripheral surface (3A) is provided so as to detachably abut against the support case (2). The outer peripheral surface (3B) faces the opposite side to the inner peripheral surface (3A) and is provided so that a flexible linear cutter (8) can be wound around it.

According to the first embodiment of the bobbin (3), the linear cutter (8) wound around the bobbin (3) can be used for a long period of time, and when replacing the linear cutter (8), the bobbin (3) can be easily removed from the support case (2), allowing the linear cutter (8) to be easily replaced.

The bobbin (3) of the second embodiment has the following configuration in addition to the configuration of the bobbin (3) of the first embodiment. In the bobbin (3) of the second embodiment, the bobbin body (30) further has a plurality of elastic bodies (33) that elastically press against the support case (2) when attached to the support case (2).

According to the second embodiment of the bobbin (3), the bobbin (3) is stably held in the support case (2) by the elastic holding force exerted by the multiple elastic bodies (33). This prevents the bobbin (3) from accidentally falling off the support case (2). Moreover, the bobbin (3) can be easily removed from the support case (2).

Claims (6)

a support case connected to a drive shaft protruding from a gear box of a brush cutter body and rotating integrally with the drive shaft;
a bobbin that is detachably attached to the support case and rotates integrally with the drive shaft and the support case,
the support case has a cylindrical portion into which the drive shaft is inserted, a flange portion extending radially outward from a lower portion of the cylindrical portion, and a plurality of withdrawal holes formed through the flange portion,
the bobbin has an inner circumferential surface that detachably contacts the outer circumferential surface of the cylindrical portion, and an outer circumferential surface that faces the opposite side to the inner circumferential surface and around which a flexible linear cutter is wound,
the bobbin is configured such that, in a state where the inner peripheral surface of the bobbin is attached to the cylindrical portion such that it abuts against the outer peripheral surface of the cylindrical portion, both ends of the linear cutter wound around the outer peripheral surface are pulled out radially outward through two of the plurality of pull-out holes ,
The bobbin is covered from above by the gear box, thereby preventing the bobbin from falling off from the support case.
Rotating body. The rotating body according to claim 1 , wherein the inner peripheral surface of the bobbin is provided with a plurality of convex or concave guide portions for guiding the attachment of the bobbin to the cylindrical portion. The rotating body of claim 1 or 2, wherein the bobbin further comprises a cylindrical bobbin body having the inner circumferential surface and the outer circumferential surface, a plurality of upper protrusions extending radially outward from an upper portion of the bobbin body, and a plurality of lower protrusions extending radially outward from a lower portion of the bobbin body. The rotating body according to claim 3 , wherein the upper protrusions and the lower protrusions are alternately positioned in a circumferential direction when viewed along a central axis of the bobbin. the support case includes the cylindrical portion made of a synthetic resin, the flange portion made of a synthetic resin, and a metal fitting connected to an upper portion of the cylindrical portion,
The rotating body according to claim 1 , wherein the metal fitting has an insertion hole through which the drive shaft is inserted. A rotating body according to any one of claims 1 to 5,
a brush cutter body having the drive shaft to which the rotating body is connected .

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