Classifications

• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
  • F04D—NON-POSITIVE-DISPLACEMENT PUMPS
  • F04D17/00—Radial-flow pumps, e.g. centrifugal pumps; Helico-centrifugal pumps
  • F04D17/02—Radial-flow pumps, e.g. centrifugal pumps; Helico-centrifugal pumps having non-centrifugal stages, e.g. centripetal
  • F04D17/04—Radial-flow pumps, e.g. centrifugal pumps; Helico-centrifugal pumps having non-centrifugal stages, e.g. centripetal of transverse-flow type
• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
  • F04D—NON-POSITIVE-DISPLACEMENT PUMPS
  • F04D25/00—Pumping installations or systems
  • F04D25/02—Units comprising pumps and their driving means
  • F04D25/06—Units comprising pumps and their driving means the pump being electrically driven
  • F04D25/0606—Units comprising pumps and their driving means the pump being electrically driven the electric motor being specially adapted for integration in the pump
• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
  • F04D—NON-POSITIVE-DISPLACEMENT PUMPS
  • F04D25/00—Pumping installations or systems
  • F04D25/02—Units comprising pumps and their driving means
  • F04D25/06—Units comprising pumps and their driving means the pump being electrically driven
  • F04D25/0606—Units comprising pumps and their driving means the pump being electrically driven the electric motor being specially adapted for integration in the pump
  • F04D25/0653—Units comprising pumps and their driving means the pump being electrically driven the electric motor being specially adapted for integration in the pump the motor having a plane air gap, e.g. disc-type
• • H—ELECTRICITY
  • H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
  • H02K—DYNAMO-ELECTRIC MACHINES
  • H02K29/00—Motors or generators having non-mechanical commutating devices, e.g. discharge tubes or semiconductor devices
  • H02K29/06—Motors or generators having non-mechanical commutating devices, e.g. discharge tubes or semiconductor devices with position sensing devices
  • H02K29/08—Motors or generators having non-mechanical commutating devices, e.g. discharge tubes or semiconductor devices with position sensing devices using magnetic effect devices, e.g. Hall-plates, magneto-resistors
• • H—ELECTRICITY
  • H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
  • H02K—DYNAMO-ELECTRIC MACHINES
  • H02K7/00—Arrangements for handling mechanical energy structurally associated with dynamo-electric machines, e.g. structural association with mechanical driving motors or auxiliary dynamo-electric machines
  • H02K7/14—Structural association with mechanical loads, e.g. with hand-held machine tools or fans

Definitions

• Impellers used for this type of cross- ⁇ ⁇ -type cooling fan 1 and 24 are mainly synthetic resin molded products, as shown in Fig. 24.
• An air supply slit 3 is formed around the center cavity 2 of the body by means of a group of vanes 4 and sucks from the radial direction of the impeller 1 as it rotates.
• the air is sent by the air slit 3 in the radial direction to heat the heat generated by the electrical components, and a wide, flat cooling air stream is sent in the form of dust. Since it can be used, it is particularly suitable for cooling the electrical component group arranged on the printed circuit board.
• the control circuit of the brushless motor is provided with a special cooling device. It is a huge one to provide a cross-flow type cutting fan device that can efficiently and efficiently displace it.
• * Komoe is because he or she connects multiple impellers in the axial direction and uses the air feed slits of adjacent impellers to make a difference between them.
• the purpose is to provide a cross flow type cooling fan device with significantly improved ventilation efficiency.
• the present invention has an impeller that forms an air-sending slit around the Katsu center cavity, and at both ends of the impeller, is rotatably supported by a supporting frame through a supporting shaft.
• the rotating side impeller, these supporting shafts, and the fixed side supporting frame, the rotating side and the fixed side are equipped with motor magnets.
• the motor winding is arranged so that the motor winding is opposed to the motor magnet, and the rotor winding drive unit is installed. Is configured.
• the motor which is separately manufactured as in the conventional case, is used as the rotary driving means for the blade wheel, and is not directly connected to the impeller.
• Substantial motor function between the impeller and its supporting frame It is possible to rotate the impeller by using the magnet and the winding line, so it is a cross-flow type reject fan device. In addition, it is possible to design compact electrical equipment with a small size and a small installation space.
• the invention is based on the fact that when the motor built in between the impeller and the support frame is configured as a brushless motor, the brushless motor is
• the control circuit part of the rotor may be installed on one side of the baffle plate, and the control circuit part may be cooled by using the cool air from the impeller. In this way, it is economical without the need for installing a cooling device g for the special control circuit section.
• the present invention may be configured such that a plurality of impellers are fast-connected in the axial direction and the air supply slots of adjacent impellers do not eat each other. In this way, the air blown from the adjacent impellers will not be delayed in time, and thus will not interfere and the air blow efficiency will be improved.
• Figures 1 to 4 show a configuration in which a motor is built in between the end face frame and the impeller, and that motor is the brush motor.
• a motor is built in between the end face frame and the impeller, and that motor is the brush motor.
• Figure 1 is a plan view
• FIG. 2 ho longitudinal sectional front view
• Ru Oh in Figure 4 is shown to cross-sectional view of the deformation example of the main part ⁇
• Figures 5 to 12 show other implementations of the brushless motor.
• Fig. 5 is a schematic front view
• Fig. 6 is a schematic plan view
• Fig. 7 is Ichiro Kirie's plan view of Yoro
• Fig. 8 is a side view
• Fig. 9 is Right side view with field winding and hall element for magnetic field detection mounted on the printed circuit board
• Figure 13 is a cross-sectional view of Yoro showing another implementation of the brushless motor.
• Fig. 14 shows a configuration with a motor built in between the end face frame and the impeller, and that motor is a brushed motor. It is a cross-sectional view of Yoro showing the case.
• Fig. 15 is a cross-sectional view of a key showing another embodiment in the case of a motor configuration with a brush.
• Fig. 16 to Fig. 19 show an example of the installation state of the control circuit of the brushless motor.
• Fig. 16 shows the position of the brushless screw Plan views showing the central node of the mold cooling fan device, ⁇ ⁇ — in Fig. 17 and Fig. S (Fig. 18) (Fig. 18 and Fig. 9)
• Fig. 18 shows the position of the brushless screw Plan views showing the central node of the mold cooling fan device, ⁇ ⁇ — in Fig. 17 and Fig. S (Fig. 18) (Fig. 18 and Fig. 9)
• Fig. 18 shows the position of the brushless screw Plan views showing the central node of the mold cooling fan device, ⁇ ⁇ — in Fig. 17 and Fig. S (Fig. 18) (Fig. 18 and Fig. 9)
• Fig. 18 shows the position of the brushless screw Plan views showing the central node of the mold cooling fan device, ⁇ ⁇ — in Fig. 17 and Fig. S (Fig. 18) (Fig
• Fig. 20 to Fig. 23 show an example in which a plurality of impellers are connected and the air supply slots of adjacent impellers are mutually different ⁇ .
• Fig. 20 Fig. 20 External view of the impeller, Fig. 21 is viewed from the opposite direction of Fig. 20: External perspective view, Fig. 22 is for the above two impellers Reject Fig. 23 is a cross-sectional view of the main part of the fan, and Fig. 23 is a cross-sectional view of the impeller.
• Fig. 24 is a perspective view showing the combined use of a conventional impeller and motor.
• FIGS 1 to 4 show an example in which a brushless motor E is installed between the impeller and the support frame as a rotary drive means for the vane wheel. I will.
• Both impellers of the impeller 107 are rotatably supported by the support frames 103 and 110 through the support shafts 111 and 112.
• Each supporting shaft U l ,i l2 is fixed to the end plate part ii 3 ,114 at the end of the vane vehicle, and fixed to the supporting frames 109, 110 by the bearings 115, 116.
• Received. 117 and 118 are bearing cases.
• a required gap 119 was placed between one end of the impeller 107 and its corresponding support frame 110, and a yaw fixed to the end plate hook 114 in this gap 11 9.
• Ku 120 is placed. It is fixed by press-fitting the bin stem 120a protruding from the yoke 120 side into the hole hook formed in the yoke 120 end cap 114.
• a ring magnet 121 is mounted by an adhesive or the like so as to be coaxial with the support shaft 112.
• the outer shaft 122 is fitted to the support shaft 112, and the outer shaft 122 is fixed to the support frame 110 while being fitted to the bearing case 118.
• the iron core 123 which is loosely coaxially fitted in the ring magnet 121, is attached to the mantle U2, and the field winding U4 is attached to the iron core 123.
• the hall element 125 is attached to a part of the iron core 123.
• the hall element U5 detects the rotating ring magnet 121 magnetic field and controls the energization of the field winding 124.
• the motor which is a rotary product of the impeller, is used as a conventional product, and the motor is directly connected to the impeller'.
• the wing magnet and the iron core and the field winding which have a substantial motor function, are arranged. Since it is designed to rotate the car, the cross-flow type
• Figures 5 to 12 show another embodiment in which a brushless motor is installed between the impeller and the supporting frame.
• a recess 21 Oa is formed in the impeller end face 210, and a flat ring-shaped magnet and y-t 214 are press-fit into the recess 210a.
• a fixed group of blades 204 are formed on the outer peripheral side of the magnet 21 4 and a group of magnets 214 is mounted in the impeller 201.
• the outer side inner circumference of the magnet 214 is a small diameter surface 214 a, so that it can be easily press-fitted and the elasticity of the synthetic resin impeller asbestos surface 210.
• the flat magnet 214 is not damaged.
• a print S3 wire substrate 215 is provided on the inner surface of the support frame 206 so as to face the magnets and y 214.
• the printed wiring board 215 has a wiring pattern of a driving circuit as shown in Fig. 10 printed on a substrate made of a silicon board.
• the coil connection hooks 215a to 215d of the field winding are formed at four locations, and the halls for magnetic field detection are also located at two locations.
• Element connection parts 215 e and 215 i are formed.
• the coil wiring parts 215a to 215d of the printed wiring board 215 have a non-ferrous flat and substantially triangular shape field winding 216a.
• ⁇ 21 ⁇ d is connected by g, and each hall element connection S
• each of the printed wiring boards 21 and the control circuit 2158 of the drive circuit 215A is bent and extended.
• the magnet 214 has 6 poles, 3 poles each with the S pole and N pole facing each other in the arrangement shown in Fig. 9. doing .
• the casing that houses the above-mentioned impeller 201 is roughly flat-shaped as shown in Fig. 8, and the housing 218a is concentric with the impeller 201 from Giro. It is composed of a baffle plate 218b that is curved in an arc shape and reaches the bottom, and a pair of support frames 2c, and a wide air intake opening 2 at the top.
• the air exhaust opening 218e is formed on one side, and the control circuit section 215B of the above-mentioned blank S-line board 215 is conducted. ⁇ on the inner surface of the wind plate 218 b
• the circuit shown in Fig. 11 is provided with two corresponding Hall elements 217a and 217b for magnetic field detection, but if one is explained in Fig. 11-11. Only the circuit of.
• the north pole of the magnet 214 is detected by the hall element 217a of the magnetic field detection
• the first pole of the PNP type is detected by the hall element 217a.
• the cluster Q1 is turned on and the second to fourth clusters Q2 to!
• Each H is turned on from the power supply +B to the field windings 21 ⁇ a, 216 c through the third and fourth transistors d3, Q4 in the direction of the N arrow.
• the hall element 217b detects the south pole of the magnetnet 214 due to the rotation of the fifth rotor Q5 the fifth transistor Q5 is turned on and the fifth transistor Q5 is turned on.
• the 6th to 8th transistors Q6 to d8 are turned on respectively, and the field winding 216b, through the 7th and 8th transistors ft7, Q8.
• Tot 214 is rotated further.
• the south pole of the magnet 214 is detected by the hall element 217a
• the fifth PNP type transistor by the hall element 217a is detected. Is turned on, and the 6th to 8th transistors (1 ⁇ to ( ⁇ are turned on, respectively, from the power supply + ⁇ to the 7th and 8th transistors).
• the mutual attraction and repulsive force cause the magnet 214 to rotate the wheel 201.
• the rotation of the wheel element 21 7b causes the hall element 2 17b to rotate on the north pole of the magnet 214.
• the current flows through the field windings 216 b, 2 i 5 d through the third and fourth transistors Q3 and Q4 in the direction of the arrow N, and each field winding
• the magnetic field of the N pole is induced in the lines 216 b and 216 d, and mutual attractive force and repulsive force are generated, so that the magnet 214 is further rotated, and thereafter the similar operation is recovered.
• the rotation of the impeller 201 is maintained. Since the printed board 215 on which the magnetic windings 21 &a to 216 d are arranged is composed of a silicon master plate, iron loss is lightly eliminated.
• the control of energization to each field winding 21 ⁇ a to 2d is a plan. This is performed by the ⁇ fj control circuit section 2158 of the wiring board 2.
• the magnet 2 I 4 and each field winding 2 U a to 216 d have substantially obtained the motor function, they are used as the driving means of the impeller 201.
• the brushless motor part is composed of the U and the blind S-line board 215, and is installed in the magnett 214 and the impeller 201. Therefore, it is possible to reduce the size on a large scale.
• the field windings 2 a to 216 (U or the printed wiring board 215 are installed, it is possible to use a sheet coil, and the field winding 21 ⁇ a ⁇ 21 Sd and hall elements U7a, 7b can be installed in the same drive circuit section 215A of the printed S-line board 215.
• the drive circuit 215A and the grate control circuit 2158 are individually provided, complicated work such as soldering for connecting them to each other is required. It requires a wire tfi such as a lead wire and a connector, and it has not been compacted-there are some problems, but in the example of In some cases, the above problem was solved by combining the drive circuit 215A and the control circuit 215B on the same printed S-line board 215. At the same time, the control circuit section 215B can be installed on the inner surface of the baffle plate 213b, which can reduce the dead space for use. .. If a double-sided printed wiring board is used as the printed wiring board 215, the degree of integration will be higher.
• the flexible S-board 215 is used as a flexible board, or the control circuit part of the flexible 82-wire board 215 is supported on the outer surface of the frame.
• the same effect can be obtained by wiring on the side of the drive circuit and the control circuit on the individual boards, using a flex-type connector.
• the magnet 214 may be installed inward of the end face 210 of the impeller. Furthermore, it is not necessary to say that the number of poles of the magnet 214 and the field windings 216a to 216d can be any number.
• the motor magnet 214 is disposed on the end face side of the impeller 201, but it is not limited to this.
• only the holding members 3 2 5 are fixed to the supporting slabs 30 8 that are axially supported by the supporting frame 3 0 ⁇ , and this holding S village 3 2 5 5.
• the motor and magnifying glass 3 2 4 are installed.
• the coil connecting hooks (not shown) of the same printed wiring board 3 2 6 arranged on the inner surface of the supporting frame 3 0 ⁇ as in the above-described embodiment are connected to the motors.
• ⁇ 3 d are connected in the S-position at equal intervals in the circumferential direction.
• Other configurations are the same as those in the above-mentioned embodiment. With such a configuration, the impeller 340 can be rotationally driven by the brushless motor method. In addition, 3 12 bearings are shown in the figure.
• the impeller is rotated by concealing the magnetic field line and the magnet, which substantially exhibits the motor function, between the impeller and the supporting frame.
• the S3 can be installed in the impeller or around the support shaft, and the field winding or the non-ferrous core can be used. Since the flat element is placed on the same printed wiring board together with the magnetic field detection element, it is possible to make it as thin as possible and to make it compact and light. The advantage is that the installation space is small and the electrical equipment can be designed to be extremely compact.
• the field winding for a motor is described as a coil having a non-ferrous core, but the coil having a ferrous core can be substituted. In most cases, it is best to keep the motor magnets in the condition of facing the iron core. (Example 3)
• the first 4 figures impeller and the motors that have a blanking La sheets between the support full record over arm @ 2 killing the embodiment. You are shown the ⁇
• the iron core 417 is fixed to the support shaft 40&, and the iron core 417 is fixed.
• the motor line 418 is attached to 417.
• the motor winding wire 18 is held on the supporting shaft 408 via the armature 4 i 7.
• the support shaft 408 is fitted outside the iron core 417, and the commutator 419 is fitted on the bearing 412 side, and the commutator (not shown) of the commutator 413 is mounted on the support shaft 408. It is connected to the motor winding 418, while the mounting base 420 is fixed to the inner side of the supporting frame 408, and these mounting bases 420 are fixed to the mounting base 420.
• the pair of brushes 421 and 422, which make contact with the commutator 419 and each of them at a symmetrical position g, are supported, and the brushes 421 and 422 are connected to each other. Is supplied with power from the power supply via a lead wire (not shown) connected through the support frame 406.
• a frame 23 made of a magnetic material in the form of a cylindrical cylinder held between the mounting base 420 and the mounting base 420 can be mounted.
• a ring-shaped motor magnet y 424, in which N poles and S poles are alternately arranged is fixed. ing .
• the frame 4.23 is the edge of the impeller end face 410. It is attached to the support frame 4 so as to be located on the inner peripheral side of the peripheral wall 410a formed on the hook, and thus dust can enter the gap. This is prevented.
• the frame 423 is desired to be a magnetic material in order to reduce the magnetic resistance, but it may be a non-magnetic material.
• the magnet 424 for the motor is not limited to the ring shape, and the fe magnet is held in a non-magnetic material for each N pole and S pole. The number of poles is the same as that of the motor winding and can be arbitrarily selected.
• the electric power is supplied from the source between the brushes 421 and 422.
• Figure 15 shows another embodiment in which a motor with a brush is arranged between the impeller and the supporting frame.
• a flat, iron-free motor winding 518 connected to a commutator 419 is attached to the end face 410 of the impeller 401.
• Other configurations are the same as those of the embodiment shown in FIG. 14 above, and corresponding components have the same reference numerals.
• the operation of rotating the impeller 401 is not the same as that shown in the above-mentioned third embodiment.
• Figures 16 to 19 show examples in which the control circuit of the brushless motor is arranged on one side of a suitable wind guide plate.
• the impeller 602 is rotatably supported by the supporting shaft, the bearing, and the supporting shaft of the brushless motor in the casing 603 as in the above-mentioned respective embodiments. It is housed in.
• This casing 603 is similar to the previous embodiment, as shown in Figs. 16 and 17 and has a substantially flat housing 803a and an impeller at the center. It consists of a baffle plate 603b and a pair of support frames (not shown) that are bent in a circular arc concentric with 602 and have a wide air intake on one side. In addition to forming an opening 603d for intake, an opening 603e for air exhaust is formed on the other side.
• the flexible substrate 607 is attached to the outside of the baffle plate S 03 b curved in the above-mentioned circular arc shape with an adhesive or the like.
• the casing 603 configured as described above, and for the main body chassis of electronic equipment such as a copying machine, an electromagnetic cooker, a personal computer, a copy machine, or a machine.
• the dead space 60 between the baffle plate 603b and chassis 604. 5 are formed.
• the data base ⁇ 0 5 is provided with the control circuit unit 6 05, which is composed of the electronic part & etc., in S3.
• This control circuit is a chip-type transistor 606b, resistor 606c, capacitor ⁇ 0 ⁇ 1, and diode 606e. It is composed of a half board attached to the surface 607a of the flexible substrate 607.
• the flexible board 607 is attached to the outside of the baffle plate 603b, and the electronic components 606b to 606e of the control circuit board 608 are attached to the flexible substrate 607.
• the flexible substrate 607 is implemented in the case where the flexible substrate 607 has a half-padded surface on the surface S07b.
• the flexible board 607 is attached to the outer surface of the wind guide plate 603 b, and the flexible board 6 (37) is equipped with the flexible board 6 (37).
• Installation of 60 & b to 60 ⁇ e As shown in the figure, the back of the 607 I), the electronic part of the control circuit ⁇ 0 ⁇ & the lead & 60 & b to ⁇ 06 e
• the flexible substrate 6 ( ⁇ is a semi-soldered part of the electronic component 60 ⁇ b to 6 (J ⁇ e is in contact with or close to the outer surface of the baffle plate & 03 b. It is also possible to attach it to the outer surface of the wind guide shaft S03b with an adhesive or the like.
• the control circuit is a 60S swordless item 606! ) ⁇ SOSe is in contact with or close to the wind guide 803b, so that the wind guide 6031) that was rejected by the wind from the impeller 60 2 Good product 606! ) ⁇ 606e is cooled, and damage to electronic parts due to thermal effects is effective, and the durability of the brushless cross-type fan unit is stopped. Moreover, there is an advantage that the reliability can be greatly improved.
• control circuit section 606 that controls energization of the brushless motor is energized, and this control circuit section is controlled.
• the control circuit section 60 S is separated from the brush motor and is installed on the dead space 605. The thermal effects on the electronic boards ifi 608b to 608e during driving are prevented, and the durability, reliability, and eventually the brass screen of the brushless motor are prevented. It is possible to improve the durability and reliability of flow-type cooling fan devices.
• Figures 20 to 23 show examples in which a plurality of impellers are connected in the axial direction and the air supply efficiency of the combined fuel efficiency is improved.
• the impeller 701 shown in Fig. 20 and Fig. 21. 1 is an integrally molded product made of synthetic resin, and it is surrounded by the central cavity 702 of the body.
• a peripheral wall is constructed, and an inclination angle of about 60 degrees is given to the peripheral wall in order to enhance the air supply efficiency of each blade 3 and the air supply slit 704.
• the group of impellers 703 is supported by the connecting ring 705 at one end, and by the end rod Akira 706 at the other end, and hence the impeller 701 at one end. It has a substantially cylindrical shape with an open mouth, and the connecting cage part 705 has its inner surface 705 a for the multi-connection of impellers and the outer surface of the end plate 70 &. If the diameter is set to be equal to that of 706a, it is connected to the inner peripheral surface 705a in an annular shape, or is intermittently connected to the invaders 707, and the other end is formed. Itaro 708b, which is connected to the outer peripheral surface 706b in an annular shape and is connected in a series, as shown in the figure, is formed. Of course, the formation of the indented part 707 and the raised part 70 ⁇ may be opposite S2.
• one of the blade plates 703 is provided with a positioning protrusion 70S shown in Fig. 2 from the Yasushi, and the end plate ⁇ 705 is engaged therewith.
• a large number of 710s are provided in the same radial position as the projections 7 and 3 in the circumferential direction.
• a circular hole 713 is formed for fitting the bearing material of the support shaft, which will be described later.
• the multiple connections of the impeller are made by pressing the end plate hooks 706 of the other impeller into the connecting ring 3 ⁇ 4 5 705 of one impeller and both Inferno 707 and raised bar 70 & are concave This is done by convex mating, and at this time, it is positioned within the connecting abutment 705 g.
• the projection 703 is inserted into one of the engaging holes 710, and the positioning is performed.
• the composition is such that the blade plates 703, 703 of the impeller that come into contact with each other in the eye contact, in other words, the air supply slits 704, 704 are not aligned in a straight line in the axial direction.
• the relationship shown by the broken line is such that the two impellers are positioned in such a way that they bite against each other and the connection of both impellers is regulated.
• the connecting ring part 7D5 of the endmost impeller is closed by the auxiliary end stub 714 as the stem material, as shown in Figs. 20 and 21. Therefore, similar to the auxiliary end plate 714 and the brace plate $70 ⁇ , the ridge 715 that is press-fitted into the recess 707 of the connecting part 705 and the engaging hole 716 that corresponds to the positioning protrusion 703. And of course, a circular hole 717 is opened in the center. Then, together with the mounting of the auxiliary plate 714, a bearing member (not shown) made of a rubber or the like was fitted in the circular hole 717 of the auxiliary end plate 714. After that, if these bearing parts are supported by a supporting shaft, a single-clamping-type cutting fan device will be constructed.
• the air-sucking sleeves 704 of the impellers that are in contact with each other as described above are arranged so as to be far from each other. Therefore, one of the impellers' air
• the cooling fan is assembled by connecting multiple units, and the connection between the impellers is due to the press fit between the ridge and the recess. It can be operated by a touch operation, it is extremely easy to design, it is self-centering by press fitting, and it is a highly accurate cooling pour. It can be mass-produced at low cost. In addition, it is easier to disassemble because it is easier to disassemble because it has better balance with the centering accuracy J:.
• the cross flow type cooling fan device As described above, the cross flow type cooling fan device, the audio amplifier, the micro computer, and the word process according to the present invention are provided. It is applicable to Uchiro cooling devices such as sensors, tube machines, electromagnetic cookers, etc., and in particular, it requires less space to install due to the recent miniaturization of electrical equipment. In most cases, it can be applied appropriately in the calculation of the compactness.
• a cross-flow cooling fan device provided within electric appliances which requires cooling, such as an audio amplifier, a microcoinputer, a word processor or a copier.
• a vane wheel (107) having air-blast slits around the periphery of a central hollow space of a cylindrical body thereof 1 supported rotatabiy at both ends thereof on support frames (109, 110) via wheel support shafts (111,112), Either of a rotary unit composed of the vane wheel (107) and its support shafts ( 111, 112), or a stationary unit consisting of the support frames (109, 110) is provided with a field magnet (121), and the other with an armature winding (124) opposing to the field magnet (121), to thereby form a vane wheel-driving unit.
• This makes it unnecessary to couple an additional motor to the axially-externai side of the vane wheel, and enables the cooling fan device to be miniaturized to a great extent.
• one of the rotation and the fixed frame is provided with a field magnet, a (121), and the other is provided with an armature. (124) is provided so as to be opposed to the electromagnetic field magnet (121) so as to constitute the rotary drive part of the impeller, and to assemble the motor of another product outside the root wheel in the wheel direction. It is a much smaller model without the need for it.
• the present invention includes, for example, audio amps, microcomputers, word ⁇ -cells, and: This is related to the cross-flow type cooling fan S, which is used to send the heat generated by the electrical parts etc. out of the air equipment. R.
• the impeller 1 used for this type of tallow flow type cooling fan device is mainly a synthetic resin molded product, as shown in Fig. 24, and the center of the barrel.
• An air supply slit 3 is formed around the cavity 2 by a group of vane plates 4, and the air sucked in from the radial direction of the impeller 1 as it rotates. It is possible to send the air in the radial direction to heat the ripening and maturation of the electrical components, and to send a wide range of flat exhaust air in the form of waste stream. Therefore, ⁇ is especially suitable for rejecting electrical components that are placed on the printed circuit board.
• the motor 8 used for the rotary drive of the impeller I can be installed continuously next to the impeller 1, it is a mechanical fan.
• the equipment installation space has increased, which has been a hindrance in the design of electrical equipment. Therefore, according to the present invention, a cross-flow type cutting fan device having a built-in motor which has a significantly reduced size and has a small installation space is provided. And are intended.
• the control circuit section of the brushless motor is provided with a special cooling device.
• the purpose is to provide a cross flow type cooling fan device g that can be efficiently rejected.
• this paper is designed to connect multiple impellers in the axial direction and to blow air through the air intake slits of adjacent impellers.
• the purpose is to provide a cross flow type cooling fan g with significantly improved efficiency.
• the impeller that forms the air-slitting slit around the central cavity is rotatably supported by the supporting frame at both ends of the impeller.
• the motor magnet On the other hand, on the other hand, the motor winding is opposed to the motor magnet, and the impeller is driven to rotate. It constitutes the assistant department.
• the motor which is a separate product from the conventional one, is used as the rotary driving means of the blade wheel, the motor is closely connected to the impeller. Substantially achieves the motor function between its supporting frames. ,
• the brushless motor when the motor built in between the impeller and the holding frame is configured as a brushless motor, the brushless motor is used. It is also possible to install the control circuit section of the motor on one side of the baffle plate, and to discontinue the control circuit section by using the cool air from the impeller. In this way, it is economical because it is not necessary to install the dismantling equipment S for the special control circuit section.
• a plurality of impellers may be connected in the axial direction, and the air supply slits of the adjacent impellers may be configured so as to eat each other. In this way, the air blown from the adjoining impellers does not generate a time shift, and thus does not interfere with the air flow, thus improving the air flow efficiency.
• Figures 1 to 4 show a configuration in which a motor is built in between the end face frame and the impeller, and that motor is the brush motor.
• a motor is built in between the end face frame and the impeller, and that motor is the brush motor.
• Fig. 1 is a plan view
• Fig. 2 is a sectional front view
• Fig. 3 is a longitudinal side view
• Fig. 4 is a sectional view showing a modification example of the main part.
• Figure 5 to Figure 12 show other implementations of brushless motors.
• Fig. 5 is a schematic vertical front view
• Fig. 6 is a schematic plan view
• Fig. 7 is a partially cutaway plan view of Yoro
• Fig. 8 is a side view
• Fig. 9 is a magnetic field.
• FIG. 10 Fig. 10 Side view showing the wiring pattern of the printed wiring board Fig. 11 Fig. 11 Electrical circuit diagram of the control circuit Fig. 12 Fig. 12 Fig. 12 Another modification of Ichiro's front view It is a figure.
• Figure 13 is a cross-sectional view showing the essential parts of another embodiment of the brushless motor.
• Figure 14 shows the case where the motor is built in between the end face frame and the impeller, but the motor is used with a brush. Is a cross-sectional view of the key.
• Fig. 15 is a key cross-sectional view showing another embodiment in the case of a motor configuration with a brush.
• Figures 16 to 19 show an example of the arrangement of the control circuit of the brushless motor.
• Figure 16 shows the brushless mouth switch ⁇ .
• a plan view showing the central part of the mold cooling fan equipment, a cross-sectional view along the line XIIV—XIIV in Fig. 17 and Fig. 16 and Fig. 18 and Fig. 19 are, respectively.
• Each is a longitudinal sectional view of another modification.
• Figures 20 to 23 show an example in which multiple impellers are connected and the air feed slits of adjacent impellers are different: E.
• Fig. 20 shows the appearance of the impeller.
• Fig. 21 shows the appearance of the impeller from the opposite direction to Fig. 20.
• Fig. 20 shows the appearance of the impeller.
• Book cooling Fig. 23 is a sectional view of the main part of the fan, and Fig. 23 is a sectional view of the impeller.
• Fig. 24 is a perspective view showing the combined use of a conventional impeller and motor.
• Figures 1 to 4 show an embodiment in which a brushless motor is installed between the impeller and the support frame as the rotary drive means for the vane wheel.
• the impeller 107 is supported on both sides by its supporting shafts 11 and 112 on the holding frames 103 and 110, and is freely rotatable.
• Each support shaft U1.112 is fixed to the end plates 113 and 114 at the end of the vane vehicle, and is supported by the support frames 109 and 110 and the bearings 115 and 116, respectively. It is. 117, 118 It is a bearing case.
• the required gap 119 was placed between one end of the impeller 107 and the corresponding support frame 110, and the end plate was fixed to the end plate hook 114 in the slag 119.
• Ku 120 is placed. It is fixed by press-fitting the pin protrusion 120a protruding from the yoke 120 side to the hole that is recessed on the end plate portion 114 side of the yoke 120. Inside the yoke, the ring magnet 121 is mounted by an adhesive or the like so as to be coaxial with the support shaft 112.
• the outer shaft 122 is fitted on the outer shaft 122, and the outer shaft is fixed on the support frame 110 while it is fitted on the bearing case 118. .
• the iron core 123 loosely coaxially fitted in the ring magnet 121 is attached to the mantle U 2, and the field winding 124 is attached to the iron core 123. It is.
• the hall element 125 is attached to a part of the iron core 123. The hall element 125 detects the rotating ring. Magnet 121 magnetic field and controls the energization of the field winding 124.
• the magnetic field corresponding to the ring magnet 121a is attached. It is also possible to change the shape of the iron core i 23a' so as to produce It is also possible to change the position of the ring magnet 121 shown in Fig. 2 to the outer girder 122 side, and the iron core 123 to the impeller 107 side.
• a slip ring is used to power the rotating winding 124.
• the motor which is a conventional Makoto product, is used as the rotary driver of the impeller to connect the impeller to the impeller.
• a ring magne- cial that substantially functions as a motor between the impeller and its end face frame.
• V-wheel, the iron core, and the field winding are ESed so that the impeller can be rotated, and the cross-flow type cutting fan e has been downsized. , With little g space Therefore, it becomes possible to design the compactness of electrical equipment.
• FIGS 5 to 12 show another embodiment in which the brushless motor is forked between the impeller and the support frame.
• a recess 21 Oa is formed on the end face 210 of the impeller, and a flat ring-shaped magnet 214 is pressed into the recess 210a.
• the vane plates 204 are formed on the outer peripheral surface of the magnet 21 4 and are fixed, and the magnet 2 H is attached to the inside of the impeller 2.
• the outer circumference of the magnet 214 is the small diameter surface 214 a, it can be easily press-fitted, and the elasticity of the impeller wheel surface 210 made of synthetic resin is flat. Magnet 214 is not damaged.
• a print S3 wire substrate 215 is arranged on the inner surface of the support frame 206 so as to face the magnet 214.
• This printed wiring board 215 has the wiring pattern of the drive circuit as shown in Fig. 10 printed on Kimura Murakami, which is made of a silicon trowel plate.
• the coil connection parts 215a to U5d of the field winding are formed in four places, and the halls for magnetic field detection are provided in two places.
• Element connection rings 215 e and 215 f are formed.
• each coil connection tab 215a to 215d of the printed wiring board '215 has a non-ferrous, substantially triangular field winding 216a.
• ⁇ 216 d are connected to the fi fi, and each hall element connection block 215 e, 215 , F are Hall elements U7a, 217b are IS connected. or
• the printed wiring board 215, the drive circuit 215A, and the control circuit 215B are bent and extended.
• the magnet 214 and the S pole and the N pole in the arrangement shown in Fig. 9 have a total of 6 poles with 3 poles facing each other. There is.
• a substantially flat housing 218a, a rear baffle 218b that is concentric with the impeller 2IH, and a bottom baffle 218b, and a pair of It is composed of a support frame 218c, a wide air intake port 2i8d is formed on the upper side, and an air exhaust port 218e is formed on one side.
• the control circuit 215B of the above-mentioned blank K-line board 215 is provided with SS on the inner surface of the baffle plate 218b.
• the circuit shown in Fig. 11 is equipped with two Hall elements 217a and 217b for magnetic field detection, but two are shown in Fig. 11. Only use the circuit.
• the Hall element 217a for magnetic field detection detects the north pole of the magnet 214
• the Hall element 217a detects the first pole of the PNP type first transistor.
• Q1 is turned on, and the second to fourth transistors Q2 to! 14 is turned on from the power supply + B, and the current is applied in the direction of arrow N to the field windings 2a and 216c through the third and fourth transistors Q3 and Q4.
• Flow and the magnetic field of the N pole is induced in each field winding 216a, 216c
• the pole element 217a of the PNP type transistor 5 by the hall element 217a is detected. (3 ⁇ 4 is turned on, and 6th to 8th transistors Q6 to Q8 are turned on, respectively, from the source + B to the 7th and 8th transistors.
• a magnetic field of the S pole is induced in the field windings U6a, 216c in the direction of the arrow S through the transistors Q7, Q8, and in the field windings 216a, 218c.
• the mutual attraction and repulsion force the magnet 214 to rotate the wing wheel 201. This rotation causes the hall element 2 17b to move the magnet 214 to the magnet 214.
• the transistor Q1 of the brush 1 When N 3 ⁇ 4 is detected, the transistor Q1 of the brush 1 is turned on, and accordingly, the second to fourth transistors (12 to! ⁇ 4) are respectively turned on.
• the current flows through the field winding 216 b .2 i 6 d in the direction of the arrow N through the third and the fourth transistor Q3 ,(H A magnetic field of the N pole is induced in the lines 216 b and 215 d to generate mutual attractive force and repulsive force, and the magnet and y-t 214 are further rotated.
• the frequency of the impeller 201 is controlled in this case.
• each of the field windings 218a to 216d is connected to the control wiring of the magnet. It is performed by the control circuit section 2158 of 215.
• the magnet 214 and the field windings 218a to 216d have more practical motor functions, they are used as a driving means for the impeller 201.
• No separate brush motor is required, and the flat and ironless magnetic field windings 21 B a to 216 d and flat magnet 214 and The brushless motor is composed of the printed wiring board 215 and the wiring board 215, and it is installed in the magnet 214 or the impeller 201.
• the field windings 2 i 6 a to 216 d are arranged on the printed S3 wire board 215, it is possible to use a sheet coil, and the field windings can be used.
• 21 fi a to 21 ⁇ (1 and hall elements 217a and 217b can be installed in the same driving circuit 215A of the printed K-line board 215A.
• the drive circuit 215A and the control circuit 215B are individually provided, a complicated work such as attaching a half pad to connect them to each other is required, and the In this example, there are problems such as the need for parts such as cables and connectors, and the lack of compaction.
• the problem is solved by installing the drive circuit board 2 ⁇ 5 ⁇ and the control circuit board 215 B on the same single S-line board 215 in one body.
• the control circuit 215B on the inner surface of the baffle plate 213b by E', it is possible to reduce the dead space for use. R.
• a double-sided printed K-line board is used as the printed S-line board 215, the degree of collecting edge becomes higher.
• the flexible S-board 215 is used as a flexible substrate, or the control circuit part 215B of the clean K-line board 215 is supported by the frame.
• the same effect can be obtained even if S2 is installed on the outer surface side of the board, and the drive circuit and control circuit that are installed on the individual boards are wired with a bent connector.
• mag- nets 4 may be installed inside the end face 210 of the impeller. Further, the number of poles and the field winding 216 a ⁇ 218 d of Ma grayed nets 214 not name even while cormorants saying ho as a child that Ki out to any number of ⁇
• the motor magnet 214 is arranged on the side of the impeller 201 on the side of the salient surface, it has been clarified that this is not the only case.
• the Toe 324 is worn.
• a coil connecting wire (not shown) is provided on each inner surface of the supporting frame 306 and on each coil connecting board (not shown) of the same printed circuit board 326 as in the previous embodiment.
• Magnetic windings 318a to 31&d are connected to the S2S at equal intervals in the circumferential direction.
• Other configurations are the same as those in the above-described embodiment. ⁇ Even with such a configuration, the impeller 304 can be rotationally driven by the brushless motor method. R. Note that there are 312 bearings in the figure.
• the FFig of the magnet and field winding which actually exhibits the motor function between the impeller and the holding frame, is used to rotate the impeller.
• the magnet since the magnet is a thin one, it can be installed in the impeller and around the support shaft, and the field winding
• the flat and flat element is placed on the same printed wiring board together with the magnetic field detection element, so it is as thin as possible and is compact and lightweight. This has the advantage that it can be designed to a much greater extent for electrical equipment with a smaller installation space and a smaller installation space.
• the field winding for motor is used as a coil having a non-ferrous core, but the coil having a ferrous core can be used as a substitute. In most cases, it is best to keep the motor magnet facing the iron core. ⁇
• Fig. 14 shows an embodiment in which a motor with a brush is installed between the blade wand and the supporting frame, gg.
• the armature 417 is fixed to the support shaft 40&, and the motor wire is attached to the iron core 417.
• the motor winding wire 418 is held on the support shaft 408 through the iron core 417.
• the support shaft 408 is fitted outside the iron core 417, and the commutator 419 is fitted on the bearing 412 side, and the commutator (not shown) of the commutator 419 is mounted on the support shaft 408. It is connected to the motor winding 418.
• the mounting base 420 is fixed to the inner peripheral side of the support frame 406, and the commutator and the commutator are connected to the mounting base 420, respectively.
• a pair of brushes 421 and 422 that make contact with each other at nominal positions are supported. These brushes 421 and 422 are not supplied with power from a power source via a lead wire (not shown) connected through a supporting frame 40K. It is.
• a frame 423 made of a cylindrical magnetic material held between the mounting frame 420 and the attachment 420 is attached.
• a ring-shaped motor magnet 424 in which the north pole and the south pole are alternately arranged is fixed to the position fi facing the iron core 417.
• the frame 4.23 is the edge of the impeller end face 410. It is attached to the holding frame 406 so as to face the inner peripheral side of the peripheral wall 4a formed on the outer wall 4a, and because of this, dust is present in the gap 416. It is prevented from entering.
• the frame 423 may be a non-magnetic material which is desired to be a magnetic material in order to reduce the magnetic resistance.
• the motor magnet 424 is not limited to the ring shape, and the magnet divided into the N pole and the S pole is held in a non-magnetic material. However, like the motor winding, the number of poles can be arbitrarily selected.
• the electric power is supplied from the power source between the brushes 421 and 422 to the motor field.
• the impeller 401 is rotated.
• Figure 15 shows another embodiment in which a motor having a brush is arranged between the impeller and the supporting frame.
• FIG. 15 shows that the flat, ironless motor winding 518 connected to the commutator 419 is attached to the end face 410 of the impeller 401.
• the motor winding 518 is held on the impeller end face 410.
• Other configurations are similar to those of the embodiment shown in FIG. 14 above, and corresponding components are designated by the same reference numerals.
• the operation of rotating the impeller 401 is not the same as that shown in the above-mentioned third embodiment.
• Figures 16 to 19 show examples in which the control circuit of the brushless motor is arranged on one side of a suitable wind guide plate.
• the impeller 602 is rotatably mounted on the supporting shaft, the bearing, and the supporting shaft of the brushless motor in the same manner as in the case of the above embodiments. It is housed in 603.
• This casing 603 is similar to the above-mentioned embodiment, as shown in Figs. 16 and 17 and has a substantially flat housing 603a and a blade at the center. It is composed of a wind guide plate 603b, which is concentric with the car 602, and is curved in a circular arc, and a pair of support frames (not shown), and has a wide air intake on one side.
• an opening 603e for the air discharge nozzle is formed on the other side.
• a flexible substrate 607 is attached to the outside of the air guide 803b curved in the arc shape with an adhesive or the like.
• the control circuit section 606 composed of electronic components and the like is arranged in this device space ⁇ -6.
• the control circuit unit 606 includes a chip-shaped transistor 606b, a resistor 60Bc, a capacitor 606d, a diode 606e, etc. as described above. It consists of soldering on the surface 607a of the board 607.
• the flexible board 607 is attached to the outside of the baffle plate 603 b and the flexible board 6 (electronic circuit ⁇ 06! of the control circuit section 606 for ⁇ ) ⁇ .
• first attach the porcelain sheet 608 (for example, resin sheet) to the outer surface of the baffle plate 603b
• An adhesive sheet 608 is attached to the insulating sheet 608, and a flexible board 607 is attached to the back surface 607b of the control circuit board 606, which is an electronic part of the control circuit board 606, which has a lead wire of ⁇ £ ⁇ 0 S b to 606 e.
• It may be attached by a fixing means such as.
• the flexible substrate 607 is implemented at the same time as the type of the flexible substrate 607 attached to the back side S07b of the flexible substrate 607. ..
• the flexible board 607 is attached to the outer surface of the air guide plate 603b, and the electronic circuit part 606 of the control circuit 606 is attached to the flexible board 607! ) To 606e, and as shown in Fig. 19 the flexures 607b are soldered to the heel part 607b with the electronic parts ta 606b to 806e of the control circuit part 60S.
• the gibble board 607 is attached to the outer surface of the air guide plate 603b with an adhesive so that the electronic components 606b to 606e come into contact with or approach the outer surface of the air guide plate &03b. You can also eat sea urchin. like this ,
• the electronic components 606! To 608e contact or approach the wind guide plate 603b, the wind guide plate 603b dismissed by the wind from the impeller 60 2 causes the electronic lead frame 603b to be closed.
• the products 606b to 606e are cooled, and damage to the core parts due to thermal effects is effectively prevented, and the durability of the brass cross-flow type cutting fan device fi is improved. It has the advantage that it can significantly improve the reliability and reliability.
• control circuit section 6 Q6 that controls the energization of the brushless motor
• control circuit section 606 from the control circuit section 606.
• the motor drive section is energized and the motor is driven to rotate
• the impeller 602 accommodated inside the casing ⁇ 03 rotates and the wide range of the casing 603 expands. It is possible to inhale air from the opening 6Q3d and expel air from the narrow opening 6Q3e.
• the control circuit section 606 is installed on the V space 605, separated from the brushless motor, and the brushless motor is driven.
• the thermal effects on the electronic SP 6 (Ub to 6()6e) are prevented, and the durability, reliability, and eventually the brushlessness of the brush motor are prevented.
• the durability and reliability of the loss-flow type cooling fan g can be improved.
• Figures 20 to 23 show an example that improves the air supply efficiency in a combined case where multiple impellers are connected in the axial direction at multiple speeds.
• the blade 20Q and the blade wheel 7Q1 shown in Fig. 21 are an integrally molded product made of synthetic resin, and the circumference of the center cavity 702 is approximately 70%.
• a peripheral wall is constructed, and an inclination angle of about 60 degrees is given to the peripheral wall to increase the air supply efficiency of each blade 3 and the air supply slit 704.
• the above-mentioned group of blades 703 is supported at one end by a connecting airo 705, supported at the other end by an end platerou 706, and thus at the end of the impeller 7G1. It has a substantially cylindrical shape with a mouth, and the connecting stub 705 and the inner surface 705a of the end plate are the same as the outer surface 706a of the end plate 706 for connecting multiple impellers.
• the inner diameter 705a is annularly connected to the inner peripheral surface 705a, but is also intermittently connected to the outer peripheral surface 706b.
• the ridges 708 are formed that are continuous in the shape of a dent and are continuous in an intermittent manner as shown in the figure. Of course, the formation of the invagination 707 and the formation of Takaro 708 may have the opposite distribution g.
• one of the blades 703 is provided with a shank 2 1 as shown in FIG.
• a plurality of 710 are installed in the same radial position as the protrusion 7 and 3 in the circumferential direction.
• a circular hole 713 is formed in the center of the end plate portion 706 for fitting the bearing shaft metal of the holding shaft, which will be described later.
• the multiple connections of the impellers are as shown in Fig. 22, as shown in Fig. 22. 707 and raised bar 70S are concave This is done in a convex mating manner, and at this time, the positioning protrusion 709 is inserted into any one of the engaging holes 710 by the connecting rod 705.
• This position g determination configuration is such that the blade plates 703, 703 of adjacent impellers, in other words, the air-sending thresholds 704, 704 are not aligned linearly in the axial direction, and the second It regulates the connection of both impellers so that they are positioned so that they do not bite against each other as shown in the solid line and broken line in the figure.
• both impellers are doubled in the axial direction and doubled in size, and when they are tripled in size, three impellers are connected in succession. It is possible to obtain an impeller with the required dimensions.
• the connecting ring part 705 of the endmost impeller is closed by the auxiliary end bark as the stem member, as shown in Fig. 20 and Fig. 21. Therefore, similarly to the auxiliary end plate 7U and the end plate, the ridge 715 that is press-fitted into the indentation 707 of the connecting node 705 and the engaging hole 716 that corresponds to the positioning projection 703 are provided. In addition to the existing ones, a circular hole 717 is also opened in the center. Then, together with the mounting of the auxiliary pant plate 714, a glazed member (not shown) made of a rubber or the like is fitted into the circular hole 717 of the auxiliary end plate 714. After that, if these bearing members are supported by the support shaft, a cross-type cooling fan device will be constructed.
• the air feed slits 7Q4 of the adjacent impellers were arranged in a mutually staggered manner as described above. Therefore, one of the impellers The air sent from Sat 7 Q 4 and the air sent from the other impeller 70 0 4 cause a time lag and therefore no interference. Yes.
• the cooling fan is assembled by connecting multiple impellers, it is clear that the connection between the impellers is due to the press fit between the ridge and the invader. It can be operated by a touch operation, the workability is extremely high, it is convenient, and the centering is not self-helping by press fitting, and a highly accurate cooling fan is provided. Inexpensive: Can be produced in ft. In addition, the improved centering accuracy improves the balance during rotation, and is easy to disassemble, which is also advantageous for maintenance.
• the positioning positional relationship between the two impellers is automatically regulated only by the mutual engagement of the positioning projection and the engaging hole.
• the labor required for the work can be omitted, and at the same time, it is possible to prevent the drought of the eyebrow that is blown from each impeller and to eliminate the pulsation.
• the cross flow type cooling fan device e is an audio amplifier, a micro computer unit and a word processor. It is useful as a ⁇ cooling device such as a compressor, copy machine, electromagnetic cooker, etc., and it is especially suitable for smaller electrical equipment as it is recently installed. In a few occasions, it may be suitable for the design of the compact.

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• Engineering & Computer Science (AREA)
• Mechanical Engineering (AREA)
• General Engineering & Computer Science (AREA)
• Power Engineering (AREA)
• Structures Of Non-Positive Displacement Pumps (AREA)
• Connection Of Motors, Electrical Generators, Mechanical Devices, And The Like (AREA)
• Brushless Motors (AREA)
• Motor Or Generator Cooling System (AREA)

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• 1985
  • 1985-11-11 JP JP1985173697U patent/JPS6281475U/ja active Pending
• 1986
  • 1986-10-01 WO PCT/JP1986/000503 patent/WO1987003149A1/ja active IP Right Grant
  • 1986-10-01 US US07/057,894 patent/US4859888A/en not_active Expired - Fee Related
  • 1986-10-01 DE DE8686905926T patent/DE3684141D1/de not_active Expired - Lifetime
  • 1986-10-01 WO PCT/JP1986/000504 patent/WO1987003049A1/ja active IP Right Grant
  • 1986-10-01 EP EP86905926A patent/EP0244487B2/en not_active Expired - Lifetime
  • 1986-10-01 DE DE8686905927T patent/DE3682279D1/de not_active Expired - Lifetime
  • 1986-10-01 EP EP86905927A patent/EP0246325B1/en not_active Expired - Lifetime
  • 1986-10-01 KR KR1019870700599A patent/KR900007105B1/ko not_active Expired

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