JP7008654B2 - Fan - Google Patents

Description

The present invention relates to a counter-rotating fan.

Conventionally, a compact counter-rotating fan has been proposed. For example, Patent Document 1 discloses a counter-rotating electric fan including a first impeller on the upstream side and a second impeller on the downstream side. The first impeller is rotationally driven by a motor, and the second impeller is rotatably provided on the rotating shaft. When the first impeller is rotated, the second impeller is rotated in the direction opposite to the rotation direction of the first impeller by the wind power of the first impeller.

Japanese Patent No. 6436923

However, in the conrotating electric fan disclosed in Patent Document 1, the first impeller and the second impeller are rotationally driven by one motor, and a sufficient flow rate as the electric fan may not be obtained. On the other hand, there is also a method of providing two motors and driving the first impeller and the second impeller individually to obtain the flow rate, but it is also assumed that the entire fan will be large, and the structure for downsizing the fan is structural. Ingenuity is required. Furthermore, if the housing of the fan is made smaller and the distance between the first impeller and the second impeller is narrowed, the housing will bend during use when assuming a handheld contra-rotating fan, and the first It is also assumed that the impeller and the second impeller collide with each other. Therefore, measures to prevent collisions between impellers are also desired.

In view of the above points, it is an object of the present invention to provide a small fan having a large air volume.

The electric fan of the present invention includes a first impeller, a second impeller that is arranged so that the center of the rotation axis is aligned with the first impeller and rotates in the opposite direction to the first impeller, and the second impeller on the second impeller side. A grill provided with a gap and inclined toward the first impeller side from the center side of the rotation axis of the second impeller toward the outside in the radial direction is provided, and the grill side of the blade in the second impeller is provided. The edge is inclined toward the first impeller side from the center side of the rotation axis toward the radially outward side, the first impeller has the first hub, and the second impeller is the first impeller. It is characterized by having a second hub provided with a boss protruding toward the hub side .

According to the present invention, it is possible to provide a small fan having a large air volume.

It is a perspective view of the electric fan and the stand which concerns on embodiment of this invention. It is an exploded perspective view seen from the front side of the electric fan and the stand which concerns on embodiment of this invention. It is an exploded perspective view seen from the back side of the electric fan and the stand which concerns on embodiment of this invention. It is a perspective view which looked at the 1st case of the electric fan which concerns on embodiment of this invention from the inside. It is a perspective view which looked at the 2nd case of the electric fan which concerns on embodiment of this invention from the inside. It is an enlarged view around the blower head in the VI-VI cross section of the electric fan of FIG. 1 which concerns on embodiment of this invention. It is an exploded perspective view seen from the front side of the mooring member which concerns on embodiment of this invention. It is an exploded perspective view seen from the back side of the mooring member which concerns on embodiment of this invention. It is an enlarged view around the gate in the IX-IX cross section of the mooring member of FIG. 1 which concerns on embodiment of this invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a perspective view of an electric fan 1 supported by a stand 4. The electric fan 1 of the present embodiment is formed as a small portable tool. The fan 1 has a grip portion 11 and a blower head 12. Further, the fan 1 has a carabiner portion 91 connected to the grip portion 11. The fan 1 can rotate the impellers 5 and 6 in the blower head 12 to generate wind by gripping the fan 1 with the grip portion 11 and pressing the switch SW. Further, the electric fan 1 can be supported in an inverted state by inserting the carabiner portion 91 into the groove portion 421 of the stand 4.

The details of the electric fan 1 and the stand 4 will be described. FIG. 2 is an exploded perspective view of the fan 1 and the stand 4 as viewed from the front side, and FIG. 3 is an exploded perspective view of the fan 1 and the stand 4 as viewed from the rear side. 4 and 5 are perspective views of the first case 2 and the second case 3 as viewed from the inside, respectively, and FIG. 6 shows the periphery of the blower head 12 in the VI-VI cross section of the fan 1 shown in FIG. It is an enlarged view. In the following description, the second case 3 side, which is the downstream side of the flow path, is referred to as the front, and the opposite side is referred to as the rear.

The fan 1 includes a first case 2 provided on the upstream side of the flow path and a second case 3 provided on the downstream side. The first case 2 and the second case 3 include a first impeller 5, a second impeller 6, motors 71 and 72, a circuit board 82, a battery 83, and a mooring member 9 inside.

As shown in FIGS. 2 to 5, the first case 2 and the second case 3 have a substantially circular shape connected to the accommodating portions 21 and 31 accommodating the circuit board 82 and the battery 83 and the upper ends of the accommodating portions 21 and 31. It has the impeller cover portions 22 and 32 of the above. The mooring member 9 is accommodated on the lower end side of the accommodating portions 21 and 31. The mooring member 9 is fixed to the accommodating portion 31 side by fixing members 312 such as a plurality of screws. A part of the mooring member 9 protrudes from the lower ends of the accommodating portions 21 and 31 via the notches 213 and 313, and a carabiner portion 91 capable of mooring and supporting the moored object is formed in the fan 1.

A plurality of engaging claws 20a are formed on the opening-side edge of the accommodating portion 21 shown in FIG. 4, and a plurality of engaged holes 20b are formed on the opening-side edge of the impeller cover portion 22. Further, a plurality of engaged holes 30a are formed on the opening-side edge of the accommodating portion 31 shown in FIG. 5, and a plurality of engaging claws 30b are formed on the opening-side edge of the impeller cover portion 32. .. In the housing of the fan 1 according to the first case 2 and the second case 3, the engaging claw 20a and the engaged hole 30a are engaged with each other, and the engaged hole 20b and the engaging claw 30b are engaged with each other. Can be formed with.

In FIG. 4, the impeller cover portion 22 is formed in a substantially short cylindrical shape with a bottom on the upstream side in the flow path direction. The impeller cover portion 22 is provided with grills 221 and 222. The grill 221 is formed on substantially the entire bottomed portion of the impeller cover portion 22. The grill 221 is formed so as to be substantially orthogonal to the rotation axis P direction of the first impeller 5 and the second impeller 6. Further, the grill 222 is arranged in an annular shape on the outer peripheral side of the grill 221 corresponding to the cylindrical side surface of the impeller cover portion 22.

On the center side of the grill 221 is a substantially circular motor accommodating portion 23 having an annular peripheral wall. In the center of the motor accommodating portion 23, a cylindrical bearing 231 is erected on the front side. The inside of the bearing 231 penetrates back and forth. The outside of the impeller cover portion 22 on one end side of the bearing 231 is closed by the disk-shaped cover 24 (see also FIG. 6).

Long rod-shaped frames 221a and 222a extending radially outward from the motor accommodating portion 23 are formed on the grills 221 and 222. Further, the grill 221 is formed with a guide frame 221b extending below the motor accommodating portion 23. The guide frame 221b is formed in the shape of a long rod like the frame body 221a. A top plate portion 211 is formed between the accommodating portion 21 and the impeller cover portion 22. The guide frame 221b is provided over the motor accommodating portion 23 and the top plate portion 211. A groove portion 221c is formed inside the guide frame 221b, and a wiring cable 811 connecting the motor 71 and the circuit board 82 is housed in the groove portion 221c (see also FIG. 6). In FIG. 6, the connection portion directly connecting the wiring cable 811 (812) and the circuit board 82 or the motor 71 (72) is not shown.

An engaging portion 232 for supporting the wiring cable 811 is formed at the connecting portion between the motor accommodating portion 23 and the guide frame 221b. The engaging portion 232 is formed with a protrusion 232a that stands upward from the upper end of the groove portion 221c. The protrusions 232a are provided on both the left and right sides of the groove 221c.

Further, a substantially rectangular cutout portion 221d is formed in a part of the wall portion forming the groove portion 221c. The top plate portion 211 is formed with a notch portion 211a extending forward from the lower end of the groove portion 221c. Further, the top plate portion 211 is formed with stepped portions 211b at both front ends of the cutout portion 211a, and the stepped portion 211b is formed with engaging projections 211c protruding forward.

Similarly, on the second case 3 side, in FIG. 5, the impeller cover portion 32 is also formed in a substantially short cylindrical shape with the downstream side in the flow path direction having a bottom. The impeller cover portion 32 is provided with a grill 321 formed on substantially the entire bottomed portion of the impeller cover portion 32. The grill 321 is formed so as to face the grill 221 so as to be substantially orthogonal to the rotation axis P direction (see also FIG. 6). A substantially circular motor accommodating portion 33 having an annular peripheral wall is arranged on the substantially central side of the grill 321. In the center of the motor accommodating portion 33, a cylindrical bearing 231 is erected on the rear side. The inside of the bearing 331 penetrates back and forth. The outside of the impeller cover portion 32, which is one end side of the bearing 331, is closed by the disk-shaped cover 34 (see also FIG. 6).

The grill 321 is formed with a long rod-shaped frame 321a extending radially outward from the motor accommodating portion 33. Further, the grill 321 is formed with a guide frame 321b extending below the motor accommodating portion 33. The guide frame 321b is formed in the shape of a long rod like the frame body 321a. A top plate portion 311 is formed between the accommodating portion 31 and the impeller cover portion 32. The guide frame 321b is provided over the motor accommodating portion 33 and the top plate portion 311. A groove portion 321c is formed inside the guide frame 321b, and a wiring cable 812 connecting the motor 72 and the circuit board 82 is housed in the groove portion 321c (see also FIG. 6).

Also on the second case 3 side, an engaging portion 332 that supports the wiring cable 812 is formed at the connecting portion between the motor accommodating portion 33 and the guide frame 321b. The engaging portion 332 is formed with a protrusion 332a that stands upright from the front at the upper end of the groove portion 321c. Further, the top plate portion 311 shown in FIG. 3 is also formed with a notch portion 311a extending rearward from the lower end of the groove portion 321c. Similar to the top plate portion 211, the top plate portion 311 is formed with stepped portions 311b at both rear ends of the cutout portion 311a, and the stepped portion 311b is formed with engaging protrusions 311c protruding rearward.

The wiring cable 811 and the wiring cable 812 are formed in substantially the same shape and are arranged so as to face each other. As shown in FIGS. 2 and 3, the wiring cables 811 and 812 are formed in a vertically long shape, and the T-shaped jack portions 811a and 812a formed on one end side of the motors 71 and 72 are formed. And a T-shaped plate-shaped engaging portion 811b, 812b formed on the other end side. Engagement holes 811c and 812c penetrating back and forth are formed on the left and right end sides of the engaging portions 811b and 812b. Further, widening portions 811d and 812d widened in a rectangular shape to the left and right are formed between the jack portions 811a and 812a of the wiring cables 811 and 812 and the engaging portions 811b and 812b.

The left and right ends of the T-shaped jack portion 811a are engaged and supported by the protrusions 232a in the engaging portion 232. Further, the engaging portion 811b can be accommodated and supported in the step portion 211b by inserting the engaging projection 211c into the engaging hole 811c. Also on the second case 3 side, the left and right ends of the jack portion 812a are engaged and supported by the protrusions 332a of the engaging portion 332. The engaging portion 812b can be accommodated and supported in the stepped portion 311b by inserting the engaging projection 311c into the engaging hole 812c.

The motors 71 and 72 are formed in a substantially short columnar shape as a whole, and drive power is supplied from the circuit board 82 via the wiring cables 811 and 812. The motor 71 is housed in the motor housing unit 23, and the motor 72 is housed in the motor housing unit 33.

The first impeller 5 has a bottomed cylindrical first hub 51 and a plurality of first blades 52 radially provided from the outer peripheral wall of the first hub 51. The first hub 51 has a circular flat plate-shaped bottom portion 511 on the front side. As shown in FIG. 3, a cylindrical bearing portion 511a projecting rearward is formed inside the first hub 51. As shown in FIG. 6, the motor 71 is housed in the first hub 51, and the rotating shaft 711 of the motor 71 is fixed to the bearing portion 511a.

Further, in the present embodiment, five first blades 52 are formed on the first impeller 5. The first blade 52 can rotate counterclockwise when viewed from the front and blow air from the rear to the front of the fan 1. The first blade 52 is formed so that the front end edge 521 is located slightly behind the bottom portion 511, as shown in the VI-VI cross-sectional view of FIG. The trailing edge 522 of the first blade 52 is formed so as to be located slightly in front of the trailing edge 512 of the first hub 51. Further, the front end edge 521 and the rear end edge 522 are formed on a substantially orthogonal plane of the rotation axis P so as to be substantially parallel to each other. The first impeller 5 is formed so that the gap between the trailing end edge 522 of the first impeller 5 and the grill 221 is substantially parallel to the outer diameter edge side of the grill 221. Can be increased. Therefore, the flow rate of the air taken in by the first impeller 5 and sent forward can be increased.

The second impeller 6 has a bottomed cylindrical second hub 61 and a plurality of second blades 62 radially provided from the outer peripheral wall of the second hub 61. The second hub 61 has a circular flat plate-shaped bottom portion 611 on the rear side. As shown in FIG. 2, a cylindrical bearing portion 611a projecting forward is formed inside the second hub 61. As shown in FIG. 6, the motor 72 is housed in the second hub 61, and the rotating shaft 721 of the motor 72 is fixed to the bearing portion 611a.

Further, in the present embodiment, seven second blades 62 are formed on the second impeller 6. The second blade 62 can rotate clockwise in the front view to blow air from the rear to the front of the fan 1. The front end edge 621 of the second blade 62 is gently curved and inclined toward the first impeller 5 side radially outward from the second hub 61 side, which is the rotation axis P side. The front end edge 621 on the base end side of the second blade 62 is connected to the front end edge 612 of the second hub 61 (see also FIG. 2). The trailing edge 622 of the second blade 62 is connected to the second hub 61 slightly forward of the bottom 611 of the second hub 61. The trailing edge 622 is gently inclined toward the first impeller 5 side radially outward from the second hub 61 side. Therefore, in the side view of FIG. 6, the gap between the rear end edge 622 of the second blade 62 and the front end edge 521 of the first blade 52 increases from the rotation axis P side toward the radial outer side of the impellers 5 and 6. It is formed so as to gradually narrow. Further, the front end edge 621 of the second blade 62 on the grill 321 side is formed so that the gap between the grill 321 and the second impeller 6 is substantially parallel (see FIG. 6).

Further, the second impeller 6 is formed to have a smaller diameter than the first impeller 5. The gap formed between the first case 2 and the first impeller 5 (the radial outer gap of the first impeller 5) is the gap formed between the second case 3 and the second impeller 6 (the first). It is formed narrower than the radial outer gap of the two impellers 6.

As shown in the enlarged view of the portion B of FIG. 3 and FIG. 6, a boss 611b protruding in a substantially annular shape is formed on the rear surface of the bottom portion 611 of the second hub 61. The boss 611b is provided on the rotation axis P of the second impeller 6.

The second case 3 has an opening 314 on the left side surface. Further, the second case 3 has a circular opening 315 in which the switch SW is exposed on the front surface.

The circuit board 82 is formed in the shape of a long rectangular plate in the left-right direction. A receptacle 821 for a USB terminal, which is a mounting component, is provided on the left side edge on the rear side of the circuit board 82. A jack can be inserted into the receptacle 821 from the outside through the opening 314. Further, a push butane type switch SW is provided on the front side of the circuit board 82.

FIG. 7 is an exploded perspective view seen from the front side of the tethered member 9, and FIG. 8 is an exploded perspective view seen from the back surface side of the tethered member 9. Further, FIG. 9 is a cross-sectional view taken along the line IX-IX around the gate 94 of the fan 1 of FIG.

The mooring member 9 has a carabiner portion 91 and a main body portion 92 fixed to the cases 2 and 3 of the fan 1. The mooring member 9 can be formed of fiber reinforced plastic. As the fiber material, for example, glass fiber, carbon fiber, or a resin fiber different from the base material can be used.

The carabiner portion 91 has a frame 911 formed in a substantially J-shape in the rear view and a hinge portion 912. The carabiner portion 91 can moor the moored object by hanging an arbitrary moored object such as a string-shaped body (not shown) in the accommodation space S formed in the frame 911 and closing the gate 94.

The frame 911 is formed in a substantially circular cross-sectional view. The nose portion 913 formed at the tip of the frame 911 is arranged so as to face the hinge portion 912. As shown in FIG. 8, a protrusion 911a is formed on the curved portion 911b of the frame 911. The protruding portion 911a protrudes in a substantially mountain-shaped plate shape from the rear surface side of the curved portion 911b.

Notches 913a and 913b are formed on the front and rear sides of the tip of the nose portion 913. The nose portion 913 is formed by the cutout portions 913a and 913b in a substantially thick plate shape in which the front surface and the rear surface on the distal end side are substantially parallel to each other. Further, a protruding portion 913c projecting to the rear side is formed in one cutout portion 913a. The protrusion 913c is formed in a part outside the accommodation space S. A part of the outer peripheral surface of the protruding portion 913c is formed continuously with the curved outer peripheral surface of the nose portion 913. Further, the tip surface 913d of the nose portion 913 is inclined downward (that is, in a direction away from the hinge portion 912) from the outside to the inside (accommodation space S side) of the carabiner portion 91.

The base end side of the hinge portion 912 is formed in a substantially columnar shape and is connected to the main body portion 92. The tip end side of the hinge portion 912 is formed in a thick plate shape. The tip surface 912a of the hinge portion 912 is inclined upward (that is, in a direction away from the nose portion 913) from the outside to the inside (accommodation space S side) of the carabiner portion 91, contrary to the above-mentioned tip surface 913d. .. Edge portions 912b and 912c, which are end faces substantially perpendicular to the axial direction of the hinge portion 912, are formed at both left and right ends of the tip surface 912a (see FIG. 8). Further, a concave curved notch 912d is formed on the edge portion 912c side of the tip surface 912a. The cutout portion 912d is cut out in the front-rear direction. Further, on the front surface and the rear surface of the hinge portion 912 on the front end surface 912a side, a rotating shaft portion 912e standing in a short columnar shape in the front-rear direction is formed.

The main body 92 is formed in a substantially plate shape as a whole. Below the main body portion 92, the proximal end side of the frame 911 of the carabiner portion 91 and the proximal end side of the hinge portion 912 are connected. A battery accommodating portion 921 that accommodates a part of the lower end side of the battery 83 shown in FIG. 2 or the like is formed on the center side of the main body portion 92. The battery accommodating portion 921 is formed in the shape of a curved plate protruding forward. Rib portions 921a extend to the left and right of the battery accommodating portion 921 on the front surface side of the main body portion 92.

A plurality of fixing holes 922 are formed on both the left and right sides of the battery accommodating portion 921. The fixing member 312 shown in FIG. 3 is inserted into each fixing hole 922, and the main body portion 92 can be fixed to the second case 3 side.

An accommodating portion 923 extending upward is formed from the upper left end of the main body portion 92. The accommodating portion 923 is formed in a substantially rectangular frame shape that opens to the front left side of the fan 1. The accommodating portion 923 is formed with a substantially L-shaped rib portion 923c extending over the inner surfaces of the top plate portion 923a and the bottom plate portion 923b. The rib portions 923c are provided at two upper and lower positions so as to be parallel to each other.

Further, on the left and right sides of the carabiner portion 91 of the main body portion 92, groove portions 924 recessed so as to face the accommodation space S side of the carabiner portion 91 are formed. The groove portion 924 can be engaged with the engaging projection 316 (see FIG. 5) provided on the lower end edge of the second case 3 to position the mooring member 9 with respect to the second case 3.

The mooring member 9 has a contact portion 93 projecting rearward between the hinge portion 912 and the main body portion 92 (see FIG. 8). The contact portion 93 is arranged on the main body portion 92 side, which is the base end side of the hinge portion 912, with respect to the rotation shaft portion 912e. The contact portion 93 is adjacent to the hinge portion 912.

The gate 94 is formed in a cylindrical shape with a bottom, and has an outer peripheral diameter substantially the same as that of the frame 911. The gate 94 has a rotating portion 941 on one upper end side and a tip portion 942 on the lower other end side. A bifurcated plate-shaped portion 942,944 (first plate-shaped portion) is formed on the rotating portion 941, and a bifurcated plate-shaped portion 945,946 (second plate-shaped portion) is also formed on the tip portion 942.

Bearing portions 943a and 944a through which the rotating shaft portion 912e is inserted are formed in the plate-shaped portions 943 and 944 of the rotating portion 941. Grooves 943b and 944b extending upward from the bearings 943a and 944a are formed on the inner surface of the plate-shaped portions 943 and 944. The groove portions 943b and 944b are formed so as to gradually become deeper toward the upper end side of the plate-shaped portions 943 and 944. Therefore, the rotating shaft portion 912e can be guided to the bearing portions 943a and 944a via the groove portions 943b and 944b, and the gate 94 can be easily assembled to the hinge portion 912.

Further, on the accommodation space S side of one of the plate-shaped portions 943, an abutted portion 943c projecting upward is formed. The contacted portion 943c is arranged on the proximal end side of the hinge portion 912 with respect to the bearing portions 943a and 944a when the gate 94 is assembled to the hinge portion 912. The upper end surface of the contacted portion 943c is inclined so as to gradually increase toward the accommodation space S side.

As shown in FIG. 9, a hollow portion 947 having an upper opening is formed in the gate 94. The hollow portion 947 is formed so that the inner diameter gradually decreases toward the bottom. An engaging protrusion 947a projecting upward is formed at the bottom of the hollow portion 947. The opening of the hollow portion 947 is formed between the plate-shaped portion 943 and the plate-shaped portion 944.

As shown in FIGS. 8 and 9, a substantially flat inclined end surface 942a is formed between the plate-shaped portions 945 and 946 on the lower end side of the gate 94. The inclined end surface 942a is inclined downward toward the accommodation space S side of the carabiner portion 91. Further, a notch portion 945a is formed on the outer side of the plate-shaped portion 945 on one side opposite to the accommodation space S. In the closed state of the gate 94, the cutout portion 945a and the protruding portion 913c are in contact with each other (see the broken line portion in FIG. 9), and the gate 94 is outside the accommodation space S with respect to the nose portion 913 (right side in FIG. 9). It can be regulated not to open too much.

Further, the gate 94 is urged to the hinge portion 912 in the closing direction by the elastic member 95. As shown in FIG. 9, the elastic member 95 includes a long plate-shaped guide plate 951 and a coil spring 952 that winds a part of the lower end of the guide plate 951. The upper end of the guide plate 951 engages with the notch 912d, and the lower end side of the guide plate 951 is arranged in the hollow portion 947. Further, the guide plate 951 is bent toward the accommodation space S side at the bent portion 951a on the central side.

The lower end of the coil spring 952 is engaged with the engaging projection 947a. The upper end of the coil spring 952 abuts on the bent portion 951a and urges the guide plate 951 upward. Therefore, the guide plate 951 engages one end side of the guide plate 951 with the notch 912d without falling into the hollow portion 947. The coil spring 952 can urge the gate 94 to the closed state by pushing the inner peripheral surface 947b or the engaging protrusion 947a of the hollow portion 947 in the closing direction by the elastic force.

As shown in FIG. 9, when the gate 94 is in the closed state, the inclined end surface 942a abuts on the tip surface 913d, and the notch 945a abuts on the protrusion 913c. Further, when the gate 94 is in the closed state, the contacted portion 943c comes into contact with the abutting portion 93. Thereby, it is possible to prevent the gate 94 from rotating too much toward the outside of the accommodation space S. Further, when the gate 94 is in the closed state, the gate 94 is substantially coaxial with the hinge portion 912 and the nose portion 913.

When the user urges the gate 94 toward the accommodation space S side, the gate 94 rotates about the rotation shaft portion 912e against the elastic force of the elastic member 95, and becomes a two-dot chain line in FIG. It can be in the open state shown. By opening the gate 94, the user can moor the moored object in the accommodation space S or remove it from the accommodation space S. Further, in the mooring member 9 of the present embodiment, the tip surface 913d of the nose portion 913 is inclined flat, so that the mooring member 9 can be easily removed from the carabiner portion 91 without being caught by the nose portion 913 when the moored object is removed from the accommodation space S. Can be removed.

Next, the stand 4 will be described. The stand 4 shown in FIG. 2 and the like is formed in a substantially L-shaped plate shape in a side view, and has a grounding portion 41 that is in contact with the mounting surface and a support portion 42 that supports the fan 1.

The ground contact portion 41 is formed in a substantially rectangular plate shape. The outer peripheral edge side of the ground contact portion 41 is formed in a flat plate shape, and the central side of the ground contact portion 41 is curved so as to be recessed upward away from the mounting surface. As shown in FIG. 3, a grounding projection 411 formed by a cushioning member or the like is formed on the lower surface of the grounding portion 41.

The support portion 42 is connected to the front end of the ground contact portion 41 with a slight inclination to the rear. The support portion 42 is formed in a substantially U-shaped frame shape that opens upward in front view. A U-shaped groove portion 421 is formed on the opposite inner edge side of the support portion 42. An opening 422 that allows the stand 4 to penetrate vertically is formed on the lower end side of the groove 421 (see FIG. 3).

As shown in the enlarged view of the A portion in FIG. 2, an engaging portion 423 that engages with the protrusion 911a of the carabiner portion 91 is formed on the inner surface 421a on the lower end side of the groove portion 421. The engaging portion 423 has two inclined protrusions 423a extending vertically and an engaging groove 423b formed between the inclined protrusions 423a. The inclined protrusion 423a is formed up and down from the edge portion of the groove portion 421 toward the opening portion 422 side. Further, the inclined protrusion 423a is inclined so as to gradually project downward from the inner surface 421a of the groove portion 421.

The engaging groove 423b is open to the upper side of the groove portion 421. The bottom portion of the engaging groove 423b is recessed lower than the inner surface 421a of the groove portion 421. Further, the lower end portion 423b1 in the engaging groove 423b can support the carabiner portion 91 by abutting a part of the protrusion 911a engaged with the engaging groove 423b.

When the stand 4 is configured in this way, the protrusion 911a of the carabiner portion 91 can be engaged (not shown) in the engagement groove 423b in the state of FIG. 1 in which the carabiner portion 91 is inserted into the groove portion 421. .. At this time, since the inclined projection 423a is inclined so as to project downward, the frame 911 of the carabiner portion 91 is inserted into the groove portion 421 and is pinched by the inclined projection 423a. Therefore, when the fan 1 is supported by the stand 4, it is possible to prevent the fan 1 from swinging to the left and right by the protrusion 911a and the engaging groove 423b, and to reliably hold the fan 1 by the narrow pressure of the inclined protrusion 423a.

As described above, the fan 1 described in the present embodiment includes the first impeller 5 and the second impeller 6, and is arranged with a gap between the second impeller 6 and the second impeller 6 on the second impeller 6 side, and the rotation shaft P of the second impeller 6 is provided. The grill 321 is provided so as to be inclined toward the first impeller 5 side from the center side to the outside in the radial direction. Further, the end edge of the blade on the grill 321 side of the second impeller 6 was inclined toward the first impeller 5 side from the center side of the rotation axis P toward the outer side in the radial direction.

The electric fan 1 has a first impeller 5 and a second impeller 6 that rotate in opposite directions to each other, and can realize powerful air blowing with low power consumption and space. Further, since the boss 611b is provided on the second hub 61 of the second impeller 6 so as to face the first hub 51 of the first impeller 5, the first case 2 and the first case 2 and the second are used while the fan 1 is being used. (2) Even if there is a load that bends the case 3, it is possible to prevent the blades (first blade 52, second blade 62) of the first impeller 5 and the second impeller 6 from coming into contact with each other. Therefore, the electric fan 1 can be provided with both portability and practicality even in a situation where the electric fan 1 is carried and used outdoors.

Further, in the present embodiment, since the first blade 52 of the first impeller 5 and the second blade 62 of the second impeller 6 are provided with an odd number of sheets, the rotation balance is kept good and the load on the motors 71 and 72 is reduced. Etc. Further, since the motor 71 of the first impeller 5 is fixed to the first case 2 side and the motor 72 of the second impeller 6 is fixed to the second case 3, the wiring cables 811 and 812 can be arranged on the front and rear outside. , The distance between the impellers 5, 6 and the motors 71, 72 can be shortened to make the entire fan 1 smaller.

Further, a part of the main body portion 92 of the mooring member 9 is arranged so as to cover a part of the mounting surface side of the circuit board 82, and forms a housing portion 923 for supporting the receptacle 821 mounted on the circuit board 82. Therefore, the load on the receptacle 821 generated by the insertion and removal of the USB cable is distributed to the accommodating portion 923, and the load on the mounting surface of the circuit board 82 can be reduced.

Further, in the carabiner portion 91, when the gate 94 is closed, the notch portion 945a of the gate 94 and the protruding portion 913c of the nose portion 913 come into contact with each other, and the contacted portion 943c of the gate 94 and the hinge portion 912 side. The structure is such that the contact portion 93 is in contact with the contact portion 93. When the carabiner structure is to be provided on various portable tools, it can be formed of a strong material such as metal, but the weight and cost are expected to increase. On the other hand, when trying to make a carabiner structure from an inexpensive material, for example, in plastic or the like, the engagement state between the nose portion 913 and the gate 94 is disengaged due to stress strain in the separation direction between the hinge portion 912 and the nose portion 913, and the gate 94 is intended. It is also assumed that the accommodation space S will rotate to the opposite side. However, the carabiner portion 91 of the present embodiment is provided with the contacted portion 943c and the abutting portion 93 to restrict the rotation of the gate 94 also on the hinge portion 912 side, thereby preventing the gate 94 from opening unintentionally. can.

Although the embodiment of the present invention has been described above, this embodiment is presented as an example and is not intended to limit the scope of the invention. These novel embodiments can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. The embodiments and variations thereof are included in the scope and gist of the invention, and are included in the scope of the invention described in the claims and the equivalent scope thereof.

1 Fan 2 1st case 3 2nd case 4 Stand 5 1st impeller 6 2nd impeller 9 Tethering member 11 Grip part 12 Blower head 20a Engagement claw 20b Engagement hole 21 Bearing part 22 Impeller cover part 23 Motor housing part 24 Cover 30a Engagement hole 30b Engagement claw 31 Accommodating part 32 Impeller cover part 33 Motor accommodating part 34 Cover 41 Grounding part 42 Support part 51 First hub 52 First blade 61 Second hub 62 Second blade 71,72 Motor 82 Circuit board 83 Battery 91 Carabina part 92 Main body part 93 Contact part 94 Gate 95 Repulsion member 211 Top plate part 211a Notch part 211b Step part 211c Engagement protrusion 213 Notch part 221 Grill 221a Frame body 221b Guide frame 221c Groove part 221d Notch part 222 Grill 222a Frame 231 Bearing 232 Engagement 232a Protrusion 311 Top plate 311a Notch 311b Step 311c Engagement 312 Fixing member 313 Notch 314 Opening 315 Opening 316 Engagement protrusion 321 Grill 321a Frame Guide frame 321c Groove 331 Bearing 332 Engagement 332a Protrusion 411 Ground protrusion 421 Groove 421a Inner surface 422 Opening 423 Engagement 423a Inclined protrusion 423b Engagement groove 423b1 End 511 Bottom 511a Bearing 521 Front edge 521 Rear end edge 611 Bottom part 611a Bearing part 611b Boss 612 Front end edge 621 Front end edge 622 Rear end edge 711 Rotating shaft 721 Rotating shaft 81 Wiring cable 811a Jack part 811b Engaging part 811c Engagement hole 811d Widening part 812 Wiring cable 812a Engagement part 812c Engagement hole 812d Widening part 821 Receptacle 911 Frame 911a Protrusion part 911b Curved part 912 Hinge part 912a Tip surface 912b Edge part 912c Edge part 912d Notch part 912e Rotating shaft part 913 Nose part 913 Protruding part 913d Tip surface 921 Battery housing part 921a Rib part 922 Fixing hole 923 Storage part 923a Top plate part 923b Bottom plate part 923c Rib part 924 Groove part 941 Rotating part 942 Tip part 942a Inclined end face 943 Plate-shaped part 943a 943b Groove part 943c Contacted part 944 Plate-shaped part 944a Bearing part 944b Groove part 945 Plate-shaped part 945a Notch part 946 Plate-shaped part 947 Hollow part 947a Engagement protrusion 947b Inner peripheral surface 951 Guide plate 951a Bending part 952 Coil spring P S accommodation space SW switch

Claims (8)

With the first impeller,
A second impeller that is arranged so that the center of the rotation axis is aligned with the first impeller and rotates in the opposite direction to the first impeller,
A grill that is arranged on the second impeller side with a gap from the second impeller and is inclined toward the first impeller side from the center side of the rotation axis of the second impeller toward the outside in the radial direction.
Equipped with
The edge of the blade on the grill side of the second impeller is inclined toward the first impeller side in the radial direction from the center side of the rotation axis.
The first impeller has a first hub and
The second impeller has a second hub provided with a boss projecting toward the first hub.
A fan that features that. The boss is erected in a cylindrical shape from the second hub with the rotation axis as the center.
The gap between the tip of the boss and the first hub is formed narrower than the gap between the first impeller and the second impeller.
The electric fan according to claim 1 . The first hub and the second hub are each formed in a bottomed cylindrical shape.
The bottom of the second hub on which the boss is formed and the bottom of the first hub are arranged so as to face each other.
The electric fan according to claim 1 or 2 , characterized in that. The aspect according to any one of claims 1 to 3 , wherein the edge of the blade on the grill side is formed so that the gap between the grill and the second impeller is parallel. Fan. The motor for rotating the first impeller is fixed to the first case accommodating the first impeller.
The motor for rotating the second impeller accommodates the second impeller and is fixed to the second case having the grill.
The electric fan according to any one of claims 1 to 4 . The first impeller is located upstream and
The second impeller is arranged on the downstream side.
The electric fan according to any one of claims 1 to 5 . The electric fan according to any one of claims 1 to 6, wherein the second impeller is formed to have a smaller diameter than the first impeller . The electric fan according to any one of claims 1 to 7, wherein the first impeller is formed so that the front end edge and the rear end edge in the axial direction of the rotation axis are parallel to each other.

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