JP2013078823A5 - - Google Patents

Description

Power tool and method of manufacturing power tool

  The present invention relates to a power tool having a ball balancer and a method for manufacturing the power tool.

  Japanese Patent Laid-Open No. 2001-300841 describes a grinder provided with a vibration isolator. This vibration isolator has a plurality of balance balls and is attached to rotate integrally with a grindstone receiver disposed on the outer periphery of the drive shaft. Even when the center of gravity of the rotating portion including the grindstone does not coincide with the center of rotation of the drive shaft, the balance ball moves, and the balance ball moves so that the center of gravity of the rotating portion and the center of rotation of the driving shaft coincide. This prevents the rotating part from vibrating.

JP 2001-300841 A

  By the way, it is desirable that the ball balancer that suppresses vibration by moving the ball moves smoothly. Therefore, lubricating oil is required in the region where the ball of the ball balancer moves. However, if the region in which the ball moves is filled with lubricating oil, a force that prevents the ball from moving due to the fluid resistance of the lubricating oil is generated, and smooth movement of the ball is hindered. Thereby, there exists a possibility of diluting the effect of the ball balancer which reduces the vibration of a power tool. Therefore, in view of the above, an object of the present invention is to provide a technique related to a ball balancer that allows a ball to operate smoothly.

  In order to solve the above-mentioned problems, according to a preferred embodiment of the power tool according to the present invention, a rotary shaft to which a tip tool is attached and a ball balancer that rotates integrally with the rotary shaft are provided. The ball balancer includes a plurality of balls, a ball storage member provided with a rotation area having a predetermined volume for holding the balls so as to be rotatable around a rotation axis, and a lubricant filled in the rotation area. doing. The lubricant filling amount is a filling amount that reduces the vibration value generated in the power tool when the power tool is driven by smoothly rotating the ball.

  According to the present invention, the filling amount of the lubricant is set to such an amount that the ball can be smoothly rotated, so that the ball balancer can be operated efficiently. Thereby, the vibration value which arises in a power tool can be reduced.

  According to the further form of the power tool according to the present invention, the filling amount of the lubricant is such that the filling rate X with respect to the volume of the rotating region is expressed by the following formula (1) with respect to the value μ corresponding to the viscosity of the lubricant. It is an amount corresponding to the filling rate satisfying (1). The “volume of the rotation area” is a volume obtained by subtracting the volume of the ball from the volume in which the ball can rotate in the rotation area.

  According to this form, the ball balancer which can operate a ball | bowl smoothly by setting a filling rate according to the viscosity of a lubricant is provided. Thereby, the vibration which a power tool generate | occur | produces can be reduced efficiently.

According to the further form of the power tool according to the present invention, the lubricant has a viscosity of VG100 or less, and the filling amount of the lubricant is an amount having a filling rate of 27% or less with respect to the volume of the rotating region. It is characterized by that. The “volume of the rotation area” is a volume obtained by subtracting the volume of the ball from the volume in which the ball can rotate in the rotation area. Note that VG is a symbol representing the ISO viscosity grade, and the numerical value following VG is the midpoint kinematic viscosity expressed in units of mm ² / s.

  According to this form, the ball balancer which can operate | move a ball | bowl smoothly by setting appropriately the viscosity and filling amount of a lubricant is provided. Thereby, the vibration which a power tool generate | occur | produces can be reduced efficiently.

According to the further form of the power tool which concerns on this invention, a power tool is a grinder. According to this embodiment, the vibration generated by the power tool can be efficiently reduced with respect to the grinder as the power tool.

According to the preferable form of the power tool according to the present invention, a rotating shaft to which the tip tool is attached, a housing that houses a part of the rotating shaft, a first bearing that is held by the housing and rotatably holds the rotating shaft, and A second bearing and a ball balancer that rotates integrally with the rotation shaft; The ball balancer includes a ball and a lubricant that reduces a vibration value generated in the power tool by smoothly rotating the ball.
  More preferably, the ball balancer is arranged so that the tip tool is attached to the rotating shaft in a state where the tip tool is in contact with the ball balancer.
  More preferably, the tip tool is attached to the rotary shaft in a state where the rotary shaft penetrates the tip tool.

  According to the preferable form of the manufacturing method of the power tool which concerns on this invention, the power tool is equipped with the rotating shaft to which a front-end tool is attached, and the ball balancer which rotates integrally with the rotating shaft. The ball balancer includes a plurality of balls, a ball storage member provided with a rotation area having a predetermined volume for holding the balls so as to be rotatable around a rotation axis, and a lubricant filled in the rotation area. doing. Then, the filling amount of the lubricant is determined so that the vibration value generated in the power tool when the power tool is driven is equal to or less than a predetermined value, and the determined filling amount of the lubricant is filled in the rotation region. A ball balancer is formed.

  According to the present invention, it is possible to determine the amount of lubricant filling so that the vibration value is equal to or less than a predetermined value, and appropriately set the amount of lubricant filling while suppressing vibration generated in the power tool. A power tool equipped with a balancer can be manufactured.

  According to the further form of the manufacturing method of the power tool which concerns on this invention, the filling amount of a lubricant is the following with respect to the value (micro | micron | mu) with which the filling rate X with respect to the volume of a rotation area | region respond | corresponds to the viscosity of the said lubricant. It is the quantity satisfy | filling Numerical formula (2), It is characterized by the above-mentioned. The “volume of the rotation area” is a volume obtained by subtracting the volume of the ball from the volume in which the ball can rotate in the rotation area.

  According to this form, the ball balancer which can operate a ball | bowl smoothly by setting a filling rate according to the viscosity of a lubricant is provided. Thereby, the power tool provided with the ball balancer which can reduce the vibration which a power tool generate | occur | produces efficiently can be manufactured.

According to the further form of the manufacturing method of the power tool which concerns on this invention, the viscosity of a lubricant is VG100 or less, and the filling amount of a lubricant is an amount whose filling amount with respect to the volume of a rotation area | region is 27% or less. It is characterized by being. The “volume of the rotation area” is a volume obtained by subtracting the volume of the ball from the volume in which the ball can rotate in the rotation area. Note that VG is a symbol representing the ISO viscosity grade, and the numerical value following VG is the midpoint kinematic viscosity expressed in units of mm ² / s.

  According to this form, the ball balancer which can operate | move a ball | bowl smoothly by setting appropriately the viscosity and filling amount of a lubricant is provided. Thereby, the power tool provided with the ball balancer which can reduce the vibration which a power tool generate | occur | produces efficiently can be manufactured.

According to the further form of the manufacturing method of the power tool which concerns on this invention, the filling amount of a lubricant is determined so that the vibration value which arises in a power tool may be 2.5 m / s < ² > or less in a hand-arm vibration value. ing.

According to this embodiment, the filling amount of the lubricant can be appropriately determined so that the vibration value generated in the power tool is 2.5 m / s ² or less in terms of hand-arm vibration value. According to the European Union Human Body Vibration Directive 2002/44 / EC promulgated by the European Union Parliament, when it is achieved, the onset of symptoms related to hand-arm vibration syndrome to users of hand-held vibration and impact devices, tools and workpieces It defines a 2.5 m / s ² daily vibration exposure control value that would reduce the possibility of. This value is generally accepted by medical professionals, scientists and government agencies, research institutions and the industry in the United States and other countries.

  According to the further form of the manufacturing method of the power tool which concerns on this invention, a power tool is a grinder.

  According to this embodiment, it is possible to manufacture a power tool that can efficiently reduce vibration generated by the power tool with respect to a grinder as a power tool.

  ADVANTAGE OF THE INVENTION According to this invention, the technique regarding the ball balancer for a ball | bowl to operate | move smoothly can be provided.

It is sectional drawing which shows the whole grinder structure concerning embodiment of this invention. It is sectional drawing of the II-II line in FIG. It is a plane sectional view of a ball balancer. It is sectional drawing of the IV-IV line in FIG. It is a flowchart which determines the filling rate of the lubricating oil of a ball balancer. It is a figure which shows the relationship between the filling rate of lubricating oil, and the vibration value of a grinder.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the present embodiment, a grinder will be described as an example of a power tool. This grinder is a power tool that rotates a grinding tool such as a grinding tool or a polishing tool or a tip tool such as a cutting tool by a motor to perform grinding, polishing, cutting, or the like on a workpiece.

  As shown in FIGS. 1 and 2, the grinder 1 is mainly composed of a main housing 10, a gear housing 20, a rear cover 30, and a wheel cover 40.

  The main housing 10 is a substantially cylindrical housing and houses the motor 100. The rotation shaft 101 of the motor 100 is disposed so as to protrude toward the gear housing 20.

  The gear housing 20 is provided on one side of the main housing 10 and accommodates a first bevel gear 200, a second bevel gear 201, a spindle 202, bearings 203 and 204, and the like. The first bevel gear is externally mounted on the rotating shaft 101 of the motor 100. The second bevel gear 201 is screwed with the first bevel gear 200, and a spindle 202 is disposed at the center of the second bevel gear 201, and the second bevel gear 201 and the spindle 202 rotate together. Thereby, the rotation output of the motor 100 is converted into a rotational force around the axis of the spindle 202 orthogonal to the rotation axis 101. The spindle 202 is held by two bearings 203 and 204.

  The rear cover 30 is provided on the opposite side of the main housing 10 from the gear housing 20 and accommodates the power supply wiring portion 300. The power supply wiring unit 300 is provided with a power supply cord 301 that supplies current from an external power supply and a switch 302 that switches ON / OFF of the drive of the grinder 1. The power supply wiring unit 300 is electrically connected to the motor 100.

  The wheel cover 40 is a substantially semicircular component that is detachably attached to the outside of the gear housing 20. A ball balancer 400 is attached to the spindle 202 outside the gear housing 20. Further, a detachable outer flange 41 is screwed to the spindle 202 at the tip of the spindle 202. The grindstone 2 is detachably held between the ball balancer 400 and the outer flange 41. The wheel cover 40 is configured so as to cover the outside of the grindstone 2 attached to the spindle 202 half a circumference. Thereby, the wheel cover 40 suppresses scattering of fragments of the workpiece processed by the grindstone 2 and protects the user from the rotating grindstone 2. This grindstone 2 is an implementation structural example corresponding to the "tip tool" of the present invention.

  Next, the ball balancer 400 will be described in detail with reference to FIGS. The ball balancer 400 is mainly composed of a balancer body 401, balls 402, and a balancer cover 403.

  The balancer body 401 is a metal substantially disk-shaped member. A through hole 404 through which the spindle 202 is inserted is formed at the center of the balancer body 401, and a groove 405 that is open on one surface of the balancer body 401 is formed around the through hole 404. The ball 402 is a metal sphere, and eight balls 402 are held in the groove 405 so as to be movable around the through hole 404 in the groove 405. A balancer cover 403 is disposed on one surface of the balancer body 401 so as to close the opening of the groove 405. Note that lubricating oil (not shown) for smooth movement of the ball 402 is enclosed in the groove 405. The balancer body 401 and the balancer cover 403 correspond to the “ball storage member” of the present invention, and the groove 405 corresponds to the “rotation region” of the present invention.

  The grinder 1 configured as described above is supplied with electric power from the external power supply to the motor 100 via the electric wiring unit 300 when the switch 302 is operated. As a result, the motor 100 is driven to rotate, and the first bevel gear 200 attached to the rotating shaft 101 rotates. When the first bevel gear 200 and the second bevel gear 201 are screwed together and rotated, the rotation output of the motor 100 is converted into a rotational force around the spindle 202 and rotated integrally with the second bevel gear 201. The grindstone 2 mounted on the spindle 202 is rotated. The workpiece can be processed by pressing the rotating grindstone 2 against the workpiece.

  The grinder 1 is vibrated by the driving of the grinder 1, but the greater the distance between the center of gravity of the grindstone 2 that rotates together with the spindle 202 and the rotation axis of the spindle 202, the greater the vibration that occurs in the grinder 1. At this time, the ball balancer 400 attached to the spindle 202 rotates integrally with the spindle 202, so that the position of the center of gravity of the grindstone 2 or the like in which the plurality of balls 402 rotate together with the spindle 202 and the spindle 202 are rotated. The groove 405 is rotated so as to reduce the separation distance from the rotation axis. Thereby, the vibration which arises in the grinder 1 is reduced.

  Next, a method for manufacturing the grinder 1 will be described. Since the manufacturing method of the grinder 1 is a well-known manufacturing method, the manufacturing method of the ball balancer 400 is demonstrated here.

  The groove 405 of the ball balancer 400 is filled with lubricating oil. If the groove 405 is filled with lubricating oil, the movement of the ball 402 is hindered by the fluid resistance of the lubricating oil. Therefore, it is necessary to appropriately set the amount of lubricating oil sealed in the groove 405. In the manufacturing method of the present embodiment, when the lubricating oil is filled in the groove 405, the ball is smoothly rotated so that the vibration value generated in the grinder when the grinder is driven is less than or equal to a predetermined value. The filling amount of the lubricant is determined. Then, the ball balancer is formed by filling the rotation region with the determined amount of lubricant.

  This filling amount is determined from the viscosity of the lubricating oil and the filling rate that is the filling amount of the lubricant with respect to the volume obtained by subtracting the volume of the ball 402 from the volume of the region in which the ball 402 can rotate in the groove 405 at that viscosity. Can do. Regarding this filling rate, the applicant sets the filling rate of the lubricating oil based on experiments conducted in advance. The experiment will be described with reference to FIG.

  First, each dimension of the ball balancer 400 is set (S1). The dimensions of the ball balancer 400 in FIGS. 3 and 4 are as follows. The inner diameter R1 of the groove 405 is 36 mm, the outer diameter R2 is 55 mm, and the depth D is 9.8 mm. The diameter of the ball 402 is 8.73 mm.

  Next, the lubricating oil filled in the groove 405 is set (S2). Here, Shell (registered trademark) terrace oil is used as the lubricating oil.

Then, for three types of lubricating oils (VG32, VG68, VG100) having different viscosities, the acceleration generated in the grinder 1 when the filling amount was changed was measured, and the relationship between the filling rate and the vibration value was measured (S3). Note that VG is a symbol representing the ISO viscosity grade, and the numerical value following VG is the midpoint kinematic viscosity expressed in units of mm ² / s.

  The acceleration is measured with a three-axis acceleration pickup in a state where the grinder 1 is held at two points in the axial direction of the rotating shaft 101 so that the rotating shaft 101 of the motor 100 matches the horizontal direction and the spindle 202 matches the vertical direction. The acceleration of each of the three axes was measured. Then, the measured acceleration was appropriately filtered, and the relationship between the filling rate of the lubricating oil and the vibration value was obtained using a value obtained by synthesizing the accelerations in the three axial directions as a vibration value.

Based on the above, the filling rate of the lubricating oil is determined (S4). FIG. 6 is a graph showing the relationship between the filling rate of the lubricating oil and the vibration value as an experimental result in S3. According to this graph, it is preferable that the lubricating oil has a viscosity of VG100 or less and a filling rate of 27% or less that gives a vibration value of 2.5 m / s ² or less.

  On the other hand, the applicant has found that the relationship between the filling rate X of the lubricating oil and the vibration value Y can be approximated by a quadratic function of the following mathematical formula (3).

Here, a and b are coefficients determined by the viscosity of the lubricating oil to be enclosed, and a = 4.5 × 10 ⁻⁶ μ and b = 30−0.5 μ. Further, c is determined by the roundness and surface roughness of the ball 402, and in the case of general processing, c is about 1.5. Here, as the μ corresponding to the viscosity, the value following the symbol VG representing the ISO viscosity grade was used.

  When the condition for the vibration value Y to be smaller than the predetermined vibration value F is obtained, the following equation (4) is obtained.

Here, when the predetermined vibration value F is 2.5, the following formula (5) is obtained. This vibration value corresponds to the daily vibration exposure countermeasure value of 2.5 m / s ² stipulated in the European Union Human Body Vibration Directive 2002/44 / EC.

  Based on the above knowledge, a predetermined vibration value F can be set, and the filling rate of the lubricating oil according to the viscosity can be determined so as to satisfy Equation (4). On the other hand, assuming that the predetermined vibration value F is 2.5, the filling rate of the lubricating oil according to the viscosity may be determined so as to satisfy Equation (5).

  The ball balancer 400 is formed by filling the groove 405 with a filling amount of lubricating oil corresponding to the filling rate determined as described above. Then, the grinder 1 is formed by attaching the ball balancer 400 to the spindle 202 integrally.

  It is needless to say that the above set values and the like are implementation configuration examples and do not limit the contents of the present invention. Further, in this embodiment, the filling rate is defined as the amount of lubricant filling with respect to the volume obtained by subtracting the volume of the ball 402 from the volume of the region in which the ball 402 can rotate in the groove 405. Defining the filling amount of the lubricant with respect to the volume of the groove 405 and calculating the relationship between the filling rate and the vibration value to determine the filling amount are also suitably included in the present invention.

  As described above, the ball 402 can be operated smoothly by setting the filling rate according to the viscosity of the lubricating oil. Thereby, the grinder 1 provided with the ball balancer 400 with which the ball 402 operates smoothly can be formed. As a result, the vibration generated by the grinder 1 can be efficiently reduced. Furthermore, in this embodiment, the filling amount of lubricating oil can be reduced compared with the case where the groove 405 is filled with lubricating oil, and the grinder 1 can be reduced in cost.

  In the above, Shell (registered trademark) terrace oil is used as the lubricating oil. However, as described above, the filling rate can be set according to the viscosity of the lubricant even when other lubricants are used. It is.

In the above, 2.5 is applied as the predetermined vibration value F, which corresponds to the vibration value 2.5 m / s ² defined in the European Union Human Body Vibration Directive 2002/44 / EC. However, the predetermined vibration value F can be appropriately set according to the required performance. As the vibration value F, a value corresponding to the vibration value can be used, the value of the vibration value itself may be used, or a value obtained by making the vibration value dimensionless may be used.

  In the above, the value μ following the symbol VG indicating the ISO viscosity grade is used as the value μ corresponding to the viscosity. However, the value of the viscosity itself may be used, and the viscosity is made dimensionless. A value may be used.

  In the above description, the grinder has been described as an example of the power tool. However, the present invention is not limited to this, and the present invention can also be applied to a hammer drill driven by a motor, a lawnmower mower driven by an engine, or the like. .

In view of the gist of the present invention, the power tool according to the present invention can be configured in the following manner.
(Aspect 1)
“Rotating shaft to which the tip tool is attached,
A ball housing member that rotates integrally with the rotation shaft and that has a plurality of balls and a rotation area having a predetermined volume for rotatably holding the balls around the rotation shaft; and the rotation A power tool comprising a ball balancer having a lubricant filled in the region,
The filling amount of the lubricant is a filling amount that reduces a vibration value generated in the power tool when the power tool is driven by smoothly rotating the ball, and is relative to the volume of the rotation region. For the filling factor X, coefficients a and b determined by the viscosity of the lubricant, coefficient c determined by the roundness and surface roughness of the ball, and a value μ corresponding to the viscosity of the lubricant, the vibration value is A power tool characterized by being an amount corresponding to a filling rate satisfying the following mathematical formula (6) that is equal to or less than a predetermined vibration value F. "

Moreover, in view of the meaning of the said invention, the following aspect can be comprised in the manufacturing method of the power tool which concerns on this invention.
(Aspect 2)
“Rotating shaft to which the tip tool is attached,
A ball housing member that rotates integrally with the rotation shaft and that has a plurality of balls and a rotation area having a predetermined volume for rotatably holding the balls around the rotation shaft; and the rotation A method of manufacturing a power tool comprising a ball balancer having a lubricant filled in a region,
By smoothly rotating the ball, the amount of the lubricant filled is adjusted so that the vibration value generated in the power tool when the power tool is driven is less than or equal to a predetermined value. The filling factor X with respect to the volume of the region is based on the coefficients a and b determined by the viscosity of the lubricant, the coefficient c determined by the roundness and surface roughness of the ball, and the value μ corresponding to the viscosity of the lubricant. The vibration value is determined to be an amount corresponding to the filling rate that satisfies the following mathematical formula (7) that is equal to or less than the predetermined vibration value F,
A method of manufacturing a power tool, wherein the ball balancer is formed by filling the rotation region with the determined amount of the lubricant. "

1 grinder 2 grindstone 10 main housing 20 gear housing 30 rear cover 40 wheel cover 41 outer flange 100 motor 101 rotating shaft 200 first bevel gear 201 second bevel gear 300 power supply wiring section 301 power cord 302 switch 400 ball balancer 401 balancer body 402 ball 403 Balancer cover 404 Through hole 405 Groove

Claims (12)

A rotating shaft to which the tip tool is attached;
A ball housing member that rotates integrally with the rotation shaft and that has a plurality of balls and a rotation area having a predetermined volume for rotatably holding the balls around the rotation shaft; and the rotation A power tool comprising a ball balancer having a lubricant filled in the region,
The power tool is characterized in that the filling amount of the lubricant is a filling amount that reduces a vibration value generated in the power tool when the power tool is driven by smoothly rotating the ball. The power tool according to claim 1,
The filling amount of the lubricant is an amount corresponding to the filling rate that satisfies the following mathematical formula (1) with respect to the value μ corresponding to the viscosity of the lubricant, with respect to the filling rate X with respect to the volume of the rotating region. Power tool characterized by

The power tool according to claim 1,
The power tool according to claim 1, wherein the lubricant has a viscosity of VG100 or less, and a filling amount of the lubricant is an amount such that a filling rate with respect to a volume of the rotating region is 27% or less. The power tool according to any one of claims 1 to 3,
The power tool is a grinder. A rotating shaft to which the tip tool is attached;
A housing for accommodating a part of the rotating shaft;
A first bearing and a second bearing held by the housing and rotatably holding the rotating shaft;
A power balance tool having a ball balancer that rotates integrally with the rotating shaft,
The ball balancer is
A power tool comprising: a ball; and a lubricant that reduces a vibration value generated in the power tool by smoothly rotating the ball. The power tool according to any one of claims 1 to 5,
The power tool, wherein the ball balancer is arranged so that the tip tool is attached to the rotating shaft in a state where the tip tool is in contact with the ball balancer. The power tool according to any one of claims 1 to 6,
A power tool characterized in that the tip tool is attached to the rotary shaft in a state where the rotary shaft penetrates the tip tool. A rotating shaft to which the tip tool is attached;
A ball housing member that rotates integrally with the rotation shaft and that has a plurality of balls and a rotation area having a predetermined volume for rotatably holding the balls around the rotation shaft; and the rotation A method of manufacturing a power tool comprising a ball balancer having a lubricant filled in a region,
By smoothly rotating the ball, the amount of the lubricant charged is determined so that a vibration value generated in the power tool when the power tool is driven is a predetermined value or less,
A method of manufacturing a power tool, wherein the ball balancer is formed by filling the rotation region with the determined amount of the lubricant. It is a manufacturing method of the power tool according to claim 8 ,
The filling amount is an amount corresponding to a filling rate where the filling rate X with respect to the volume of the rotation region of the lubricant satisfies the following mathematical formula (2) with respect to a value μ corresponding to the viscosity of the lubricant. A method for manufacturing a power tool.

It is a manufacturing method of the power tool according to claim 8 ,
The lubricant has a viscosity of VG100 or less,
The method of manufacturing a power tool, wherein the filling amount is an amount such that a filling rate with respect to the volume of the rotating region is 27% or less. It is a manufacturing method of the power tool according to any one of claims 8 to 10 ,
The vibration value is a hand-arm vibration value,
The method for manufacturing a power tool, wherein the predetermined value is 2.5 m / s ² . It is a manufacturing method of the power tool according to any one of claims 8 to 11 ,
The method of manufacturing a power tool, wherein the power tool is a grinder.