JPWO2016027807A1 - Magnetic attachment aids for fixtures and electric screwdrivers - Google Patents

Abstract

By providing a driver bit and magnetizing it, the present invention provides a magnetic attachment auxiliary tool for a fixture that can magnetize not only iron but also a stainless steel fixture at the tip of the bit, and an electric screwdriver using the same. A plurality of permanent magnets (21) are joined together in a bundle without gaps so that ends of adjacent permanent magnets (21) have the same polarity so that a hollow through hole (13) is formed in the center. In the preferred embodiment, each of the plurality of permanent magnets (21) has a cushion material (22) interposed on the end surface opposite to the hollow through hole (13). I am letting.

Description

  The present invention relates to a magnetic auxiliary tool for a fixture for attaching an iron or stainless steel fixture to the tip of the screw by inserting and removing a driver bit or the like, and an electric screwdriver using the magnetic auxiliary tool. .

  As a conventional magnetizing auxiliary tool for a fixture, for example, there is one described in Patent Document 1 below.

  This auxiliary tool is formed of two semi-rings of neodymium magnets, with a space between the two magnets and arranged in a ring shape, and a driver bit is inserted into the central space (hollow through hole). The shaft portion is magnetized, and a rotary fixing tool such as a screw is adsorbed and held at the tip of the driver bit.

JP 2004-141986

  However, in the above document, a fixing tool such as an iron screw is used for attachment, and a magnetic force strong enough to attract and hold a fixing tool such as a stainless steel screw at the tip of an electric screwdriver bit is provided. I can't get it.

  Especially recently, iron and other fasteners are rusted and corroded, so they are not suitable for outdoor buildings, and stainless steel screws are often used. As with iron screws, it is desired to develop an auxiliary tool that can be attracted and held at the tip of an electric screwdriver bit.

  The present invention has been proposed in view of such circumstances, and its purpose is to strongly magnetize the tip of the driver bit and to magnetically attach it even with a stainless steel fixture. It is to provide an auxiliary tool.

  In order to achieve the above-mentioned object, the magnetic auxiliary tool for a fixture according to the present invention has a plurality of permanent magnets, and end portions of the same polarity of adjacent permanent magnets so that a hollow through hole is formed in the center. It is characterized in that a petal-like cylindrical body is formed by joining in a bundle without gaps.

  In the present invention, a cushion material may be interposed between the end surfaces of the plurality of permanent magnets opposite to the hollow through holes.

  Furthermore, in order to obtain a larger magnetic force, the plurality of permanent magnets may have a magnetization direction defined by an inclination angle at which the magnetic lines of force are directed toward the tip with respect to the axis of the driver bit inserted into the hollow through hole, The inventor has also proposed such a structure.

  In addition, the plurality of permanent magnets may be configured to further increase the magnetic force by attaching auxiliary permanent magnets to the outer circumferences along the penetration direction of the hollow through holes.

  Furthermore, the petal-like cylindrical body may have a regular n-gon shape.

  Furthermore, the permanent magnet may have a chamfered joint surface formed on adjacent side surfaces between the magnets.

  Moreover, the electric driver of the present invention has a configuration in which the magnetic auxiliary tool for fixing device according to any one of claims 1 to 7 is mounted on a driver bit.

  According to the magnetizing auxiliary tool for a fixing device of the present invention, since it has the above-described configuration, the leakage of the magnetic flux of the structure in which the permanent magnets are bundled is almost eliminated, and the magnetic flux is applied to the hollow through hole into which the driver bit is inserted. Can concentrate. For this reason, a large amount of magnetic lines of force can be collected also at the tip of the driver bit inserted into the hollow through hole, so that a fixing tool such as a stainless steel screw can be magnetically attached.

(A) is a perspective view which shows the external appearance of the magnetic attachment auxiliary tool for fixing tools which concerns on one Embodiment of this invention, (b) is the same side view. (A) is a cross-sectional view corresponding to the line AA in FIG. 1 (b), (b) is a magnetic support for the fixture of FIG. 1 (a) corresponding to the line BB in FIG. 2 (a). It is sectional drawing of a tool. It is the longitudinal cross-sectional view showing the use point of the magnetic attachment auxiliary tool for fixtures, and the state where the screwdriver bit was inserted and the screw was magnetically attached to the tip. It is a figure which shows magnetic flux distribution when a driver bit is inserted by the magnetic attachment auxiliary tool for fixtures. (A), (b) is a schematic explanatory drawing of the permanent magnet used for the magnetic auxiliary tool for fixtures, and (a) is directed to the magnetization direction of the permanent magnet perpendicular to the axis of the driver bit and 90 degrees. FIG. 6B is a schematic diagram with an inclination W smaller than 90 degrees. These are the model explanatory drawings of the auxiliary permanent magnet used for the magnetic attachment auxiliary tool for fixtures. (A)-(e) is a schematic diagram which shows the example of arrangement | positioning of the permanent magnet of the magnetic attachment auxiliary tool for fixtures.

  Embodiments of the present invention will be described below with reference to the accompanying drawings.

  A fixing tool magnetic auxiliary tool 1 (hereinafter referred to as a magnetic auxiliary tool 1) is configured by arranging a plurality of permanent magnets 21 in a petal shape into a cylindrical body. It has a structure in which end portions of the same polarity of adjacent permanent magnets 21 are joined in a bundle without gap so that the through-hole 13 is formed.

  The relationship between the permanent magnet 21 and the hollow through-hole 13 can be as shown in FIG. 7 in addition to that shown in FIG. 2A. The central hollow through-hole 13 is preferably a regular n-square shape. However, it is not limited to such a shape.

  Next, with reference to FIG. 1 and FIG. 2, a more specific structure of the magnetizing aid 1 will be described.

  The magnetic field auxiliary tool 1 shown in FIG. 1 has a cylindrical shape having a hollow through hole 13 at the center (see FIG. 1A). The hollow through hole 13 in the illustrated example has a regular hexagonal column shape, and is arranged at the center position of the circle.

  The magnetic attachment aid 1 includes a main body case 10, a permanent magnet 21, a cushion material 22 made of an elastic material such as rubber, and a yoke 15. Among these, the permanent magnet 21, the cushion material 22, and the yoke 15 are arranged along the penetration direction of the hollow through-hole 13 as seen in FIG. 2.

  The main body case 10 is made of a non-magnetic resin that substantially forms the columnar shape of the magnetic attachment aid 1, and has an opening at the top and a hexagonal opening for forming the hollow through hole 13 at the bottom. It is comprised with the main body 11 and the cover body 12 which block | closes upper opening.

  The permanent magnet 21 is filled with the resin material 16 in the main body 11 of the main body case 10 so that six of the same shape retain the petal shape. The cross-sectional shape of each permanent magnet 21 is a hexagonal shape formed by combining a rectangle and an isosceles trapezoid as shown in FIG. Also, the arrangement of the polarities is the same between the permanent magnets 21. In the example of this figure, the hollow through hole 13 side is arranged to be the N pole, but the S pole and the N pole may be arranged in reverse. .

  In the illustrated example, the six permanent magnets 21 do not form a gap between adjacent permanent magnets 21, and in the illustrated example, both sides corresponding to the leg sides of the isosceles trapezoid are in contact with each other. The chamfered joint surfaces 25 are arranged in a petal shape so as to be in close contact with each other.

  In addition, a cushion material 22 is disposed on the end surface of each of the plurality of permanent magnets 21 opposite to the hollow through hole 13, so that the diameter of the bit inserted into the hollow through hole 13 is slightly larger or smaller. However, the error is absorbed and a gap is not generated.

  Since the six permanent magnets 21 are arranged in the main body 11 of the main body case 10 so that the same magnetic poles face each other, a repulsive force of the same polarity is generated. Therefore, the permanent magnet 21 is firmly restrained by filling the resin material 16 in the main body 11 so as not to break the shape of the petals.

  Next, with reference to FIG. 3 and FIG. 4, how to use the magnetic field auxiliary tool 1 will be described.

  The plurality of permanent magnets 21 are inclined so as to be directed to the tip 41 with respect to the axis 43 (see FIG. 3) of the driver bit 40 inserted into the hollow through-hole 13 as indicated by arrows of the respective magnetization directions. However, such a configuration is not an essential configuration of the present invention as will be described later.

  In general, since a fastener such as a stainless steel screw cannot be magnetized, it cannot be magnetized, but among stainless steels, austenitic (SUS304) is usually a non-magnetic material, It is known that when deformed by applying a large load, it can be transformed into martensite and magnetized, and the present inventor is made of stainless steel screws such as SUS304 used in ordinary buildings. In the process of forming an insertion groove into which the tip 41 of the driver bit 40 is fitted in the head, it is known that such a transformation has already occurred, and the present invention has been achieved.

  As shown in FIG. 3, in the present magnetic auxiliary tool 1, when a driver bit 40 made of a ferromagnetic material is inserted into the hollow through-hole 13, the driver bit 40 is magnetized, and a stainless screw or the like is used. When the bit insertion groove 48 formed in the head 46 of the stainless steel fastener 45 is brought close to the tip 41 of the driver bit 40, the stainless steel screw 45 can be adsorbed. In addition, the code | symbol 47 of FIG.

  As shown in FIG. 4, in the state where the driver bit 40 is inserted into the magnetic field auxiliary tool 1, a magnetic field is generated in which the magnetic lines of force 32 are radiated as shown by the two-dot chain line. In FIGS. 3 and 4, the magnetic force lines 31 along the axis connecting the magnetic poles are shown separately from the magnetic force lines 32.

  That is, in the state where the driver bit 40 is inserted into the hollow through hole 13, the magnetic flux of the six permanent magnets 21 concentrates on the hollow through hole 13 and enters the driver bit 40, and the magnetic flux that enters the driver bit 40 further increases. A magnetic flux loop that enters the distal end side of the yoke 15 of the magnetic field auxiliary tool 1 toward the distal end and a magnetic flux loop that enters the proximal end side and enters the rear end of the yoke 15 of the magnetic field auxiliary tool 1 are formed. If many magnetic lines of force 32 can be guided to the tip 41 of the driver bit 40, a strong magnetic force can be applied to the tip 41 not only by iron but also by stainless steel screws.

  According to the present invention, as described above, a plurality of permanent magnets are joined together in a bundle without gaps, and a hollow through hole is formed in the center to form a petal-like cylindrical body. Since a strong magnetic field is formed by concentrating the magnetic flux radiated from the hollow through-hole, the driver bit 40 is magnetized and a stainless steel fixture 45 such as a stainless steel screw is attracted to the tip 41 of the driver bit 40. However, as a result of further investigation by the present inventor, the magnetic flux entering the driver bit 40 from the permanent magnet 21 is biased so that the magnetic flux directed toward the tip 41 side is larger than the base end 42 side of the driver bit 40. (See the direction of the magnetic force lines 31 in FIGS. 3 and 4), it has been found that a stronger magnetic flux density can be obtained at the tip 41 of the driver bit 40.

  The first form proposed by the present inventors for biasing the magnetic flux toward the tip 41 side of the driver bit 40 is that the direction of magnetization of each of the permanent magnets 21 constituting the petal-like cylindrical body is changed to the hollow through hole. This structure is directed toward the tip side of the driver bit 40 inserted into the motor 13, and such a structure can be easily achieved by setting the magnetization direction of the permanent magnet 21 to an angle with respect to the axis 43 of the driver bit 40. Can be implemented.

  FIG. 5 shows the direction of magnetization of the permanent magnet 21, and FIG. 5A shows a direction perpendicular to the axis 43 of the driver bit 40, that is, 90 degrees, whereas FIG. (B) schematically shows a magnet in which the direction of magnetization of the permanent magnet 21 is tilted by W with respect to the axis 43 of the driver bit 40 and magnetized.

  In FIG. 5A, since the magnetization direction of the permanent magnet 21 is set to be perpendicular to the axis 43 of the driver bit 40, that is, 90 degrees, in this embodiment, the S pole of the permanent magnet 21 is used. And the magnetic pole branch point 35 of the N pole are parallel to the direction of the hollow through hole 13, and the magnetic flux radiated from the permanent magnet 21 enters the driver bit 40 without being biased toward the distal end 41 side and the proximal end 42 side. .

  In FIG. 5B, the direction of magnetization of the permanent magnet 21 is set to an inclined angle W with respect to the axis 43 of the driver bit 40. In this embodiment, the permanent magnet 21 has an S pole and The boundary with the N pole is not parallel to the direction of the hollow through hole 13, and the magnetic pole branch point 35 on the tip 41 side of the driver bit 40 is inclined so as to be away from the surface of the driver bit 40.

  The magnetic flux radiated from the permanent magnet 21 is larger on the tip 41 side of the driver bit 40 than on the base end 42 side. Therefore, by changing the inclination angle W, an optimum value at which a larger magnetic flux density can be obtained on the tip 41 side. Can be explored.

  Further, according to the study of the present inventor, the magnitude of the magnetic flux at the tip 41 of the driver bit 40 is the boundary point on the tip 41 side of the driver bit 40 (the magnetic pole branch point 35) of the boundary line between the S pole and the N pole. To the end face of the permanent magnet 21 on the N-pole side is generally determined by the length of the distance L.

  According to this, as the magnetic pole branch point 35 is located farther from the surface of the driver bit 40, a larger magnetic flux can be concentrated on the tip 41 of the driver bit 40. Therefore, if the thicker permanent magnet 21 is used, the driver bit A strong magnetic force is generated at the tip 41 of 40.

  5B is also useful as a means for providing the magnetic pole branch point 35 at a position far from the surface of the driver bit 40.

  Further, as shown in FIG. 6, the second form of biasing the magnetic flux is to incline the magnetization directions of the permanent magnets 21 constituting the petal-like cylindrical body with respect to the axis 43 of the driver bit 40. In addition to the configuration, the auxiliary permanent magnets 23 having the magnetic poles aligned along the direction of the through hole of the hollow through hole 13 can be provided on the outer periphery of each permanent magnet 21.

  In the form of FIG. 6, the plurality of auxiliary permanent magnets 23 are arranged such that their magnetic poles are arranged along the penetration direction of the hollow through hole 13, and the N pole is arranged on the tip 41 side of the driver bit 40. An auxiliary permanent magnet 23 is disposed on the front.

  According to such a combination of the permanent magnet 21 and the auxiliary permanent magnet 23, the magnetic pole branch point 35 on the tip 41 side of the driver bit 40 can be formed at a further distant position. Then, a stronger magnetic force is generated.

  In the magnetic field auxiliary tool 1 having the configuration shown in FIG. 5B or FIG. 6, many magnetic field lines 31 having an inclination angle W toward the distal end are radiated with respect to the axis 43 of the driver bit 40, so that the thickness is increased. The magnetic force can be increased by the tip 41 of the driver bit 40 without increasing the thickness.

  A test for measuring the magnetic force at the tip 41 of the driver bit 40 was performed on the permanent magnet 21 whose magnetization direction was changed from 60 degrees to 90 degrees with respect to the axis 43 of the driver bit 40. As the permanent magnet 21, a rare earth magnet neodymium magnet having a high residual magnetic flux density was used, but each of which was magnetized with a magnetic flux density of 20000 G and a residual magnetic density of 5000 G was bundled, What was comprised as a petal-like cylindrical body of a hexahedron was used.

  Tests were conducted for projection lengths of 1 mm, 6 mm, 11 mm, 16 mm, and 21 mm from the exit of the hollow through-hole 13 (the end of the permanent magnet 21) to the tip 41 of the driver bit 40.

  It was confirmed that the shorter the protrusion length from the permanent magnet 21 to the tip 41 of the driver bit 40, the stronger the magnetic force at the tip 41, and naturally high magnetic force was generated when the protrusion length was 1 mm. Considering the ease of operation, when the direction of the tip 41 of the driver bit 40 is viewed from above, it is desirable that the tip 41 protrudes to the extent that it is not hidden by the magnetic field auxiliary tool 1, so that the protruding length is about 16 mm. Is required. In that case, a magnetic force of about 6000 gauss can be measured at the tip 41 of the driver bit 40, and it was confirmed that a magnetic force of about 5000 gauss was generated even when the protrusion length was 21 mm. It was sufficient to magnetize the stainless steel fixture 45.

  Further, a test was performed in the case where the auxiliary permanent magnets 23 were further attached to the permanent magnets 21 of the respective magnetic field angles W (corresponding to FIG. 6), and a higher magnetic force was obtained than in the above test.

  As described above, it can be confirmed that the tip 41 of the driver bit 40 can be strongly magnetized by using the magnetizing aid 1 using six neodymium magnets as the permanent magnet 21 and bundling them without gaps. It was.

  Next, the petal-like cylindrical body will be described with reference to FIGS.

  These have the hollow through-hole 13 having a cross-sectional shape other than a hexagon. 7 (a) and 7 (b), the hollow through-hole 13 is circular, FIG. 7 (c) is square, FIG. 7 (d) is pentagonal, and FIG. 7 (e) is rectangular.

  As the permanent magnet 21, three identical arc-shaped permanent magnets 21 are used in FIG. 7A, and four identical arc-shaped permanent magnets 21 are used in FIG. 7B. Further, in FIGS. 7C, 7D, and 7E, a hexagonal shape in which the cross section is a combination of a rectangular shape and an isosceles trapezoid is used, like the permanent magnet 21 shown in FIG. . 7C and 7D, the plurality of permanent magnets 21 have the same shape as each other. In FIG. 7E, two types of permanent magnets 21 are used so as to correspond to the side length of the rectangle. It has been.

  In the five types of shapes shown in FIG. 7, the adjacent permanent magnets 21 are in close contact with each other as in the case shown in FIG. The tip 41 (see FIG. 4) can be effectively given a strong magnetic force.

  The various magnetic attachment aids 1 described above can be used by being attached to a driver bit 40 (see FIG. 3 and the like) such as an electric screwdriver.

1 Magnetic attachment aids for fixtures (Magnetic attachment aids)
DESCRIPTION OF SYMBOLS 10 Main body case 11 Main body 12 Cover body 13 Hollow through-hole 15 Yoke 16 Resin material 21 Permanent magnet 22 Cushion material 23 Auxiliary permanent magnet 25 Chamfering joint surface 31 Magnetic field line (Axis line connecting between magnetic poles)
32 Magnetic field lines 35 Magnetic pole branch point 40 Driver bit 41 Tip of driver bit 42 Base end of driver bit 43 Axis 45 Stainless steel fixture (screw)
46 Head 47 Shaft 48 Bit insertion slot

  The present invention relates to a magnetic auxiliary tool for a fixture for attaching an iron or stainless steel fixture to the tip of the screw by inserting and removing a driver bit or the like, and an electric screwdriver using the magnetic auxiliary tool. .

  As a conventional magnetizing auxiliary tool for a fixture, for example, there is one described in Patent Document 1 below.

  This auxiliary tool is formed of two semi-rings of neodymium magnets, with a space between the two magnets and arranged in a ring shape, and a driver bit is inserted into the central space (hollow through hole). The shaft portion is magnetized, and a rotary fixing tool such as a screw is adsorbed and held at the tip of the driver bit.

JP 2004-141986

  However, in the above document, a fixing tool such as an iron screw is used for attachment, and a magnetic force strong enough to attract and hold a fixing tool such as a stainless steel screw at the tip of an electric screwdriver bit is provided. I can't get it.

  Especially recently, iron and other fasteners are rusted and corroded, so they are not suitable for outdoor buildings, and stainless steel screws are often used. As with iron screws, it is desired to develop an auxiliary tool that can be attracted and held at the tip of an electric screwdriver bit.

  The present invention has been proposed in view of such circumstances, and its purpose is to strongly magnetize the tip of the driver bit and to magnetically attach it even with a stainless steel fixture. It is to provide an auxiliary tool.

  In order to achieve the above-mentioned object, the magnetic auxiliary tool for a fixture according to the present invention has a plurality of permanent magnets, and end portions of the same polarity of adjacent permanent magnets so that a hollow through hole is formed in the center. , And joined together in a bundle without gaps to form a petal-like cylindrical body, and the plurality of permanent magnets are inclined so that the magnetic lines of force are directed toward the tip with respect to the axis of the driver bit inserted into the hollow through hole. By defining the magnetization direction with an angle, the magnetic pole branch point on the tip side of the driver bit is tilted away from the surface of the driver bit.

  In the present invention, a cushion material may be interposed between the end surfaces of the plurality of permanent magnets opposite to the hollow through holes.

  In addition, the plurality of permanent magnets may be configured to further increase the magnetic force by attaching auxiliary permanent magnets to the outer circumferences along the penetration direction of the hollow through holes.

  Furthermore, the petal-like cylindrical body may have a regular n-gon shape.

  Furthermore, the permanent magnet may have a chamfered joint surface formed on adjacent side surfaces between the magnets.

  Moreover, the electric driver of the present invention has a configuration in which the magnetic auxiliary tool for fixing device according to any one of claims 1 to 7 is mounted on a driver bit.

  According to the magnetizing auxiliary tool for a fixing device of the present invention, since it has the above-described configuration, the leakage of the magnetic flux of the structure in which the permanent magnets are bundled is almost eliminated, and the magnetic flux is applied to the hollow through hole into which the driver bit is inserted. Can concentrate. For this reason, a large amount of magnetic lines of force can be collected also at the tip of the driver bit inserted into the hollow through hole, so that a fixing tool such as a stainless steel screw can be magnetically attached.

(A) is a perspective view which shows the external appearance of the magnetic attachment auxiliary tool for fixing tools which concerns on one Embodiment of this invention, (b) is the same side view. (A) is a cross-sectional view corresponding to the line AA in FIG. 1 (b), (b) is a magnetic support for the fixture of FIG. 1 (a) corresponding to the line BB in FIG. 2 (a). It is sectional drawing of a tool. It is the longitudinal cross-sectional view showing the use point of the magnetic attachment auxiliary tool for fixtures, and the state where the screwdriver bit was inserted and the screw was magnetically attached to the tip. It is a figure which shows magnetic flux distribution when a driver bit is inserted by the magnetic attachment auxiliary tool for fixtures. (A), (b) is a schematic explanatory drawing of the permanent magnet used for the magnetizing auxiliary tool for fixtures, and (a) is the direction of 90 degrees with respect to the axis of the driver bit. FIG. 4B is a schematic diagram in which the inclination angle of the magnetization direction of the permanent magnet is an angle smaller than 90 degrees. These are the model explanatory drawings of the auxiliary permanent magnet used for the magnetic attachment auxiliary tool for fixtures. (A)-(e) is a schematic diagram which shows the example of arrangement | positioning of the permanent magnet of the magnetic attachment auxiliary tool for fixtures.

  Embodiments of the present invention will be described below with reference to the accompanying drawings.

  A fixing tool magnetic auxiliary tool 1 (hereinafter referred to as a magnetic auxiliary tool 1) is configured by arranging a plurality of permanent magnets 21 in a petal shape into a cylindrical body. It has a structure in which end portions of the same polarity of adjacent permanent magnets 21 are joined in a bundle without gap so that the through-hole 13 is formed.

  The relationship between the permanent magnet 21 and the hollow through-hole 13 can be as shown in FIG. 7 in addition to that shown in FIG. 2A. The central hollow through-hole 13 is preferably a regular n-square shape. However, it is not limited to such a shape.

  Next, with reference to FIG. 1 and FIG. 2, a more specific structure of the magnetizing aid 1 will be described.

  The magnetic field auxiliary tool 1 shown in FIG. 1 has a cylindrical shape having a hollow through hole 13 at the center (see FIG. 1A). The hollow through hole 13 in the illustrated example has a regular hexagonal column shape, and is arranged at the center position of the circle.

  The magnetic attachment aid 1 includes a main body case 10, a permanent magnet 21, a cushion material 22 made of an elastic material such as rubber, and a yoke 15. Among these, the permanent magnet 21, the cushion material 22, and the yoke 15 are arranged along the penetration direction of the hollow through-hole 13 as seen in FIG. 2.

  The main body case 10 is made of a non-magnetic resin that substantially forms the columnar shape of the magnetic attachment aid 1, and has an opening at the top and a hexagonal opening for forming the hollow through hole 13 at the bottom. It is comprised with the main body 11 and the cover body 12 which block | closes upper opening.

  The permanent magnet 21 is filled with the resin material 16 in the main body 11 of the main body case 10 so that six of the same shape retain the petal shape. The cross-sectional shape of each permanent magnet 21 is a hexagonal shape formed by combining a rectangle and an isosceles trapezoid as shown in FIG. Also, the arrangement of the polarities is the same between the permanent magnets 21. In the example of this figure, the hollow through hole 13 side is arranged to be the N pole, but the S pole and the N pole may be arranged in reverse. .

  In the illustrated example, the six permanent magnets 21 do not form a gap between adjacent permanent magnets 21, and in the illustrated example, both sides corresponding to the leg sides of the isosceles trapezoid are in contact with each other. The chamfered joint surfaces 25 are arranged in a petal shape so as to be in close contact with each other.

  In addition, a cushion material 22 is disposed on the end surface of each of the plurality of permanent magnets 21 opposite to the hollow through hole 13, so that the diameter of the bit inserted into the hollow through hole 13 is slightly larger or smaller. However, the error is absorbed and a gap is not generated.

  Since the six permanent magnets 21 are arranged in the main body 11 of the main body case 10 so that the same magnetic poles face each other, a repulsive force of the same polarity is generated. Therefore, the permanent magnet 21 is firmly restrained by filling the resin material 16 in the main body 11 so as not to break the shape of the petals.

  Next, with reference to FIG. 3 and FIG. 4, how to use the magnetic field auxiliary tool 1 will be described.

  The plurality of permanent magnets 21 are inclined so as to be directed to the tip 41 with respect to the axis 43 (see FIG. 3) of the driver bit 40 inserted into the hollow through-hole 13 as indicated by arrows of the respective magnetization directions. However, such a configuration is not an essential configuration of the present invention as will be described later.

  In general, since a fastener such as a stainless steel screw cannot be magnetized, it cannot be magnetized, but among stainless steels, austenitic (SUS304) is usually a non-magnetic material, It is known that when deformed by applying a large load, it can be transformed into martensite and magnetized, and the present inventor is made of stainless steel screws such as SUS304 used in ordinary buildings. In the process of forming an insertion groove into which the tip 41 of the driver bit 40 is fitted in the head, it is known that such a transformation has already occurred, and the present invention has been achieved.

  As shown in FIG. 3, in the present magnetic auxiliary tool 1, when a driver bit 40 made of a ferromagnetic material is inserted into the hollow through-hole 13, the driver bit 40 is magnetized, and a stainless screw or the like is used. When the bit insertion groove 48 formed in the head 46 of the stainless steel fastener 45 is brought close to the tip 41 of the driver bit 40, the stainless steel screw 45 can be adsorbed. In addition, the code | symbol 47 of FIG.

  As shown in FIG. 4, in the state where the driver bit 40 is inserted into the magnetic field auxiliary tool 1, a magnetic field is generated in which the magnetic lines of force 32 are radiated as shown by the two-dot chain line. In FIGS. 3 and 4, the magnetic force lines 31 along the axis connecting the magnetic poles are shown separately from the magnetic force lines 32.

  That is, in the state where the driver bit 40 is inserted into the hollow through hole 13, the magnetic flux of the six permanent magnets 21 concentrates on the hollow through hole 13 and enters the driver bit 40, and the magnetic flux that enters the driver bit 40 further increases. A magnetic flux loop that enters the distal end side of the yoke 15 of the magnetic field auxiliary tool 1 toward the distal end and a magnetic flux loop that enters the proximal end side and enters the rear end of the yoke 15 of the magnetic field auxiliary tool 1 are formed. If many magnetic lines of force 32 can be guided to the tip 41 of the driver bit 40, a strong magnetic force can be applied to the tip 41 not only by iron but also by stainless steel screws.

  According to the present invention, as described above, a plurality of permanent magnets are joined together in a bundle without gaps, and a hollow through hole is formed in the center to form a petal-like cylindrical body. Since a strong magnetic field is formed by concentrating the magnetic flux radiated from the hollow through-hole, the driver bit 40 is magnetized and a stainless steel fixture 45 such as a stainless steel screw is attracted to the tip 41 of the driver bit 40. However, as a result of further investigation by the present inventor, the magnetic flux entering the driver bit 40 from the permanent magnet 21 is biased so that the magnetic flux directed toward the tip 41 side is larger than the base end 42 side of the driver bit 40. (See the direction of the magnetic force lines 31 in FIGS. 3 and 4), it has been found that a stronger magnetic flux density can be obtained at the tip 41 of the driver bit 40.

  The first form proposed by the present inventors for biasing the magnetic flux toward the tip 41 side of the driver bit 40 is that the direction of magnetization of each of the permanent magnets 21 constituting the petal-like cylindrical body is changed to the hollow through hole. This structure is directed toward the tip side of the driver bit 40 inserted into the motor 13, and such a structure can be easily achieved by setting the magnetization direction of the permanent magnet 21 to an angle with respect to the axis 43 of the driver bit 40. Can be implemented.

  FIG. 5 shows the direction of magnetization of the permanent magnet 21, and FIG. 5A shows a direction perpendicular to the axis 43 of the driver bit 40, that is, 90 degrees, FIG. 5B schematically shows the permanent magnet 21 magnetized with the direction of magnetization inclined by W with respect to the axis 43 of the driver bit 40.

  In FIG. 5A, since the magnetization direction of the permanent magnet 21 is set to be perpendicular to the axis 43 of the driver bit 40, that is, 90 degrees, in this embodiment, the S pole of the permanent magnet 21 is used. And the magnetic pole branch point 35 of the N pole are parallel to the direction of the hollow through hole 13, and the magnetic flux radiated from the permanent magnet 21 enters the driver bit 40 without being biased toward the distal end 41 side and the proximal end 42 side. .

  In FIG. 5B, the direction of magnetization of the permanent magnet 21 is set to an inclined angle W with respect to the axis 43 of the driver bit 40. In this embodiment, the permanent magnet 21 has an S pole and The boundary with the N pole is not parallel to the direction of the hollow through hole 13, and the magnetic pole branch point 35 on the tip 41 side of the driver bit 40 is inclined so as to be away from the surface of the driver bit 40.

  The magnetic flux radiated from the permanent magnet 21 is larger on the tip 41 side of the driver bit 40 than on the base end 42 side. Therefore, by changing the inclination angle W, an optimum value at which a larger magnetic flux density can be obtained on the tip 41 side. Can be explored.

  Further, according to the study of the present inventor, the magnitude of the magnetic flux at the tip 41 of the driver bit 40 is the boundary point on the tip 41 side of the driver bit 40 (the magnetic pole branch point 35) of the boundary line between the S pole and the N pole. To the end face of the permanent magnet 21 on the N-pole side is generally determined by the length of the distance L.

  According to this, as the magnetic pole branch point 35 is located farther from the surface of the driver bit 40, a larger magnetic flux can be concentrated on the tip 41 of the driver bit 40. Therefore, if the thicker permanent magnet 21 is used, the driver bit A strong magnetic force is generated at the tip 41 of 40.

  5B is also useful as a means for providing the magnetic pole branch point 35 at a position far from the surface of the driver bit 40.

  Further, as shown in FIG. 6, the second form of biasing the magnetic flux is to incline the magnetization directions of the permanent magnets 21 constituting the petal-like cylindrical body with respect to the axis 43 of the driver bit 40. In addition to the configuration, the auxiliary permanent magnets 23 having the magnetic poles aligned along the direction of the through hole of the hollow through hole 13 can be provided on the outer periphery of each permanent magnet 21.

  In the form of FIG. 6, the plurality of auxiliary permanent magnets 23 are arranged such that their magnetic poles are arranged along the penetration direction of the hollow through hole 13, and the N pole is arranged on the tip 41 side of the driver bit 40. An auxiliary permanent magnet 23 is disposed on the front.

  According to such a combination of the permanent magnet 21 and the auxiliary permanent magnet 23, the magnetic pole branch point 35 on the tip 41 side of the driver bit 40 can be formed at a further distant position. Then, a stronger magnetic force is generated.

  In the magnetic field auxiliary tool 1 having the configuration shown in FIG. 5B or FIG. 6, many magnetic field lines 31 having an inclination angle W toward the distal end are radiated with respect to the axis 43 of the driver bit 40, so that the thickness is increased. The magnetic force can be increased by the tip 41 of the driver bit 40 without increasing the thickness.

  A test for measuring the magnetic force at the tip 41 of the driver bit 40 was performed on the permanent magnet 21 whose magnetization direction was changed from 60 degrees to 90 degrees with respect to the axis 43 of the driver bit 40. As the permanent magnet 21, a rare earth magnet neodymium magnet having a high residual magnetic flux density was used, but each of which was magnetized with a magnetic flux density of 20000 G and a residual magnetic density of 5000 G was bundled, What was comprised as a petal-like cylindrical body of a hexahedron was used.

  Tests were conducted for projection lengths of 1 mm, 6 mm, 11 mm, 16 mm, and 21 mm from the exit of the hollow through-hole 13 (the end of the permanent magnet 21) to the tip 41 of the driver bit 40.

  It was confirmed that the shorter the protrusion length from the permanent magnet 21 to the tip 41 of the driver bit 40, the stronger the magnetic force at the tip 41, and naturally high magnetic force was generated when the protrusion length was 1 mm. Considering the ease of operation, when the direction of the tip 41 of the driver bit 40 is viewed from above, it is desirable that the tip 41 protrudes to the extent that it is not hidden by the magnetic field auxiliary tool 1, so that the protruding length is about 16 mm. Is required. In that case, a magnetic force of about 6000 gauss can be measured at the tip 41 of the driver bit 40, and it was confirmed that a magnetic force of about 5000 gauss was generated even when the protrusion length was 21 mm. It was sufficient to magnetize the stainless steel fixture 45.

  Further, a test was performed in the case where the auxiliary permanent magnets 23 were further attached to the permanent magnets 21 of the respective magnetic field angles W (corresponding to FIG. 6), and a higher magnetic force was obtained than in the above test.

  As described above, it can be confirmed that the tip 41 of the driver bit 40 can be strongly magnetized by using the magnetizing aid 1 using six neodymium magnets as the permanent magnet 21 and bundling them without gaps. It was.

  Next, the petal-like cylindrical body will be described with reference to FIGS.

  These have the hollow through-hole 13 having a cross-sectional shape other than a hexagon. 7 (a) and 7 (b), the hollow through-hole 13 is circular, FIG. 7 (c) is square, FIG. 7 (d) is pentagonal, and FIG. 7 (e) is rectangular.

  As the permanent magnet 21, three identical arc-shaped permanent magnets 21 are used in FIG. 7A, and four identical arc-shaped permanent magnets 21 are used in FIG. 7B. Further, in FIGS. 7C, 7D, and 7E, a hexagonal shape in which the cross section is a combination of a rectangular shape and an isosceles trapezoid is used, like the permanent magnet 21 shown in FIG. . 7C and 7D, the plurality of permanent magnets 21 have the same shape as each other. In FIG. 7E, two types of permanent magnets 21 are used so as to correspond to the side length of the rectangle. It has been.

  In the five types of shapes shown in FIG. 7, the adjacent permanent magnets 21 are in close contact with each other as in the case shown in FIG. The tip 41 (see FIG. 4) can be effectively given a strong magnetic force.

  The various magnetic attachment aids 1 described above can be used by being attached to a driver bit 40 (see FIG. 3 and the like) such as an electric screwdriver.

1 Magnetic attachment aids for fixtures (Magnetic attachment aids)
DESCRIPTION OF SYMBOLS 10 Main body case 11 Main body 12 Cover body 13 Hollow through-hole 15 Yoke 16 Resin material 21 Permanent magnet 22 Cushion material 23 Auxiliary permanent magnet 25 Chamfering joint surface 31 Magnetic field line (Axis line connecting between magnetic poles)
32 Magnetic field lines 35 Magnetic pole branch point 40 Driver bit 41 Tip of driver bit 42 Base end of driver bit 43 Axis 45 Stainless steel fixture (screw)
46 Head 47 Shaft 48 Bit insertion slot

Claims (8)

  A plurality of permanent magnets are joined together in a bundle without gaps so that a hollow through-hole is formed at the center, thereby forming a petal-like cylindrical body. A magnetic auxiliary tool for fixtures. In claim 1,
Each of the plurality of permanent magnets is a magnetizing auxiliary tool for a fixture, wherein a cushion material is interposed on an end surface opposite to the hollow through hole. In claim 1 or 2,
The fixing support magnetic attachment tool, wherein the plurality of permanent magnets define a magnetization direction with an inclination angle of a magnetic force line toward a tip with respect to an axis of a driver bit inserted into the hollow through hole. In any one of Claims 1-3,
The plurality of permanent magnets is a magnetizing auxiliary tool for a fixture, wherein auxiliary permanent magnets having magnetic poles aligned along the penetrating direction of the hollow through hole are attached to the outer periphery thereof. In any one of Claims 1-4,
The petal-like cylindrical body is a magnetizing auxiliary tool for fixtures having a regular n-gonal shape. In any one of Claims 1-5,
The permanent magnet has a chamfering joint surface on an adjacent side surface, and is a magnetic attachment aid for a fixture. In any one of Claims 1-6,
The fixing tool is a fixing tool such as a stainless steel screw. The electric driver which mounted | wore the driver bit with the magnetic sticking auxiliary tool for fixing tools in any one of Claims 1-7.

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