JP6730160B2 - Blower - Google Patents

Description

The present invention relates to a blower device such as a fan or a circulator.

Conventionally, as a blower of this type, a support seat as a base placed on the floor, a support pillar provided above the support seat, and an upper end of the support pillar are provided as a fan for blowing air. A main body as a blower having a propeller and a rotary shaft drive device for horizontally swinging the main body, and by making the support column rotatable with respect to the support seat, BACKGROUND ART There is known a fan capable of changing the direction of a propeller of a supported main body (see, for example, Patent Document 1).

Utility model registration No. 3184739

However, in such an air blower, it is necessary to rotate the air blower provided with the fan and the fan motor at the upper end portion, and thus the air blower may be unstable.

An object of the present invention is to solve the above problems and to provide an air blower capable of stably rotating or reciprocally rotating the air blower.

Blower according to claim 1 of the present invention, a base, a feed air portion that is rotatably or reciprocally rotated relative to the base, rotating or reciprocating rotation of the blower with respect to the base In a blower having a swinging motor, the blower unit has a support column vertically erected from a base, an arm provided at an upper end of the support unit, and a blower provided with a fan and a fan motor. A main body , at least a part of the fan motor is inserted into a hub of the fan , the fan motor is located inside a guard covering the outside of the fan, and is located behind the fan motor. A hinge portion is provided that axially supports the blower unit body so that the blower unit can be elevated, and the hinge portion is connected to the arm portion that projects rearward from the outer surface of the lower end portion of the blower unit, and the blower direction is horizontal. in the state, a shall be located on the central axis of the pillar longitudinal center of the fan is the center of rotation of the blower.

The blower according to claim 2 of the present invention is the blower according to claim 1, wherein the distance from the central axis of the blower to the rear end of the arm is the distance from the central axis to the left and right ends of the guard. Is smaller than.

With the air blower according to claim 1 of the present invention, not only can the air blower main body of the air blower be thinned in the front and rear, but also the center of gravity of the air blower main body can be centered. Since it can be positioned near the axis, the blower unit can be stably rotated or reciprocally rotated. Further, since the fan motor is located inside the guard covering the outside of the fan, not only can the air blower main body of the air blower be thinned forward and backward, but also the center of gravity of the air blower main body is centered. Since it can be positioned near the axis, the blower unit can be stably rotated or reciprocally rotated. Further, behind the fan motor, there is provided a hinge portion for axially supporting the fan so that the fan can be lifted. The hinge portion is connected to an arm portion protruding rearward from the central axis of the rotating shaft, and the air blowing direction is horizontal. In such a state, the center of the fan in the front-rear direction is located on the center axis of the support column that is the center of rotation of the blower, so that the center of gravity of the blower main body can be located close to the center axis. Not only that, but compared to the structure of a fan with a general structure in which the guard is located in front of the stanchion, or the structure of a fan that supports the guard from the left and right, the rotation radius of the blower unit body can be made smaller, so that the blower unit is stable. Can be rotated or reciprocally rotated.

Further, the distance from the central axis to the rear end of the arm is smaller than the distance from the central axis to the left and right ends of the guard, so that the radius of rotation when the blower unit rotates or reciprocates. By reducing the size, the blower unit can be stably rotated or reciprocally rotated.

1 is an overall front view of a blower device showing an embodiment of the present invention. It is a partially expanded sectional view of the same ventilation part. FIG. 3 is an enlarged perspective view of the base of the same. FIG. 3 is a schematic explanatory diagram of the inside of the base portion. 3A and 3B are external views of a rotating body that constitutes the position detecting means, FIG. 6A is a plan view, FIG. 4B is a front view, and FIG. FIG. 3 is a perspective view of a rotating body that constitutes the position detecting means. FIG. 3 is an explanatory diagram of an operation unit and a display unit on the top surface of the base unit. FIG. 7 is an explanatory diagram showing a display state of the display unit when the power plug is connected. FIG. 7 is an explanatory diagram showing a display state of the display unit when the power is turned on. FIG. 7 is an explanatory diagram showing a display state of the display unit when the power is turned on. FIG. 7 is an explanatory diagram showing a display state of the display unit when the power is turned on. FIG. 7 is an explanatory diagram showing a display state of the display unit when the power is turned on. FIG. 7 is an explanatory diagram showing a display state of the display unit when the minimum air volume is the same. FIG. 7 is an explanatory diagram showing a display state of the display unit at the time of maximum air volume. FIG. 6 is an explanatory diagram showing the rotation of the air blower when the direction of the air blower is designated. FIG. 5 is an explanatory diagram showing the rotation of the blower unit when the designated range is one place. FIG. 5 is an explanatory diagram showing the rotation of the blower unit when the designated range is the entire circumference. FIG. 8 is an explanatory diagram showing the rotation of the blower unit when the designated range is two or more places and the range excluding the maximum non-designated range Bmax is 180 degrees or less. FIG. 9 is an explanatory diagram showing the rotation of the blower unit when the designated range is two or more and the range excluding the maximum non-designated range Bmax is larger than 180 degrees. It is the whole blower unit perspective view showing other embodiments of the present invention.

Embodiments of the present invention will be described below with reference to FIGS. 1 to 19. In the following description, the “direction of the blower unit 3” refers to the blowing direction of the blower unit 3. Further, "rotating (or rotating) the air blower 3" means changing the direction of the air blower 3, and is distinguished from "rotating the axial fan 35 of the air blower 3". Further, counterclockwise rotation is defined as forward rotation or forward direction, and clockwise rotation is defined as reverse rotation or reverse direction. 1 is an electric fan as an air blower of the present invention. The electric fan 1 is configured to have a base 2 having a short cylindrical shape and an air blower 3 provided on the base 2. The blower unit 3 is provided with a support column 4 standing vertically from the center of the base unit 2, an inclined L-shaped arm unit 5 provided at the upper end of the support unit 4, and an upper end of the arm unit 5. The air blower main body 6 is provided and configured.

The base 2 has a frame (not shown) and a casing 7 supported on the outside of the frame. An upper bearing 8 and a lower bearing 9 are supported on the frame. The mounting shaft 10 is supported by the bearings 8 and 9. Further, a driven gear 11 is supported on the mounting shaft 10. The driven gear 11 is located between the upper bearing 8 and the lower bearing 9. Further, below the driven gear 11, a position detecting means 12 for detecting in which direction the blower unit 3 faces is provided. A swinging motor 13 including a stepping motor is provided on the side of the mounting shaft 10. That is, the rotation of the swing motor 13 is controlled by the number of pulses of the supplied current. A drive gear 15 is supported on the rotary shaft 14 of the swing motor 13. The drive gear 15 meshes with the driven gear 11. Therefore, the rotation of the swing motor 13 is transmitted to the mounting shaft 10 by the power transmission mechanism including the drive gear 15 and the driven gear 11. The swing motor 13 and the drive gear 15 are located between the upper bearing 8 and the lower bearing 9 in the vertical direction. Therefore, the swinging motor 13, the power transmission mechanism including the driving gear 15 and the driven gear 11, the mounting shaft 10, and the upper bearing 8 and the lower bearing 9 are compactly arranged, so that the base is downsized. You can On the other hand, the space between the upper bearing 8 and the lower bearing 9 can be maximized within the dimensional range of the base 2, so that the mounting shaft 10, and thus the blower 3, can be stably supported. can do. Further, a slip ring 16 for power supply is provided below the mounting shaft 10. The movable side of the slip ring 16 is connected to the mounting shaft 10 and can rotate or rotate together with the mounting shaft 10. On the other hand, the fixed side of the slip ring 16 is fixed to the frame. Reference numeral 17 is a control circuit in which a control unit is mounted. The support column 4 is coaxially fixed to the upper end of the mounting shaft 10.

The position detecting means 12 will be described in detail. As shown in FIGS. 5 and 6, the position detecting means 12 is configured to include a rotating body 18 fixed to the mounting shaft 10 and sensors 19 and 20 fixed to the frame of the base. That is, the rotating body 18 is configured to rotate or reciprocally rotate together with the mounting shaft 10 and, by extension, the blower unit 3 fixed to the mounting shaft 10. The rotating body 18 has a pair of disc-shaped first shield plates 21 and second shield plates 22 and a short cylindrical portion 23 that connects these shield plates 21 and 22, and has a bobbin shape as a whole. Composed. A plurality of (eight in this example) slits 24, 25 are provided in each of the shielding plates 21, 22. It should be noted that these slits 24, 25 are not provided at random, and half of the detection points provided at a predetermined angular interval (16 places in 22.5 degree intervals in this example) are provided with the slits 24. , 25 are formed. Therefore, in the first shielding plate 21, the angle formed by the one slit 24 and the other slit 24 is a multiple of the predetermined angle (22.5 degrees). The same applies to the second shielding plate 22. On the other hand, each of the sensors 19 and 20 is of a type called a photo interrupter. That is, it comprises a light emitting portion and a light receiving portion (neither is shown). Then, the light emitted from the light emitting portion is received by the light receiving portion through the slits 24 and 25, whereby the sensors 19 and 20 emit an ON signal. On the other hand, if the light emitted from the light emitting unit is blocked by the shielding plates 21 and 22 and cannot be received by the light receiving unit, the sensors 19 and 20 do not emit an ON signal. In other words, this state is the off state. That is, in the shield plates 21 and 22 of the rotating body 18, the position where the slits 24 and 25 are formed is the ON portion, and the slits 24 and 25 are separated by a multiple of a predetermined angle (22.5 n degrees: n is an integer). The position where the slits 24 and 25 are not formed is the off portion.

A remote control light receiving window 26, an adjusting unit 27, and a designating unit 28 are concentrically provided on the upper surface of the base 2 from the center toward the outer periphery so as to surround the pillar 4. A plurality of light receiving elements (not shown) are provided in the remote control light receiving window 26. Therefore, the infrared signal emitted from the remote controller (not shown) is received by the light receiving element without being blocked by the support column 4. The adjusting means 27 also serves as a power switch 27a and an air volume display section 27b. The air volume indicator 27b has a plurality of (24 in this example) display LEDs 27c as display elements arranged in an annular shape inside. Further, the designating means 28 also serves as the range display portion 28b. The range display unit 28b has a plurality of (16 in this example, three sets) display LEDs 28c arranged in an annular shape inside the range display unit 28b. The adjusting means 27 and the designating means 28 are operated by pushing them with a finger or tracing in the length direction. The adjusting means 27 and the designating means 28 are provided in an annular shape over the entire circumference of the base 2. As a result, it is possible to intuitively adjust the air volume and specify the air flow direction range from any direction. Further, since the designating means 28 is provided on the upper surface of the base portion 2, the designated range can be viewed, so that the blowing range can be designated more easily. Further, the direction range designated by the designation means 28 is displayed by the range display unit 28b. For this reason, since it is easy to understand which direction range has been specified, it is possible to more easily specify the blast range range.

The adjusting means 27 and the designating means 28 will be described in detail. The adjusting means 27 has an annular switch element (not shown) provided in the base 2, and an annular operating body 27d for operating the switch element. Similarly, the designating means 28 also has an annular switch element (not shown) provided in the base 2, and an annular operating body 28d for operating the switch element. The operating bodies 27d and 28d have a light-transmitting property, and are configured to guide the light of the display LEDs 27c and 28c provided in the casing 7 of the base 2 and emit the light to the outside. .. Then, the adjusting means 27 is divided into 24 segments in the circumferential direction by software in correspondence with the display LEDs 27c. That is, in the adjusting means 27, one segment is in the range of 15 degrees. On the other hand, as shown in FIG. 7, the designating means 28 is divided into 16 segments (S _{0 to} S ₁₅ ) in software in correspondence with the display LEDs 28c. That is, in the designating means 28, one segment is in the range of 22.5 degrees. This is shown in the table below.

The slits 24 and 25 provided on the rotating body 18 of the position detecting means 12 and the places where these slits are not provided, that is, the ON portion and the OFF portion correspond to the respective segments S _{0 to} S _15. It is provided. The correspondence relation between these segments S _{0 to} S ₁₅ and the ON part and the OFF part is as shown in the table below.

The slits 24 and 25 of each of the shielding plates 21 and 22 are provided so that a combination of one segment and an adjacent segment is uniquely determined. For example, when the blower unit 3 rotates forward from S ₀ to S ₁ , the output of the first sensor 19 becomes “OFF-OFF” and the output of the second sensor 20 becomes “ON-ON”. As described above, there is no other place where the first sensor 19 outputs “OFF-OFF” and the second sensor 20 outputs “ON-ON” in the case of forward rotation. Therefore, when the first sensor 19 outputs “OFF” for the second time and the second sensor 20 outputs “ON” for the second time during forward rotation, it is determined that the corresponding segment is currently S _1. To be done. Similarly, when the first sensor 19 outputs “OFF-OFF” and the second sensor 20 outputs “ON-OFF”, at the time when each sensor 19, 20 outputs the second time, The corresponding segment is identified as S ₂ . The same applies when the blower unit 3 rotates in the reverse direction, and the combination of one segment and the adjacent segment is uniquely determined. In other words, the two detection results by the two sensors 19 and 20 are, in other words, a 4-digit binary number, that is, a decimal number “0 to 15”, and the segments S _{0 to} S ₁₅ are divided into 16 segments. It is possible to make a one-to-one correspondence. Note that if the number of divided segments exceeds 16, it cannot be represented by a 4-digit binary number, so it can be handled by moving by 3 segments or increasing the number of sensors. The binary numbers in the above table are arranged in the order of the first detection result of the first sensor 19, the second detection result, the first detection result of the second sensor 20, and the second detection result. In this way, the current direction of the blower unit 3 can be specified by the minimum number of sensors 19 and 20 and the minimum rotation of the blower unit 3.

The pillar 4 is formed in a hollow cylindrical shape. The lower end of the column 4 is fixed to the upper end of the mounting shaft 10 coaxially with the mounting shaft 10. The arm portion 5 includes a retreat portion 29, a bending portion 30, and a standing portion 31. The receding part 29 is formed to extend obliquely upward and rearward. The upright portion 31 is formed to extend obliquely upward and forward. The curved portion 30 and the upright portion 31 are provided as a left and right pair. Then, electric wiring (not shown) is passed through the inside of the support column 4 and the arm portion 5. Further, the air blower main body 6 is provided at an upper end portion of the standing portion 31 of the arm portion 5. The blower unit main body 6 includes a hinge portion 32, a motor casing 33, a fan motor 34, an axial fan 35, and a guard 36. The hinge portion 32 has a swinging mechanism (not shown), and is provided so that the tilting operation can be manually performed on the arm portion 5. In this example, the hinge 32 allows the blower unit body 6 to perform a tilting operation within a range of an elevation angle of 45 degrees to a depression angle of 12 degrees. The motor casing 33 is provided on the front side of the hinge portion 32. Further, the fan motor 34 is entirely provided in the motor casing 33, except for a rotating shaft 34 a projecting forward of the motor casing 33. Further, the axial fan 35 is configured to be rotated by the fan motor 34. Further, the guard 36 is provided so as to surround the fan 35.

A small diameter portion 37 is formed on the front side of the motor casing 33, and the front portion of the fan motor 34 is located in the small diameter portion 37. A short cylindrical hub 38 is provided at the center of the axial fan 35. The inner diameter of the hub 38 is formed to be slightly larger than the outer diameter of the small diameter portion 37. Therefore, when the axial fan 35 is attached to the rotary shaft 34 a, the small diameter portion 37 enters the inside of the hub 38. Therefore, a part of the fan motor 34 is located inside the hub 38 of the axial fan 35. The hinge portion 32 and the motor casing 33 are arranged so as to sandwich the rear portion of the guard 36. Therefore, the fan motor 34 is located inside the guard 36. Further, the center of the guard 36 and the center of the axial flow fan 35 arranged in the guard 36 in the front-rear direction is located on the central axis A in a state where the air blowing direction is horizontal as shown in FIG. Then, as described above, a part of the fan motor 34 is located inside the hub 38, the entire fan motor 34 is located inside the guard, and the hinge portion 32 is provided behind the guard 36. Since the protrusion size of the blower unit can be minimized, not only can the blower unit body 6 be thinned in the front-rear direction, but the center of gravity of the blower unit body 6 becomes a position close to the central axis A. Further, the distance Z from the central axis A of the column 4 to the rear end of the curved portion 30 of the arm 5 is smaller than the distance X from the central axis A to the left and right ends of the guard 36. For this reason, not only the deviation of the center of gravity of the blower unit 3 from the central axis A can be minimized, but also the fan having a general structure in which the guard is located in front of the column and the guard from the right and left Compared with the structure of the fan to support, the radius of rotation of the blower unit body 6 can be made smaller, and the blower unit 3 can be stably rotated or reciprocally rotated. The radius R of the base 2 is smaller than the distance X described above. Therefore, when the blower unit 3 is rotated, all the elements of the fan 1 except the power cord (not shown) are located inside the trajectory drawn by the left and right ends of the guard 36 in plan view.

Next, the operation of this embodiment will be described. First, when the user connects a power plug (not shown) to an AC power source, as shown in FIG. 8, the display LED 27c, which is a display element of the air volume display unit 27b, blinks darkly. At the same time, the control circuit 17 operates the swing motor 13 to rotate the blower unit 3 in the forward direction, and the position detection unit 12 identifies the direction in which the blower unit 3 is facing. That is, when the first sensor 19 outputs “OFF-OFF” and the second sensor 20 outputs “ON-ON”, the air blowing is performed when the respective sensors 19, 20 output the second time. It is specified that the part 3 faces the direction D ₁ . Similarly, when the first sensor 19 outputs "OFF-OFF" and the second sensor 20 outputs "ON-OFF", the air blown at the time when each sensor 19, 20 outputs the second time. It is specified that the part 3 faces the direction D ₂ . Then, the control circuit 17 stops the drive of the swing motor 13 at the time when the direction of the blower unit 3 is specified, and stores the current direction of the blower unit 3.

The operation for specifying the direction of the blower unit 3 may be performed when the power is turned on. Further, even if the blower unit 3 is rotated in the forward direction by two segments in order to specify the direction of the blower unit 3 and then the blower unit 3 is held at that position, the blower unit 3 is moved in the reverse direction by two segments. You may make it rotate and return.

Next, the fan 1 is turned on by touching and lightly pressing the adjusting means 27 which also serves as the power switch 27a. The power switch 27a/adjusting means 27 may be pushed anywhere on the annular operation body 27d. Then, when the electric power of the fan 1 is turned on, the control circuit 17 ends the dark blinking of the air volume display unit 27b, lights the display LED 27c in the air volume display of the initial setting value, and causes the fan motor 24 to operate. By supplying the electric current, the axial fan 35 is rotated to generate wind. In the case of this example, the set air volume is 10 steps, and the initial value of the set air volume is 5. Further, the set air volume is expressed by the number of lights of the display LED 27c. The number of the indicator LEDs 27c that are turned on is as shown in the table below.

That is, at the time of the minimum air volume, as shown in FIG. 13, the number of lights of the display LED 27c of the air volume display section 27b is four. On the other hand, at the maximum air volume, as shown in FIG. 14, the number of the display LEDs 27c of the air volume display section 27b that are turned on is 22. Since these display LEDs 27c are arranged in an annular shape, the number of lights of these display LEDs 27c is the length of the arc. Then, the lit display LED 27c rotates in the forward direction while keeping the number, that is, keeping the length of the arc, unless the air volume is changed. For example, when the air volume is the initial setting value, the number of the indicator LEDs 27c that are turned on is 12. Then, among the illuminated display LEDs 27c, the display LED 27c at the rear end in the forward direction is turned off, and at the same time, the display LED 27c adjacent to the display LED 27c at the front end in the forward direction is illuminated. By repeating this, as shown in FIGS. 9 to 12, the light emission display of the air volume display unit 27b rotates in the forward direction.

With such a display, the air volume display unit 27b can display the air volume in all directions in the same manner. That is, in the conventional structure in which the display unit is fixed, the air volume display can be viewed only from a certain direction or is difficult to view. However, in the structure of the present invention, since the display makes one round in a predetermined time, the display of the air volume display unit 27b can be viewed from any direction without distinction between the front, rear, left and right of the fan 1.

Electric power is supplied from the control circuit 17 to the fan motor 34 via the slip ring 16 and lead wires (not shown) that are passed through the inside of the support column 4 and the arm portion 5. As described above, the electric power is supplied from the control circuit 17 of the base unit 3 to the fan motor 34 of the blower unit 3 via the slip ring 16, so that the blower unit 3 can supply 360 to the base unit 2. Even if the rotation speed is far exceeded, the control circuit 17 can continue to safely supply electric power to the fan motor 34.

The remote controller (not shown) is provided with a child lock button. When the child lock button is pressed, the rotation display of the air volume display unit 27b is stopped. The child lock state can also be obtained by performing a special operation, for example, pressing the power switch 27a three times. In the child lock state, the operation of the main body of the fan 1 can be performed only by turning off the power by operating the power switch 27a and adjusting means 27, except for a special operation for releasing the child lock. The child lock state is released by a child lock button on the remote controller or a special operation of the power switch 27a.

The air volume is adjusted by operating the adjusting means 27. More specifically, the control circuit 17 controls the fan motor 34 according to the distance and the direction of tracing the operation body 27d of the adjusting means 27 with a finger. More specifically, in the first two touched segments of the 24 segments of the adjusting means 27, the control circuit 17 determines whether the finger is traced in the forward direction or the backward direction. That is, it is determined whether the first touched segment and the next touched segment have a forward positional relationship or a reverse positional relationship. When it is determined that the operating body 27d is traced in the forward direction, the control circuit 17 controls the fan motor 34 to increase the air volume. On the contrary, when it is determined that the operating body 27d is traced in the opposite direction, the control circuit 17 controls the fan motor 34 so as to reduce the air volume. Then, after the first direction determination, how many segments are traced is detected. In the case of this example, the air volume setting is changed by one step for each segment of the finger movement. In the case of this example, the second segment touched for detecting the direction is regarded as one stage of the air volume setting. For example, a case of changing from the minimum air volume state to the maximum air volume state will be described. In this case, the air volume is increased by 9 steps. At this time, the user traces the operating body 27d for 10 segments at an angle of 150 degrees with a finger. Two segments are used for detecting the direction of tracing with a finger and for the first one-step increase in air volume, and eight segments are used for the remaining eight-step air volume increase. Even if the finger is traced over 10 segments (150 degrees), the control circuit 17 ignores the 11th segment and thereafter. Further, for example, when the current air volume is in the fifth stage and the maximum air volume is increased, the control circuit 17 ignores the amount exceeding 6 segments (90 degrees). The same applies when the operation is performed to reduce the air volume.

When tracing the operating body 27d with a finger to adjust the air volume, the starting point may be anywhere on the annular operating body 27d. That is, the air volume can be adjusted simply by determining the tracing direction and the tracing distance with a finger. Therefore, the amount of air can be adjusted in the same manner and intuitively from any direction of the fan 1. Further, in this example, the air volume can be adjusted according to the direction in which the operating body 27d is traced with the finger, and the air volume can be adjusted according to the number of times in which the operating body 27d is traced with the finger. May be.

A case where the direction of the blower unit 3 is changed will be described. The direction in which the blower unit 3 is directed can be directly designated by the designating unit 28 and can be stopped during rotation or rotation of the blower unit 3 from D ₀ to D _15. Either of them can be selected. Then, whichever method is used, the direction in which the blower unit 3 is facing is specified. In the former method, the designation is made directly by the designation means 28, which is obvious. In the latter method, since the blower unit 3 is driven by the swinging motor 13 which is a stepping motor, it can be specified. That is, the number of pulses N that needs to be supplied to the swing motor 13 to move the blower unit 3 by an angle of one segment, and the number of pulses required when the blower unit is rotated or rotated from the reference position to the current position. The number of pulses (however, the number of pulses when rotating or rotating in the forward direction is plus, and the number of pulses when rotating or rotating in the opposite direction is minus) can be specified. For example, from the state in which the blower unit 3 is oriented in the direction D ₃ corresponding to the end of the swing range, a 3N pulse is supplied to the swing motor 13 in the forward direction, and then the blower unit 3 is rotated. When the movement is stopped, the direction in which the blower unit 3 is facing is the corresponding direction D ₆ of the segment S ₆ which is a position moved by 3 segments in the forward direction with respect to the initial direction D ₃ (segment S ₃ ). Is identified. When the direction of the blower unit 3 is changed, information on the current direction of the blower unit 3 is stored in the storage unit of the microcomputer (not shown) of the control circuit 17. In this way, which of the directions D ₀ to D ₁₅ the blowing unit 3 is facing is specified and stored. The direction of the blower unit 3 is controlled by the number of pulses of the current supplied to the swing motor 13, but is corrected by the position detection unit 12. As described above, the correction by the position detection unit 12 makes it possible to accurately control the rotation or rotation of the blower unit 3.

The method of directly designating the direction of the blower unit 3 by the designating means 28 will be described in more detail. With the blower unit 3 not rotating or rotating, the user touches an arbitrary position on the operating body 28d of the annular designating unit 28 and gently pushes it. As described above, since the segment of the designation means 28 is directly designated, the segment serving as the target position is specified. In addition, since the current direction of the blower unit 3 is stored in the storage unit of the microcomputer (not shown), the segment at the current position is also specified. Then, the control circuit 17 calculates whether the angle formed by the starting segment and the target segment around the central axis A becomes smaller by forward rotation or reverse rotation, and swings around the angle where the angle becomes smaller. By driving the motor 13, the blower unit 3 is rotated. For example, as shown in FIG. 15, when the starting segment corresponding to the current direction D ₀ of the blower unit 3 is S ₀ and S ₇ is designated as the target segment, the blower unit 3 is moved backward 202. Instead of rotating 5 degrees, rotate forward 157.5 degrees. In addition, when the target segment is the exact opposite of the departure segment, the blower unit 3 may be rotated in either direction, but in this example, the blower unit when the rotation or the rotation is stopped last is performed. The rotation or rotation direction of 3 is stored and this direction is adopted.

In this way, when the direction of the blower unit 3 is designated, it is calculated from the relationship between the starting segment and the target segment which of the forward rotation and the reverse rotation is smaller, and the smaller angle is calculated. By rotating the blower unit 3 around such a range that the angular distance between the starting segment and the target segment becomes smaller, not only can the blower unit 3 be oriented in a desired direction in a short time, but also the blower unit. It is possible to reduce unnecessary electric power when rotating the device 3.

The rotation angular velocity when rotating the blower unit 3 to the designated direction is faster than the rotation angular velocity or the rotation angular velocity during the blown air, which will be described later. However, as described above, not only is the displacement of the center of gravity of the blower unit 3 from the central axis A minimized, but the mounting shaft 10 to which the support column 3 is fixed has a vertical distance. By being pivotally supported by the pair of bearings 8 and 9 provided separately from each other, the blower unit 3 can be stably and smoothly rotated without swaying.

A case where the air is blown while rotating or rotating the air blower 3 will be described. The user can specify the blowing range of the blowing unit 3 by tracing the designation unit 28 with a finger. For example, as shown in FIG. 16, of the user the designation unit 28, by specifying the blowing range by tracing from _{S 1} to _{S 4} with a finger, the display LED28c of the specified segment _S 1 to S ₄ is It lights up and the range of 67.5 degrees corresponding to the direction D ₁ to the direction D ₄ becomes one designated range F ₁ . In this way, the blowing range can be intuitively designated by tracing the operating body 28d of the designating means 28, which is formed in an annular shape around the support column 4, with a finger. When the direction of the blower unit 3 is within the designated range F _{1 when} the range is designated, the control circuit 17 causes the blower unit 3 to reciprocate between the directions D ₁ to D ₄ as it is. On the other hand, when the direction of the blower unit 3 is outside the specified range F _{1 when} the range is designated, the control circuit 17 causes the blower unit 3 to move the direction of the blower unit 3 to the direction D ₁ or D _4. After rotating 3, it is reciprocally rotated between directions D ₁ to D ₄ . The rotation angular velocity of the blower unit 3 when the blower unit 3 is rotated from the initial direction to the direction D ₁ or D _{4 is the same} as that of the blower unit 3 when the blower unit 3 is reciprocally rotated between the directions D ₁ and D _4. Is faster than the rotation angular velocity of. In this way, when only one designated range F _{1 for} 15 segments or less is designated, the control circuit 17 causes the blower unit 3 to reciprocally rotate. Note that, as shown in FIG. 17, when one designated range F ₁ is designated over 16 segments (that is, the entire circumference), the control circuit 17 rotates the blower unit 3 in the forward direction.

Further, a plurality of blowing ranges can be designated. For example, as shown in FIG. 18, after tracing the segments S ₁ to S _{4 of the} designating means 28 with a finger to designate the designated range F ₁ , the segments S ₇ to S _{9 of} the designating means 28 are traced with a finger. The designated range F ₂ can be designated. In this case, in addition to the display LED28c of the specified segment _S 1 to S _4, display LED28c of the specified segment _S 7 to S ₉ is turned. At this time, non-designated ranges B ₁ and B ₂ are generated between the designated ranges F ₁ and F ₂ . In this case, the non-specified range _{B 1} is up direction _{D 7} of the segment _{S 7,} from the direction _{D 9} segments _{S 9} to the direction _{D 4} of the segment _{S 1} in a non-specified range _{B 2} in the direction _{D 4} of the segments _{S 4} ..

Then, the control circuit 17 rotates or rotates the blower unit 3 depending on the condition of the designated blower range. Specifically, when the value obtained by subtracting the angle of the non-designated range Bmax having the largest angle among the non-designated ranges from 360 degrees is greater than 180 degrees, the control circuit 17 causes the blower to blow the air. Rotate the part 3. On the other hand, when the value obtained by subtracting the angle of the non-designated range Bmax having the largest angle among the non-designated ranges from 360 degrees is 180 degrees or less, the control circuit 17 reciprocates the blower unit 3 back and forth. Rotate. In the case of FIG. 18, when the non-designated ranges B ₁ and B ₂ are compared, since B ₁ is 67.5 degrees and B ₂ is 180 degrees, B ₂ =Bmax, and 180 degrees is subtracted from 360 degrees. Since the value is 180 degrees, the control circuit 17 reciprocally rotates the blower unit 3. On the other hand, as shown in FIG. 19, when S ₀ to S ₄ are designated as F ₁ and S ₇ to S ₁₀ are designated as F ₂ , since B ₁ is 67.5 degrees and B ₂ is 135 degrees, , B ₂ =Bmax, and the value obtained by subtracting 135 degrees from 360 degrees is 225 degrees, so the control circuit 17 rotates the blower unit 3. When organized, it looks like the table.

In the case of FIG. 18, the control circuit 17 causes the swing motor 13 to rotate the blower unit 3 at a low speed in the forward direction until the direction of the blower unit 3 changes from the direction D ₁ to the direction D _4. To drive. Next, the control circuit 17 drives the swing motor 13 so as to rotate the blower unit 3 in the forward direction at high speed until the direction of the blower unit 3 changes from the direction D ₄ to the direction D _7. To do. Next, the control circuit 17 drives the swing motor 13 so that the blower unit 3 rotates in the forward direction at a low speed until the direction of the blower unit 3 changes from the direction D ₇ to the direction D _9. To do. Next, the control circuit 17 drives the swing motor 13 so that the blower unit 3 rotates at a low speed in the opposite direction until the direction of the blower unit 3 changes from the direction D ₉ to the direction D _7. To do. Next, the control circuit 17 drives the swinging motor 13 so that the blower unit 3 rotates in the opposite direction at high speed until the direction of the blower unit 3 changes from the direction D ₇ to the direction D _4. To do. Further, the control circuit 17 drives the swinging motor 13 so that the blower unit 3 rotates in the reverse direction at a low speed until the direction of the blower unit 3 changes from the direction D ₄ to the direction D _1. .. By repeating these series of operations, the blower unit 3 reciprocally rotates in the range from the direction D ₁ to the direction D ₉ with the high speed rotation in the non-designated range B ₁ sandwiched. While the blower unit 3 reciprocally rotates in this manner, the axial fan 35 continues to rotate (ie, blows air) without distinction between the designated ranges F ₁ and F ₂ and the non-designated range B ₁ .

On the other hand, in the case of FIG. 19, the control circuit 17 swings the blower unit 3 at a low speed in the forward direction until the direction of the blower unit 3 changes from the direction D ₀ to the direction D _4. The motor 13 is driven. Next, the control circuit 17 drives the swing motor 13 so as to rotate the blower unit 3 in the forward direction at high speed until the direction of the blower unit 3 changes from the direction D ₄ to the direction D _7. To do. Next, the control circuit 17 drives the swinging motor 13 so that the blower unit 3 rotates in the forward direction at a low speed until the direction of the blower unit 3 changes from the direction D ₇ to the direction D _10. To do. Further, the control circuit 17 drives the swinging motor 13 so that the blower unit 3 rotates in the forward direction at high speed until the direction of the blower unit 3 changes from the direction D ₁₀ to the direction D _0. .. By repeating these series of operations, the blower unit 3 rotates in the forward direction while sandwiching the high speed rotation in the non-designated ranges B ₁ and B ₂ . While the blower unit 3 is rotating in this manner, the axial fan 35 continues to rotate (ie, blows air) without distinction between the designated ranges F ₁ and F ₂ and the non-designated ranges B ₁ and B ₂ .

When a plurality of designated ranges are designated, the rotational angular velocity or the rotational angular velocity of the blower unit 3 in the non-designated range is in the designated range regardless of whether the blower unit 3 is rotated in one direction or reciprocally rotated. Rotational angular velocity or faster than rotational angular velocity. Specifically, the rotation angular velocity or the rotation angular velocity in the non-designated range is twice the rotation angular velocity or the rotation angular velocity in the designated range. In this way, the blower unit 3 wants to send the wind by making the rotation angular velocity or the rotation angular velocity of the blower unit 3 in the non-designated range faster than the rotation angular velocity or the rotation angular velocity of the blower unit 3 in the designated range. By shortening the time to look out of the range, you can send the wind focusing on the area you want to send.

The reason why the blower unit 3 is rotated or reciprocally rotated depending on the condition of the designated range is as follows. That is, when the wind is blown in a range wider than 180 degrees, or when the entire circumference is in the designated range, it is possible to install the wind in the center of the room and blow the wind to the entire room. In such a case, the control circuit 17 rotates the blower unit 3 so that the wind is blown in a predetermined direction at equal time intervals. On the other hand, when the wind is blown in the range of 180 degrees or less, it is considered that the fan 3 is placed at a position close to the wall. In such a case, since it is useless to send the wind to the wall, the control circuit 17 causes the blower unit 3 to reciprocally rotate. Further, when the designated range is one and is larger than 180 degrees, the user's intention that the wind is not sent to the non-designated range B can be seen. This is because when there are a plurality of designated ranges, the blower unit 3 always blows air to the non-designated range even for a short time. Therefore, in this case, the control circuit 17 causes the blower unit 3 to reciprocally rotate so that air is blown only in the designated range.

The specified range can be canceled. For example, in FIG. 18, the segment _S 7 to S ₉ for the specified range _{F 2} by pressing and holding the specified range _{F 2} is released, a state of only the specified range _{F 1} is specified FIG. At this time, the segment to be pressed for a long time may be any of S ₇ , S ₈ , and S ₉ . If the direction of the blower unit 3 is within the designated range F ₁ , the control circuit 17 causes the blower unit 3 to reciprocally rotate within the designated range F ₁ as it is. On the other hand, if the direction of the blower unit 3 is outside the designated range F ₁ , the control circuit 17 rotates the blower unit 3 at high speed to the designated range F _{1 and} then reciprocally rotates within the designated range F ₁ . Let By releasing the designated range, the control circuit 17 causes the blower unit 3 to operate as shown in the table below.

As described above, not only is the displacement of the center of gravity of the blower unit 3 from the central axis line A minimized, but the mounting shaft 10 to which the support column 3 is fixed has a vertical distance. By vertically supporting the pair of bearings 8 and 9 provided separately from each other, the blower unit 3 can be stably and smoothly rotated or reciprocally rotated without swaying.

The direction of tracing the operation body 28d of the designating unit 28 and the direction of rotating the blower unit 3 can be matched. That is, when the user traces the designating unit 28 with the finger in the forward direction to designate the blowing range, the control circuit 17 can rotate the blowing unit 3 in the forward direction. On the other hand, the control circuit 17 can rotate the blower unit 3 in the reverse direction by the user designating the ventilation range by tracing the designating unit 28 with the finger in the reverse direction. By doing so, the user can intuitively and easily select the rotation direction of the blower unit 3.

Further, as described above, the direction in which the blower unit 3 is directed is specified by the pulse number of the current supplied to the swing motor 13 which is a stepping motor and the position detection means 12. Then, based on the specified direction, the direction in which the blower unit 3 is facing can be displayed on the range display unit 28b. The display LEDs 28c displayed on the range display unit 28b may be one segment (three) collectively or one by one. There are several possible methods for displaying the direction of the blower unit 3. One is to blink the display LED 28c of the segment corresponding to the direction in which the blower unit 3 is facing. First, in the designated range, among the lit display LEDs 28c, the display LED 28c of the segment corresponding to the direction in which the blower unit 3 is facing is turned off, and in the non-designated range, the turned off display LED 28c. Of these, the display LED 28c of the segment corresponding to the direction in which the blower unit 3 is facing is turned on. One is to use a multicolor LED as the display LED 28c of the range display unit 28b, and to turn on the display LED 28c of a segment corresponding to the direction in which the blower unit 3 faces, with a color different from the color for displaying the designated range. Is. In this manner, by turning on or off the display LED 28c of the range display unit 28b so that the direction in which the blower unit 3 is facing can be seen, the blower unit 3 can be used from a remote position using a remote controller or the like. Since it serves as a guide for the position when determining the direction of, the direction of the blower unit 3 can be easily determined.

When the fan 35 is stopped, the adjusting means 27 that also serves as the power switch 27a is touched and kept pressed for 1 second without tracing. As a result, the fan 35 is stopped and the electric power of the fan 1 is turned off. The setting immediately before the power of the fan 1 is turned off, that is, the direction or the designated range of the blower unit 3 and the air volume are stored in the storage unit of the microcomputer of the control circuit 17, and a power plug (not shown). It will be maintained unless it is unplugged or the power goes out. Then, the power of the electric fan 1 is turned on again by touching and pushing the adjusting means 27 that also serves as the power switch 27a. At this time, the control circuit 17 drives the fan motor 34 and the swing motor 13 based on the setting stored in the storage unit of the microcomputer of the control circuit 17.

As described above, the fan 1 as the air blower of the present invention is provided with the base portion 2 and the blower portion 3 which is provided so as to be rotatable or reciprocally rotatable with respect to the base portion 2 and also provided with the axial fan 35 and the fan motor 34. And a swing motor 13 for rotating or reciprocally rotating the blower unit 3 with respect to the base 2, the swing motor 13 is provided in the base 2, and the swing motor 13 allows The blower unit 3 is rotatable with respect to the base unit 2 by more than 360 degrees, and a mounting shaft 10 as a rotation shaft connected to the blower unit 3 is vertically provided in the base unit 2 and the mounting is performed. The shaft 10 is rotatably supported with respect to the base 2 by a plurality of bearings 8 and 9 which are vertically spaced apart from each other, so that the air blower 3 can be stably and smoothly rotated without swaying. Can be moved.

Further, the fan 1 as the air blower of the present invention serves as a power transmission mechanism that transmits the swing motor 13 and the rotation of the swing motor 13 to the mounting shaft 10 between the plurality of bearings 8 and 9. Since the drive gear 15 and the driven gear 11 are provided, not only the base portion 2 can be downsized, but also the interval between the bearings 8 and 9 can be increased to more stably support the blower portion 3. can do.

Further, the fan 1 as the air blower of the present invention is provided with the slip ring 16 whose movable side is attached to the mounting shaft 10 and whose fixed side is attached to the base portion 2. Even if the rotation is far exceeding 360 degrees, the fan motor 34 can be safely supplied with electric power.

Further, in the fan 1 as the air blower of the present invention, at least a part of the fan motor 34 is inserted into the hub 38 of the axial fan 35 so that the air blower main body 6 of the air blower 3 is moved back and forth. Not only can it be made thinner, but the center of gravity of the blower unit body 6 can be set closer to the central axis A, so that the blower unit 3 can be stably rotated or reciprocally rotated.

Further, in the fan 1 as the air blower of the present invention, the fan motor 34 is located inside the guard 36 that covers the outside of the axial fan 35, so that the air blower main body 6 of the blower unit 3 is moved forward and backward. Not only can it be made thinner, but the center of gravity of the blower unit body 6 can be set closer to the central axis A, so that the blower unit 3 can be stably rotated or reciprocally rotated.

Further, in the fan 1 as the air blower of the present invention, a hinge portion 32 that pivotally supports the axial fan 35 so that the axial fan 35 can be raised and lowered is provided behind the fan motor 34, and the hinge portion 32 corresponds to the blower portion 3. The distance Z from the central axis A that is the rotation center of the blower unit 3 to the rear end of the arm 5 is connected to the arm 5 that projects rearward from the outer surface of the pillar 4 that is the lower end. By being smaller than the distance X from the central axis A to the left and right ends of the guard 36, the radius of rotation when the blower unit 3 rotates or reciprocally rotates is reduced, and the blower unit 3 rotates stably. Alternatively, it can be reciprocally rotated.

The present invention is not limited to the above embodiment, and various modifications can be made within the scope of the gist of the invention. For example, in the above embodiment, the blower is an axial fan fan, but a blower such as a circulator or a tower fan 1a having a blower unit 3a using a cross flow fan as shown in FIG. It may be.

1 Fan (Blower)
2 base 3 blower 8 upper bearing 9 lower bearing 11 driven gear (power transmission mechanism)
13 Swing motor 15 Drive gear (power transmission mechanism)
34 Fan Motor 35 Axial Fan
36 Guard 38 Hub A Center axis

Claims (2)

A base, the blower device comprising a feed air portion that is rotatably or reciprocating rotation, and a swing motor for rotating or reciprocating rotation of the blower with respect to the base portion relative to the base,
The blower unit is configured to include a column unit vertically erected from a base unit, an arm unit provided at an upper end of the column unit, and a blower unit body provided with a fan and a fan motor,
At least a part of the fan motor is inserted into the hub of the fan , the fan motor is positioned inside a guard covering the outside of the fan, and the fan unit main body is located behind the fan motor so that the fan unit can be elevated. A supporting hinge part is provided, the hinge part is connected to the arm part projecting rearward from the outer surface of the lower end part of the blower part, and the center of the fan in the front-rear direction is in a state where the blower direction is horizontal. blower There characterized that you located on the central axis of the strut as a center of rotation of the blower. The distance from the center axis of the blower unit to the rear end of the arm portion, blower according to claim 1, wherein less than the distance from the central axis to the right and left end portions of the guard.

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