JP2008297937A - Fan motor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fan motor capable of being manufactured at lower cost. <P>SOLUTION: The fan motor 1 is provided with a fan formed body 13 rotating around a shaft 15, a bearing 7 supporting the shaft 15 of the fan formed body 13, a sleeve 5 supporting the bearing 7, a cap 8 fixing the bearing 7 on the sleeve 5. A press-in deformation part 23 formed by pressing is provided on a cap 8, and the cap 8 is enabled to be pressed in an inside of the sleeve 5. Consequently, the fan motor 1 can be manufactured at lower cost by using the press cap 8 for the fan motor 1 more than a case using a machined cap. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a fan motor mounted on an electronic device and having fan blades extending in the outer peripheral direction of a rotor.

  In recent years, personal computers are becoming thinner and lighter. For this reason, every component is required to be reduced in size, thickness and weight. Price competition is also intensifying due to the entry of overseas manufacturers. Even considering a cooling fan, which is one of the parts of a personal computer, cost competition is intensifying. In the structure of a fan motor, there are blades and a bearing that supports the blades. The bearing structure for supporting the blades is composed of a bearing, a sleeve, and a cap (Patent Document 1).

  FIG. 15 shows an example of such a fan motor. Reference numeral 101 denotes a fan motor provided inside a housing of various electronic devices. The outer motor 102 includes a rotating device 103 as a fan motor. The rotating device 103 includes a bottomed cylindrical sleeve 105 provided on one side of the outer shell 102, that is, a thrust plate 106 attached to the inner bottom surface of the sleeve 105, and the sleeve 105 after the thrust plate 106 is inserted. A bearing 107 that is press-fitted and fixed inside, a cap 108 that is provided at an opening on the upper surface of the sleeve 105, prevents the bearing 107 from being detached from the sleeve 105, and is fixedly attached to the outer periphery of the sleeve 105. A circuit board 110 on which the stator 109 and other elements wound thereon are mounted, a fan molded body 113 having a plurality of blades 112 on the outer peripheral side surface of the cup-shaped central portion 111, and the central portion 111. The yoke 114 is fixedly attached to the inner peripheral surface by insert molding, and the center portion 111 is also fixed by insert molding. A shaft 115 as a rotating shaft that is fixed to the shaft 108 and is rotatably supported on the inner peripheral surface of the bearing 107 through the cap 108, and an inner peripheral side surface of the yoke 114 that faces the stator 109. And a permanent magnet 116. The outer shell 102 includes an intake hole 118 provided on at least one side and an exhaust hole 120 provided in a direction orthogonal to the intake hole 118.

  Such a fan motor 101 applies an electric current to the stator 109, thereby generating an attractive force and a repulsive force with the permanent magnet 116 facing the stator 109, and a fan molded body 113 with the shaft 115 as the rotation center. Rotates. Thereby, the air in the housing is taken in from the intake hole 118 formed on at least one side of the outer shell 102, and warm air is sent out of the housing from the exhaust hole 120 provided in a direction orthogonal to the intake hole 118. Thus, the temperature rise of the heat generating component inside the housing is prevented.

  FIG. 16 shows another example of the fan motor. The fan motor 201 is made of metal so as to fix the cap 209 for fixing the bearing 207 and the core 209A for transmitting the magnetic force of the coil to the sleeve 205. The upper end surface of the formed sleeve 205 is crushed with press teeth and fixed by crimping. The other configuration is the same as that of the fan motor 101 shown in FIG.

FIG. 17 shows another example of the fan motor. The fan motor 301 has a structure in which a bearing 307 made of a sintered oil-impregnated bearing and a thrust plate 306 are assembled to an outer shell 302 having an insert-molded sleeve 305. Other configurations are the same as those of the fan motor 101 shown in FIG. As another example, as shown in FIG. 18, there is a configuration in which a cap 308 for collecting bearing oil is added to the configuration of the fan motor 301 shown in FIG.
JP 2004-341669 A

  In the fan motor 101 shown in FIG. 15, the cap 107 is a cut product, and is produced by cutting one point at a time.

  Further, the fan motor 201 shown in FIG. 16 has a problem that metal scraps are generated when the sleeve is caulked and enters the bearing 207, noise is worsened and the life of the fan motor 1 is reduced. Since the sleeve 205 made of metal and the outer shell 102 made of resin are necessarily separate parts, there is a problem in that the number of assembly steps and the number of parts increase, and the cost increases.

  Further, in both fan motors 301 shown in FIGS. 17 and 18, a bearing 307 made of a sintered oil-impregnated bearing is fixed to the outer shell 302 made of resin only by press-fitting. The bearing 307 sometimes dropped off. In addition, since the bearing oil is not collected in the configuration of FIG. 17, particularly when the fan motor 301 is used downward, the bearing oil flows out of the bearing assembly and the life of the fan motor 301 is significantly reduced. It was.

  An object of the present invention is to solve the above problems and provide a fan motor that can be manufactured at a lower cost.

  Moreover, this invention solves the said problem, and provides the fan motor which can fix the core which transmits the magnetic force of the cap and coil which fixes a bearing at low cost, without increasing a number of parts. Objective.

  Furthermore, the present invention solves the above-described problems, and uses a retaining ring having a spring property on a cap, and a fan motor comprising a motor bearing assembly in which a sintered oil-impregnated bearing is firmly fixed in an insert of a resin case The purpose is to provide.

  According to another aspect of the present invention, the fan motor includes a fan that rotates about a shaft, a bearing that supports the shaft of the fan, a sleeve that supports the bearing, and a cap that fixes the bearing to the sleeve. The cap is provided with a press-fitting deformation portion formed by pressing, and the cap can be press-fitted into the sleeve.

  The fan motor according to claim 2 includes a fan that rotates about a shaft, a bearing that supports the shaft of the fan, a sleeve that supports the bearing, and a cap that fixes the bearing to the sleeve. Further, a caulking portion is provided on the cap or the sleeve or both of the cap and the sleeve.

  In the fan motor of the invention of claim 3, a fan, a rotating shaft of the fan, a bearing for holding and rotating the rotating shaft, a sleeve made of a resin for holding the bearing, and a cap for fixing the bearing And a stator provided on the sleeve, wherein a welding portion for fixing the cap and the stator to the sleeve is formed on the sleeve.

  According to a fourth aspect of the present invention, in the fan motor according to the third aspect, the cap is made of resin.

  A fan motor according to a fifth aspect of the present invention is the fan motor according to the third aspect, wherein the cap is made of metal.

  A fan motor according to a sixth aspect of the present invention is the fan motor according to any one of the third to fifth aspects, wherein the cap contains or is coated with an oil repellent.

  A fan motor according to a seventh aspect of the invention is characterized in that, in the fan motor according to any one of the third to sixth aspects, an outer shell of the fan motor is made of resin and is integrally formed with the sleeve.

  The fan motor of the invention of claim 8 is a fan motor comprising a resin case, an insert portion formed in the resin case, and a bearing assembled to the insert portion, and the insert portion has a spring property. A retaining ring is provided, and this retaining ring fixes the bearing to the insert portion.

  The fan motor of the invention of claim 9 is a fan motor comprising a resin case, an insert portion formed in the resin case, a bearing assembled to the insert portion, and a cap, wherein the insert portion has a spring. A retaining ring having a property is provided, and this retaining ring fixes the bearing and the cap to the insert portion.

  According to the first aspect of the present invention, by using a pressed product cap for the fan motor, it is possible to manufacture the fan motor at a lower cost than when using a cut product cap.

  According to the invention of claim 2, by providing the caulking portion, it is possible to prevent the bearing from falling off the sleeve and to improve the fixing strength between the sleeve and the bearing.

  According to the third aspect of the present invention, the cap and the stator can be fixed without increasing the number of parts by forming the welded portion on the sleeve and fixing the cap and the stator at the same time. Also, it is cheaper than the method of fixing the cap and the stator by forming the caulking portion made of press working on the sleeve, and engaging the cap and the stator with the caulking portion, and at the time of press working Since no caulking waste is generated, the fan motor can have a longer life.

  According to the fourth aspect of the present invention, the cap and the cap are made of resin, so that when the weld portion is formed on the sleeve, the sleeve and the cap are melted together, thereby further strengthening the coupling between the sleeve and the cap. Can be prevented from falling off the sleeve.

  According to the fifth aspect of the present invention, the cap is made of metal, so that a structure that is hardly affected by heat or the like when forming the welded portion on the sleeve can be obtained.

  According to the sixth aspect of the present invention, it is possible to prevent the bearing oil of the bearing from leaking out of the sleeve 5 through the cap 8 by containing or applying an oil repellent to the cap.

  According to the seventh aspect of the present invention, since the case that is the outer shell of the fan is made of resin and integrally formed with the sleeve, the outer shell and the sleeve can be formed without increasing the number of parts. A costly fan motor can be manufactured, and the structure of the bearing portion can be strengthened by integrating the sleeve with the outer shell.

  According to the invention of claim 8, the retaining ring is bitten into the inner surface of the sleeve by the elastic restoring force generated at the time of press-fitting, so that the bearing is press-fitted with the insert portion by heat or impact applied to the bearing structure. When the fitting due to fixing is loosened and the bearing moves in the direction of detachment of the insert part, a retaining ring is used to abut and support the bearing that moves in the direction of detachment so that the bearing does not come off from the insert part. The bearing can be firmly fixed to the insert part.

  According to the ninth aspect of the present invention, the bearing and the cap are inserted into the insert portion by heat or impact applied to the bearing structure by causing the retaining ring to bite into the inner surface of the sleeve by the elastic restoring force generated at the time of press-fitting. When the fitting due to press-fitting is loosened and the bearing and cap move in the direction of detachment of the insert part, the bearing and cap that move in the direction of removal are abutted and supported by the retaining ring, and the bearing and The bearing and the cap can be firmly fixed to the insert portion by pressing the cap so that it does not come off.

  Hereinafter, preferred embodiments of a fan motor according to the present invention will be described with reference to the accompanying drawings. FIGS. 1 to 4 show a first embodiment of the present invention. Reference numeral 1 denotes a fan motor provided inside a housing of various electronic devices. This is an outer shell 2 made of a member or resin excellent in thermal conductivity. Is provided with a rotating device 3 as a fan motor. The rotating device 3 includes a bottomed cylindrical sleeve 5 provided by caulking on one side, that is, the lower side of the outer shell 2, by insert molding, welding, or integral molding, and a thrust plate 6 mounted on the inner bottom surface of the sleeve 5. A bearing 7 that is press-fitted and fixed inside the sleeve 5 after the thrust plate 6 is inserted; a cap 8 that is provided in an opening on the upper surface of the sleeve 5 to prevent the bearing 7 from being detached from the sleeve 5; A circuit board 10 on which a stator 9 having a core 9A and a coil wound thereon and other elements are mounted, and a plurality of blades 12 are provided on the outer peripheral side surface of a cup-shaped center portion 11. A fan molded body 13 that is a fan, a yoke 14 that is attached and fixed to the inner peripheral surface of the center portion 11 by insert molding, and is also fixed and fixed to the center of the center portion 11 by insert molding. A shaft 15 as a rotating shaft that passes through the cap 8 and is rotatably supported on the inner peripheral surface of the bearing 7; and a permanent magnet 16 that is provided on the inner peripheral side surface of the yoke 14 so as to face the stator 9. Consists of. The outer shell 2 includes an intake hole 18 provided on at least one side and an exhaust hole 20 provided in a direction orthogonal to the intake hole 18. The outer diameter of the shaft 15 here is φ3 mm or less. In the present embodiment, the intake hole 18 is provided in one place in the drawing, but a cover that covers the upper portion of the outer shell 2 is provided, and both surfaces of the cover are provided with an intake hole facing the intake hole 18. An intake type fan motor may be used.

  As shown in FIGS. 3 and 4, the cap 8 is formed from a cylindrical sheet metal in a ring shape in plan view, which includes a shaft penetration portion 22 formed at the center of the upper surface portion 21 and a press-fit deformation portion 23. Become.

  Here, the press-fitting deformation portion 23 is formed so that the cap 8 is elastically deformed in the radial direction when a force is applied to the cap 8 in the radial direction. As shown in FIGS. 8 is formed on the outer peripheral side of the lower surface portion 24.

  As shown in FIG. 4, the press-fitting deformed portion 23 bends the outer peripheral portion 25 of the sheet metal substantially vertically downward with respect to the lower surface portion 24 of the cap 8, and further, the outer peripheral end surface 26 of the sheet metal is substantially vertically upward. The portion 25 is formed by folding outward 180 degrees. When the outer peripheral portion 25 is folded outward, the top portion 28 is downward in FIG. 4, that is, the bent portion formed toward the insertion direction of the cap 8 is a downward protrusion 27 of the outer peripheral portion 25. The folding and folding of the sheet metal is performed by pressing using a press machine or the like.

  The outer diameter of the cap 8, that is, the outer diameter D1 of the press-fitting deformation portion 23 is formed to be equal to or greater than the inner diameter D2 of the sleeve 5.

  Further, the bending direction of the sheet metal when forming the press-fitted deformation portion 23 is not limited to the downward direction with respect to the lower surface portion 24, and may be upward with respect to the upper surface portion 21. It is good also as what was bent in what is called a wave shape bent toward 21 upwards. Further, the folding direction of the sheet metal is not limited to the outside, and may be the inside, and the angle at which the sheet metal is folded back is not limited to 180 degrees.

  Further, the cap 8 of the present embodiment is not particularly limited in the vertical direction shown in FIGS. 1, 2, and 4. Even if the through-hole 22 is formed in the lower surface portion 24, the press-fit deformed portion is also used. Even if 23 is provided on the upper surface portion 21, the top portion 28 of the downward projection 27 of the press-fitting deformation portion 23 faces upward in the figure, that is, in the opposite direction which is different from the insertion direction of the cap 8. It may be formed.

  In this embodiment, the press-fitting deformation portion 23 is provided on the outer peripheral side of the cap 8. However, if the cap 8 is elastically deformed in the radial direction, the pressure deformation portion 23 is provided on the inner peripheral side of the cap 8. Also, the cap 8 may be provided on both the outer peripheral side and the inner peripheral side.

  Here, FIG. 5 shows a modification of the first embodiment. The upper surface 5A of the sleeve 5 is formed by being widely crushed in the radial direction of the sleeve 5, that is, in the radial direction of the shaft 15 by press working with press teeth or the like. The first caulking portion 31 is provided. Similarly, the outer peripheral end surface 26 of the cap 8 is provided with a second caulking portion 32 that is formed by being crushed widely in the radial direction of the cap 8, that is, the radial direction of the shaft 15 by press working with press teeth or the like. As described above, in the modification of the first embodiment shown in FIG. 5, the sleeve 5 and the cap 8 are respectively provided with the caulking portions 31 and 32. These caulking portions 31 and 32 may be provided only on either the sleeve 5 or the cap 5. In this modification, the outer diameter of the cap 8 before the caulking portion 32 is formed is equal to or smaller than the inner diameter of the sleeve 5 before the caulking portion 31 is formed.

  Next, the operation of the above configuration will be described. Here, in assembling the fan motor as shown in FIGS. 1 and 2, after the thrust plate 6 is mounted on the inner bottom surface of the sleeve 5 of the fan motor 1, the bearing 7 is press-fitted and fixed inside the sleeve 5. A cap 8 is inserted into the sleeve 5 from above the bearing 7. Here, the cap 8 inserted into the sleeve 5 from the top portion 28 has the outer diameter of the cap 8 shown in FIGS. 3 and 4, that is, the outer diameter D1 of the press-fitting deformation portion 23 is equal to the inner diameter D2 of the sleeve 5 shown in FIG. Since it is formed to be equivalent or higher, it is inserted into the sleeve 5 in a press-fitted state. In the cap 8 inserted into the sleeve 5 in a press-fit state, the press-fit deformation portion 23 is provided so as to cause elastic deformation in the radial direction of the cap 8 when a force is applied in the radial direction of the cap 8 at the time of insertion. Yes. During the elastic deformation, an outer peripheral surface 8A of the cap 8 is generated by an elastic restoring force F1 (indicated by a white arrow in FIG. 2) generated radially outward from the deformed press-fitted deformation portion 23 with respect to the cap 8. Is firmly pressed against the inner surface of the sleeve 5. In this case, the cap 8 is smoothly inserted by being inserted from the top portion 28. However, since the outer peripheral end surface 26 of the inserted cap 8 is formed upward, the cap 8 is detached in the direction opposite to the insertion direction. In the direction, the outer peripheral end face 26 that has received this elastic restoring force F1 is caught on the inner face of the sleeve 5, so that the cap 8 is not easily detached.

  As described above, the upper portion of the sleeve 5 is firmly closed by the cap 8, thereby preventing the bearing 7 from falling off the sleeve 5. Further, since the bearing 7 is pressed into the sleeve 5 by the top portion 28 of the downward protrusion 27, the bearing 7 is prevented from idling inside the sleeve 5.

  In the fan motor 1 manufactured in this manner, by applying an electric current to the stator 9, an attractive force and a repulsive force are generated between the stator 9 and the permanent magnet 16, and the fan is driven with the shaft 15 as the rotation center. The molded body 13 rotates. Thereby, the air in the housing is taken in from the intake hole 18 formed on at least one side of the outer shell 2, and warm air is sent out from the exhaust hole 20 provided in a direction orthogonal to the intake hole 18 to the outside of the housing. Thus, the temperature rise of the heat generating component inside the housing is prevented.

  Further, in the modification of this embodiment shown in FIG. 5, the cap 8 having the second caulking portion 32 formed by being crushed widely in the radial direction of the cap 8, that is, the radial direction of the shaft 15, is inserted into the sleeve 5 in a press-fit state. Since the second caulking portion 32 is pressed against the inner surface of the sleeve 5 by being fitted to the cap 5, the cap 8 is firmly fixed to the sleeve 5.

  Then, after the stator 9, particularly the core 9 </ b> A, is mounted on the outer periphery of the sleeve 5, the upper surface 5 </ b> A of the sleeve 5 is crushed widely in the radial direction of the sleeve 5 by pressing with press teeth or the like, and the first caulking portion 31. Since the first caulking portion 31 is engaged with the core 9A of the stator 9 and the second caulking portion 32 provided on the cap 8, the core 9A and the cap 8 of the stator 9 are Prevents the sleeve 5 from falling off.

  By providing each of the caulking portions 31 and 32 on one of the sleeve 5 and the cap 8, the sleeve 5 and the cap 8 are locked by the caulking portions 31 and 32 provided on either one of the cap 5 and the cap 8. Prevents the sleeve 5 from falling off.

  As described above, in the present embodiment, the fan molded body 13 that rotates about the shaft 15, the bearing 7 that supports the shaft 15 of the fan molded body 13, the sleeve 5 that supports the bearing 7, and the bearing 7 are the sleeve 5. The fan motor 1 includes a cap 8 that is fixed to the cap motor 8. The cap motor 8 includes a press-fitting deformation portion 23 formed by press working, and the cap 8 can be press-fitted into the sleeve 5. By using the pressed product cap 8, it is possible to manufacture at a lower cost than when using a cut product cap.

  A fan including a fan molded body 13 that rotates about the shaft 15, a bearing 7 that supports the shaft 15 of the fan molded body 13, a sleeve 5 that supports the bearing 7, and a cap 8 that fixes the bearing 7 to the sleeve 5. In the motor 1, the caulking portions 31 and 32 are provided on the cap 8 or the sleeve 5 or both the cap 8 and the sleeve 5, and the caulking portions 31 and 32 are provided, so that the bearing 7 is dropped from the sleeve 5. This can be prevented and the fixing strength between the sleeve 5 and the bearing 7 can be improved.

  Next, a second embodiment of the fan motor according to the present invention will be described with reference to FIGS. Note that portions corresponding to those in the first embodiment are denoted by the same reference numerals and description thereof is omitted.

  The fan motor 1 of the present embodiment is provided with a bottomed cylindrical sleeve 5 made of resin, a bearing 7 that is press-fitted and fixed inside the sleeve 5, and an upper surface opening of the sleeve 5. A cap 8 that prevents the bearing 7 from being detached, a core 9A that is fixedly attached to the outer periphery of the sleeve 5 and constitutes the stator 9, and a rotation that is rotatably supported on the inner peripheral surface of the bearing 7 through the cap 8. And a shaft 15 as an axis.

  Here, as shown in FIG. 6, the sleeve 5 is provided with a welded portion 41 that is formed by being widely crushed in the radial direction of the sleeve 5, that is, the radial direction of the shaft 15, on the upper surface 5 </ b> A of the sleeve 5 made of resin. And the cap 8 and the stator 9, particularly the core 9A.

  The welding portion 41 is formed by melting the upper surface 5A of the sleeve 5 by welding means W such as heat welding or ultrasonic welding.

  The cap 8 includes a through-hole 8B through which the shaft 15 can be inserted, and is formed of metal or resin. The cap 8 is subjected to a so-called oil repellent treatment in which an oil repellent is impregnated or applied. In particular, the cap 8 made of resin melts at least a part of the cap 8 by thermal welding or ultrasonic welding when forming the welded portion 41 in the sleeve 5, so that a welded portion (not shown) is also formed on the cap side. And is welded integrally with the welded portion 41 of the sleeve 5. A clearance (gap) C (not shown) between the penetrating portion 8B of the cap 8 and the shaft 15 inserted through the penetrating portion 8B is formed at a distance so as not to hinder the rotation of the shaft 15. The clearance C is, for example, about 0.05 mm to about 0.2 mm.

  The bearing 7 may be either a sliding bearing such as a fluid bearing or a rolling bearing such as a ball bearing.

  Further, when the outer shell 2 is made of resin, the sleeve 5 made of resin as in the outer shell 2 may be formed by integral molding or the like.

  The operational effects of the above configuration will be described. By performing thermal welding or ultrasonic welding on the upper surface 5A of the sleeve 5 made of resin, the fan motor 1 assembled as shown in FIG. By forming a welded portion 41 as shown, and fixing the sleeve 5 and the cap 8 and the core 9A attached to the sleeve 5 together so as to cover the cap 8 and the core 9A from above, the cap 8 6 and at least upward in the axial direction of the sleeve 5 shown in FIG. 6 in the core 9A, that is, at least upward movement in the axial direction of the shaft 15 is restricted to prevent the cap 8 and the core 9A from falling off the sleeve 5. In this case, by forming the cap 8 from resin, the upper surface 5A of the sleeve 5 and the cap 8 are melted with each other, so that the sleeve 5 and the cap 8 are more strongly joined, and the cap 8 is prevented from falling off the sleeve 5. prevent. Furthermore, by forming the bearing 7 from metal, it is possible to make the structure less susceptible to the influence of welding means such as thermal welding and ultrasonic welding when forming the welded portion on the sleeve, and the clearance C is formed with high accuracy. And the rotation of the shaft is kept accurate.

  When the bearing 7 is a slide bearing, the bearing oil attached to or contained in the bearing 7 passes through a minute gap between the bearing 7 and the shaft 15 due to a capillary phenomenon as the shaft 15 rotates, and the sleeve 8 When the inside of the shaft 15 springs up along the surface of the shaft 15 and reaches the vicinity of the cap 8, the clearance C between the penetrating portion 8B of the cap 8 and the shaft 15 inserted through the penetrating portion 8B impedes the rotation of the shaft 15. The cap 8 that has been subjected to an oil repellent treatment impregnated or coated with an oil repellent agent has been formed so that it does not come out, and it has springed up along the surface of the shaft 15. Bearing oil that passes through and leaks out of the sleeve is spilled off. As a result, the bearing oil that flows up along the shaft 15 is prevented from passing through the cap 8 and leaking to the outside of the sleeve 5.

  When the outer shell 2 is made of resin, the outer shell 2 and the sleeve 5 are formed without increasing the number of parts by forming the sleeve 5 made of resin in the same manner as the outer shell 2 by integral molding or the like. Therefore, the low-cost fan motor 1 can be manufactured, and the sleeve 5 is integrated with the outer shell 2, so that the structure of the bearing 7 portion can be strengthened. .

  As described above, in this embodiment, the fan molded body 13, the shaft 15 of the fan molded body 13, the bearing 7 that holds and rotates the shaft 15, and the sleeve 5 that is made of a resin that holds the bearing 7, A fan motor 1 having a cap 8 for fixing a bearing 7 and a stator 9 provided on the sleeve 5, wherein a welded portion 41 for fixing the cap 8 and the stator 9 to the sleeve 5 is formed on the sleeve 5. As a result, the cap 8 and the stator 9 can be fixed without increasing the number of components. Further, it is cheaper than a method of fixing the cap 8 and the stator 9 by forming a caulking portion formed by press working on the sleeve 5 and engaging the cap 8 and the stator 9 with the caulking portion. And since the metal scrap at the time of crimping which generate | occur | produces at the time of press work does not generate | occur | produce, it can be set as the fan motor 1 with a longer lifetime.

  Further, since the cap 8 is made of resin, the sleeve 5 and the cap 8 are melted together when the welded portion 41 is formed on the sleeve 5, so that the coupling between the sleeve 5 and the cap 8 becomes stronger. Can be prevented from falling off the sleeve 5.

  Furthermore, since the cap 8 is made of metal, a structure that is hardly affected by heat or the like when forming the welded portion 41 on the sleeve 5 can be obtained.

  In addition, the cap 8 contains or applies an oil repellent agent, thereby preventing the bearing oil of the bearing 7 from passing through the cap 8 and leaking to the outside of the sleeve 5.

  Further, the outer shell 2 of the fan motor 1 is made of resin and is integrally formed with the sleeve 5 so that the outer shell 2 and the sleeve 5 can be formed without increasing the number of parts. In addition, since the sleeve 5 is integrated with the outer shell 2, the structure of the bearing portion can be strengthened.

  Next, a third embodiment of the fan motor 1 of the present invention will be described with reference to FIGS. Note that portions corresponding to those in the first embodiment are denoted by the same reference numerals and description thereof is omitted.

  The fan motor 1 according to the present embodiment includes, for example, a bottomed cylindrical sleeve 5 that is an insert portion integrally formed of resin by insert molding on an outer shell 2 that is a resin case of the fan motor 1, and press-fitted and fixed inside the sleeve 5. Of the bearing 7, the cap 8 provided in the upper opening of the sleeve 5, the retaining ring 51 mounted on the sleeve 5 from above the cap 8, and the cap 8 and the retaining ring 51 penetrating the bearing 7. And a shaft 15 as a rotating shaft that is rotatably supported on the inner peripheral surface.

  The bearing 7 is a cylindrical sintered oil-impregnated bearing in which a green compact obtained by compressing raw material powder is heated and sintered, and a sintered body obtained by the sintering is impregnated with bearing oil.

  As shown in FIGS. 10 to 13, the retaining ring 51 is made of a sheet metal having a spring property formed in a ring shape in plan view having a through-hole 52 for a shaft at the center, and projects radially from the outer peripheral edge 53 of the sheet metal. A plurality of locking protrusions 54 are provided. As shown in FIGS. 10 and 12, the locking protrusions 54 protrude from the center of the sheet metal at equal angles (for example, the angle θ is 60 degrees). Further, as shown in FIGS. 11 and 13, the locking protrusion 54 is formed by bending in the axial direction of the retaining ring 51 from the base end 55 side. Thereby, the diameter of the retaining ring 51 is increased from the base end 55 side to the distal end 56 side of the locking projection piece 54 with respect to the axial direction by the locking projection piece 54 formed by bending in the axial direction on the outer periphery of the retaining ring 51. Thus, the inclined surface 57 is formed. As shown in FIGS. 10 to 13, the outer diameter D3 including the retaining protrusions 54 of the retaining ring 51 is equal to the inner diameter D2 (see FIG. 2) of the sleeve 5 to which the retaining ring 51 is attached. It is formed more than that.

  As shown in FIGS. 10 and 12, with respect to the retaining ring 51, a plurality of types of retaining rings 51 are prepared depending on the difference in the width H on the proximal end 55 side of the retaining protrusion 54. Regarding the shape of the base end 55 side, as shown in FIG. 10, the width H is formed large, and the base end 55 sides of the adjacent locking projections 54 are connected to each other, or as shown in FIG. There is one in which a width H is formed so as to protrude independently from the outer peripheral edge 53 of the sheet metal in a state where the base end 55 side of the stop projecting piece 54 is separated.

  Further, as shown in FIG. 9, a notch 58 is formed on the inner peripheral side of the lower surface of the cap 8 formed in a ring shape in the vertical direction in the figure.

  As shown in FIG. 9, a stepped portion 59 having a surface that is made lower by reducing the diameter of the shaft 15 is provided at a location corresponding to the cap 8 of the shaft 15.

  The bearing 7 and the cap 8 are provided so as to be press-fitted into the sleeve 5 by any one of an interference fit, an intermediate fit, and a clearance fit.

  FIG. 14 shows a modification of the present embodiment. The fan motor 1 includes a bottomed cylindrical sleeve 5 integrally formed of resin by insert molding on the outer shell 2 of the fan motor 1, and the inside of the sleeve 5. A bearing 7 which is press-fitted into the sleeve, a retaining ring 51 provided in the upper surface opening of the sleeve 5, and a shaft as a rotating shaft that is rotatably supported on the inner peripheral surface of the bearing 7 through the retaining ring 51. 15 is the same as the fan motor 1 shown in FIG. 8 except that the cap 8 is omitted.

  The operation and effect of the above configuration will be described. In the assembly of the bearing structure of the fan motor 1 of this embodiment shown in FIG. 8, the bearing 7 is press-fitted and fixed inside the sleeve 5. The cap 8 is press-fitted and fixed to the surface where the notch 58 is formed, and the retaining ring 51 is fixed to the upper end opening of the sleeve 5 from above the cap 8. The shaft 15 is press-fitted and fixed so that the 55 side faces in the press-fitting direction. Finally, the shaft 15 is passed through the cap 8 and the retaining ring 51 so as to be rotatably supported on the inner peripheral surface of the bearing 7.

  As shown in FIG. 9, the retaining ring 51 inserted into the sleeve 5 in a press-fitted state makes the base end 55 side of the locking projection 54 abut against the cap 8, and the tip 56 of the locking projection 54 is connected to the sleeve. 5 is pressed against the inner surface. Here, when the locking protrusion 54 is inserted into the sleeve 5 having a smaller diameter than the retaining ring 51, if a force is applied in the radial direction of the retaining ring 51 from the inner surface of the sleeve 5, the retaining ring 51. Is provided so as to cause elastic deformation so that the diameter thereof is reduced in the radial direction. During the elastic deformation, an elastic restoring force F2 (indicated by a white arrow in FIG. 9) is generated radially outward with respect to the retaining ring 51 by the deformed locking projection piece 54. The locking protrusion 54 is pressed against the inner surface of the sleeve 5 by the force F2. In this case, the diameter of the retaining ring 51 is increased from the proximal end 55 side to the distal end 56 side of the locking projection piece 54 with respect to the axial direction by the locking projection piece 54 formed by being bent in the axial direction. Thus, the retaining ring 51 is inserted from the base end 55 side so that the base end 55 side of the retaining ring 51 is caught by the inside of the sleeve 5 until the base end 55 abuts against the cap 8. Inserted smoothly.

  Further, by inserting the retaining ring 51 from the base end 55 side of the retaining projection 54, the distal end surface 60 of the retaining projection 54, which is the outer peripheral end surface of the inserted retaining ring 51, faces upward in FIG. It is pressed against the inner surface of the sleeve 5 in a direction opposite to the direction in which the ring 51 is inserted (hereinafter referred to as a detaching direction), and the retaining ring 51 is inserted in a press-fitted state, so that the retaining ring 51 is elastically deformed so that its diameter is reduced. Accordingly, the surface direction of the tip surface 60 is more directly opposed to the detachment direction. Thus, the retaining ring 51 in the press-fit state bites the front end 56 side of the locking projection piece 54 by the elastic restoring force F2 in a state where the front end surface 60 of the locking projection piece 54 stands with respect to the inner surface of the sleeve 5. Therefore, the frictional force in the detaching direction is increased with respect to the inner surface of the sleeve 5. For this reason, when the retaining ring 51 tries to move in the disengagement direction, the distal end surface 60 of the locking protrusion 54 on which the elastic restoring force F2 is applied is caught on the inner surface of the sleeve 5, and the retaining ring 51 is not easily detached. It has become. In this case, by combining different materials of the sleeve 5 made of resin and the retaining ring 51 made of metal, the tip 56 of the locking projection piece 54 of the retaining ring 51 made of a material having a high mechanical strength with respect to the sleeve 5 becomes the sleeve 5. The retaining ring 51 is structured to be more difficult to separate from the sleeve 5.

  In this manner, the engagement protrusions 54 of the retaining ring 51 are caused to bite into the inner surface of the sleeve 5 by the elastic restoring force F2 generated at the time of press-fitting, so that the bearing 7 and the cap 8 are subjected to heat or impact exerted on the bearing structure. For example, when the fitting by the press-fitting and fixing with the sleeve 5 is loosened, and the bearing 7 and the cap 8 are moved in the releasing direction of the sleeve 5, the bearing 7 and the cap are about to move in the releasing direction by the retaining ring 51. 8 is abutted and supported so that the bearing 7 and the cap 8 are not removed from the sleeve 5.

  Further, the cap 8 and the bearing 7 can be pressed together by press-fitting and fixing the retaining ring 51 after the cap 8 is press-fitted and fixed inside the sleeve 5 as described above.

  The bearing oil contained in the bearing 7 is supplied to the minute gap between the bearing 7 and the shaft 15 by capillary action, and the gap between the bearing 7 and the shaft 15 springs in the axial direction of the shaft 15 as the shaft 15 rotates. Go up. Here, as shown in FIG. 9, a notch portion 58 is formed in the cap 8, and the surface 8 </ b> C on the side where the notch portion 58 of the cap 8 is formed inside the sleeve 5 is placed on the bearing 7 from above the bearing 7. 7 is brought into contact with the upper surface 7A of the roller 7 and press-fitted and fixed, so that a space K for recovering bearing oil is formed between the cap 8, the bearing 7 and the shaft 15, and the gap between the bearing 7 and the shaft 15 rises. When the bearing oil reaches the vicinity of the cap 8, the bearing oil released into the space K and the surface tension of the shaft 15 is released is the bearing oil recovery route R indicated by the arrow in FIG. And is absorbed by the bearing 7. Thus, by forming the notch portion 58 in the cap 8, the bearing oil supplied to the gap between the shaft 15 and the bearing 7 by the bearing 7 made of a sintered oil-impregnated bearing is removed from this gap by the rotation of the shaft 15. The oil-impregnated bearing 7-shaft 15 and the oil-impregnated oil are used to return the bearing oil to the bearing 7 by the bearing recovery space K formed by the notch portion 58, while trying to leak to the outside of the spring sleeve 5. A bearing oil circulation circuit consisting of a clearance between the bearing 7, a space K, and the oil-impregnated bearing 7 is configured to recover and circulate the bearing oil, thereby preventing leakage of the bearing oil, and the lack of bearing oil in the oil-impregnated bearing 7. This prevents the operating life of the fan motor 1 from being lowered.

  Furthermore, in the present embodiment, as shown in FIG. 9, the step portion 59 having a lower surface by reducing the diameter of the portion corresponding to the cap 8 of the shaft 15 is provided. As indicated by the route R, the bearing oil that springs up through the surface of the shaft 15 through the gap between the shaft 15 and the bearing 7 is dropped onto the bearing 7 by the step portion 59 of the shaft 15, and the bearing oil is supplied to the bearing 7. It has a structure to return. In this case, by collecting and circulating the bearing oil, leakage of the bearing oil is prevented, and a decrease in the operating life of the fan motor 1 due to a lack of bearing oil in the oil-impregnated bearing 7 is prevented.

  As shown in FIGS. 10 and 12, the retaining ring 51 has a different shape due to the difference in the width H on the base end 55 side of the locking projection piece 54, and the larger the width H, the locking projection piece. The bending strength of 54 is large, and the elastic restoring force F2 at the same deformation amount of the locking protrusion 54 is also large. Therefore, when the weight of the fan structure 13 is large and the swinging force due to the centrifugal force is large, the retaining ring 51 having a large width H as shown in FIG. It becomes possible to hold down. Further, the retaining ring having a small width H as shown in FIG. 12 is suitable for use in the case of a fan having a small weight (for example, about 10 g or less).

  14 shows a case where the use of the fan motor 1 is limited so that the surface of the outer shell 2 provided with the intake holes 18 becomes the non-top surface of the outer shell 2. 8, the cap 8 is removed from the fan motor 1 shown in FIG. 8, but the other configurations and operational effects are the same, and thus detailed description thereof is omitted.

  As described above, in this embodiment, the fan motor 1 includes the outer shell 2, the sleeve 5 formed on the outer shell 2, and the bearing 7 assembled to the sleeve 5, and the sleeve 5 has a spring property. By providing the ring 51 and fixing the bearing 7 to the sleeve 5, the retaining ring 51 bites the retaining ring 51 into the inner surface of the sleeve 5 by the elastic restoring force F <b> 2 generated during press-fitting, When the bearing 7 is loosely fitted by press-fitting with the sleeve 5 due to heat or impact applied to the bearing structure and the bearing 7 moves in the direction in which the sleeve 5 is detached, the retaining ring 51 causes the direction of this separation. It is possible to firmly fix the bearing 7 to the sleeve 5 by abutting and supporting the bearing 7 about to move to the sleeve 5 and pressing the bearing 7 so as not to come off from the sleeve 5.

The fan motor 1 includes an outer shell 2, a sleeve 5 formed on the outer shell 2, a bearing 7 assembled to the sleeve 5, and a cap 8. The sleeve 5 is provided with a retaining ring 51 having a spring property. Since the retaining ring 51 fixes the bearing 7 and the cap 8 to the sleeve 5, the retaining ring 51 is bitten into the inner surface of the sleeve 5 by the elastic restoring force F2 generated during press-fitting. 7 and the cap 8 when the fitting due to press-fitting to the sleeve 5 is loosened due to heat or impact applied to the bearing structure and the bearing 7 and the cap 8 move in the direction in which the sleeve 5 is detached. 51, the bearing 7 and the cap 8 which are going to move in the separating direction are abutted and supported, and the bearing 7 and the cap 8 are pressed from the sleeve 5 so as not to come off. The can be firmly fixed to the sleeve 5.

  Further, as an effect of the present embodiment, the bearing 7 is a sintered oil-impregnated bearing, and by collecting and circulating the bearing oil dropped by the cap 8 so as to overflow from the sleeve 5, Leakage can be prevented and the operating life of the fan motor 1 can be prevented from being reduced due to a lack of bearing oil in the oil-impregnated bearing 7.

  In addition, this invention is not limited to said each Example, A various deformation | transformation implementation is possible. For example, with respect to the retaining ring 51, the number of protruding protruding protrusions and the equiangular angle from the center of the sheet metal (in FIG. 10 and FIG. 12, the angle θ is 60 degrees) can be appropriately changed.

1 is an overall cross-sectional view of a fan motor in a first embodiment of the present invention. It is a principal part enlarged view in FIG. 1 same as the above. It is a top view of a cap same as the above. It is sectional drawing of a cap same as the above. It is a principal part expanded sectional view which shows the modification of a fan motor same as the above. It is a principal part expanded sectional view of the fan motor in 2nd Example of this invention. It is a principal part expanded sectional view of a fan motor before a welding part is formed same as the above. It is whole sectional drawing of the fan motor in 3rd Example of this invention. It is the principal part expanded sectional view of a fan motor same as the above. It is a top view of a retaining ring same as the above. FIG. 11 is a cross-sectional view of the retaining ring in FIG. FIG. 11 is a cross-sectional view of a retaining ring having a shape different from that of FIG. 10 retaining ring. FIG. 13 is a cross-sectional view of the retaining ring in FIG. It is a whole sectional view showing a modification of a fan motor same as the above. It is whole sectional drawing of the fan motor which shows a prior art example. It is a principal part expanded sectional view of the fan motor which shows another prior art example. It is whole fan sectional drawing of the fan motor which shows another prior art example. FIG. 18 is an overall cross-sectional view showing a modification of the fan motor shown in FIG.

Explanation of symbols

1 Fan motor 2 Outer shell (resin case)
5 Sleeve (insert part)
7 Bearing 8 Cap 9 Stator 13 Fan molded body (fan)
15 Shaft (Rotating shaft)
23 Press fit deformation part 31 1st caulking part (caulking part)
32 Second caulking part (caulking part)
41 welding part 51 retaining ring

Claims (9)

A fan motor comprising a fan that rotates about a shaft, a bearing that supports the shaft of the fan, a sleeve that supports the bearing, and a cap that fixes the bearing to the sleeve;
A fan motor, wherein the cap includes a press-fitting deformation portion formed by press working, and the cap can be press-fitted into the sleeve. A fan motor comprising a fan that rotates about a shaft, a bearing that supports the shaft of the fan, a sleeve that supports the bearing, and a cap that fixes the bearing to the sleeve;
A fan motor, wherein a caulking portion is provided on the cap, the sleeve, or both of the cap and the sleeve. A fan, a rotating shaft of the fan, a bearing that holds and rotates the rotating shaft, a sleeve made of a resin that holds the bearing, a cap that fixes the bearing, and a stator provided in the sleeve A fan motor comprising:
A fan motor, wherein a welding portion for fixing the cap and the stator to the sleeve is formed in the sleeve.   4. The fan motor according to claim 3, wherein the cap is made of resin.   4. The fan motor according to claim 3, wherein the cap is made of metal.   The fan motor according to claim 3, wherein the cap contains or is coated with an oil repellent.   The fan motor according to any one of claims 3 to 6, wherein an outer shell of the fan motor is made of resin and integrally formed with the sleeve. A fan motor comprising a resin case, an insert portion formed in the resin case, and a bearing assembled to the insert portion,
A fan motor characterized in that a spring retaining ring is provided in the insert portion, and the retaining ring fixes the bearing to the insert portion. A fan motor including a resin case, an insert portion formed in the resin case, a bearing assembled to the insert portion, and a cap,
A fan motor characterized in that a spring retaining ring is provided in the insert portion, and the retaining ring fixes the bearing and the cap to the insert portion.

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