JP2017198181A - Air blower - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air blower capable of specifying the current direction of an air blowing part by using less sensors and minimum turn of the air blowing part.SOLUTION: A fan 1 as the air blower includes a base part 2, an air blowing part 3 which is provided rotatably or turnably relative to the base part 2 and in which an axial flow fan 35 and a fan motor 34 are provided, and an oscillating motor 13 for rotating or turning the air blowing part 3 relative to the base part 2. Herein, a control circuit 17 is provided as control means for controlling the oscillating motor 13 on the basis of a signal from position detecting means 12. The position detecting means 12 consists of sensors 19, 20, and a turning body 18 having ON parts and OFF parts for turning on and off the output of the sensors 19, 20. Out of the whole arrangement of the continuous ON and OFF parts of the turning body 18, the arrangement of the two ON and OFF parts are uniquely determined.SELECTED DRAWING: Figure 6

Description

  The present invention relates to an air blower such as an electric fan or a circulator characterized by an operation unit and a display unit.

  Conventionally, as this type of air blower, a base as a base placed on the floor, a post provided above the base, and an air blower provided at the upper end of the post and having a fan for blowing air And a left and right swing mechanism as a moving mechanism for swinging the air blower in the horizontal direction. By switching the operation panel on the top surface of the base, the power can be turned on and off, An electric fan is known that performs on / off switching of a swing mode, selection of a swing angle, and switching of an air volume level from a blower (see, for example, Patent Document 1).

JP 2014-163351 A

  However, in such a blower device, the swing range of the blower unit can be switched to another angle by a push button type switch disposed on the operation panel. Can not intuitively understand the range to blow. In addition, a power switch for switching on / off of the power source and an air volume switch for adjusting the air volume from the air blowing unit are respectively disposed in the operation panel provided on the front side of the base, for example, the side of the air blower main body or It is difficult to push these switches from the rear. In addition, it is difficult to grasp the current operation state from other than the front of the blower.

  An object of the present invention is to solve the above problems, and to improve the operability of a blower that can intuitively specify a range to be blown and can grasp an operation state from all directions.

  The blower device according to claim 1 of the present invention includes a base, a blower provided to be rotatable or rotatable with respect to the base, a fan and a fan motor, and the blower to the base. An air blower having a swing motor to be rotated or rotated has a control means for controlling the swing motor based on a signal from a position detection means, and the position detection means includes a sensor and an output of the sensor. A rotating body having an ON portion and an OFF portion for turning ON or OFF, and a predetermined number of ON portions and OFF portions of the entire ON portion and OFF portion arrangement in the rotating body. Is configured to be uniquely determined.

  By configuring the air blower according to claim 1 of the present invention as described above, it is possible to specify the current direction of the air blower with a small number of sensors and the minimum rotation of the air blower. .

It is a whole front view of the air blower which shows one Embodiment of this invention. It is a partial expanded sectional view of a ventilation part same as the above. It is an enlarged perspective view of a base part. It is a schematic explanatory drawing of the inside of a base part. It is the external appearance figure of the rotary body which comprises a position detection means similarly, (a) is a top view, (b) is a front view, (c) is a bottom view. It is a perspective view of the rotary body which comprises a position detection means equally. It is explanatory drawing of the operation part and display part of a base upper surface similarly. It is explanatory drawing which shows the display state of the display part at the time of a power plug connection similarly. It is explanatory drawing which shows the display state of the display part at the time of a power-on. It is explanatory drawing which shows the display state of the display part at the time of a power-on. It is explanatory drawing which shows the display state of the display part at the time of a power-on. It is explanatory drawing which shows the display state of the display part at the time of a power-on. It is explanatory drawing which shows the display state of the display part at the time of the minimum air volume similarly. It is explanatory drawing which shows the display state of the display part at the time of the maximum air volume similarly. It is explanatory drawing which shows rotation of the ventilation part at the time of designating the direction of a ventilation part. It is explanatory drawing which shows rotation of the ventilation part in case the designated range is one place similarly. It is explanatory drawing which shows rotation of the ventilation part in case a designated range is a perimeter. It is explanatory drawing which shows rotation of a ventilation part in case the range which excludes the maximum non-designated range Bmax is 180 degrees or less, and the designated range is two or more places. It is explanatory drawing which shows rotation of the ventilation part in the case where the range except the maximum non-designated range Bmax is larger than 180 degree | times, and the designated range is the same. It is a whole perspective view of the air blower which shows other embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to FIGS. In the following description, “the direction of the air blowing unit 3” refers to the air blowing direction by the air blowing unit 3. Further, “rotate (or rotate) the air blowing unit 3” is to change the direction of the sending unit 3 and is distinguished from “rotate the axial fan 35 of the air blowing unit 3”. Furthermore, counterclockwise is defined as forward rotation or forward direction, and clockwise is defined as reverse rotation or reverse direction. Reference numeral 1 denotes a fan as a blower of the present invention. The electric fan 1 includes a short cylindrical base 2 and a blower 3 provided on the upper part of the base 2. The blower 3 includes a support column 4 erected vertically from the center of the base 2, an inclined L-shaped arm unit 5 provided at the upper end of the support column 4, and an upper end of the arm unit 5. It has a blower body 6 provided.

  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. Further, the mounting shaft 10 is supported by both 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, position detecting means 12 is provided for detecting which direction the blower 3 is directed. A swinging motor 13 made of 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. Accordingly, the rotation of the swing motor 13 is transmitted to the mounting shaft 10 by a 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. Accordingly, the swing motor 13, the power transmission mechanism including the drive gear 15 and the driven gear 11, the mounting shaft 10, and the upper bearing 8 and the lower bearing 9 are arranged in a compact manner. Can do. On the other hand, the distance 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 hence the blower 3 can be stably supported by the shaft. can do. Further, a slip ring 16 for supplying power is provided below the mounting shaft 10. The movable side of the slip ring 16 is connected to the mounting shaft 10 and can be rotated or rotated 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 denotes a control circuit on which a control unit is mounted. The support column 4 is coaxially fixed to the upper end portion of the mounting shaft 10.

  The position detector 12 will be described in detail. As shown in FIGS. 5 and 6, the position detection unit 12 includes a rotating body 18 fixed to the mounting shaft 10 and sensors 19 and 20 fixed to the base frame. That is, the rotating body 18 is configured to rotate or reciprocate together with the mounting shaft 10, and consequently, the air blowing unit 3 fixed to the mounting shaft 10. The rotating body 18 has a pair of disc-shaped first shielding plate 21 and second shielding plate 22 and a short cylindrical portion 23 for connecting these shielding plates 21 and 22 to each other, and has a bobbin shape as a whole. Composed. Each of the shielding plates 21 and 22 is provided with a plurality of (eight in this example) slits 24 and 25. Note that the slits 24 and 25 are not provided at random, but half of the slits 24 out of the detection points provided at a predetermined angular interval (16 in this example in increments of 22.5 degrees). , 25 are formed. Accordingly, in the first shielding plate 21, the angle formed by one slit 24 and the other slit 24 is a multiple of a predetermined angle (22.5 degrees). The same applies to the second shielding plate 22. On the other hand, the sensors 19 and 20 are each of a type called a photo interrupter. That is, it is composed of a light emitting part and a light receiving part (both not shown). Then, the light emitted from the light emitting unit is received by the light receiving unit 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 portion is blocked by the respective shielding plates 21 and 22 and cannot be received by the light receiving portion, the sensors 19 and 20 do not emit an ON signal. In other words, this state is an off state. That is, in the shielding plates 21 and 22 of the rotating body 18, the position where the slits 24 and 25 are formed is an ON portion, and is a multiple of a predetermined angle (22.5 n degrees: n is an integer) from the slits 24 and 25. The position where the slits 24 and 25 are not formed is the off portion.

  On the upper surface of the base 2, a remote control light receiving window 26, an adjusting unit 27, and a specifying unit 28 are provided concentrically from the center toward the outer periphery so as to surround the support column 4. In the remote control light receiving window 26, a plurality of light receiving elements (not shown) are provided. For this reason, an infrared signal emitted from a 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 unit 27b. The air volume display section 27b has a plurality of (in the case of this example, 24) display LEDs 27c arranged in a ring shape inside. Furthermore, the designation means 28 also serves as a range display portion 28b. The range display portion 28b includes a plurality of (in this example, 16 sets of 3) display LEDs 28c arranged in a ring shape. The adjusting means 27 and the specifying means 28 are operated by pressing them with a finger or tracing them in the length direction. The adjusting means 27 and the specifying means 28 are provided in an annular shape over the entire circumference of the base portion 2. As a result, the air volume can be intuitively adjusted from any direction and the air blowing direction range can be designated. Moreover, since the designation | designated means 28 is provided in the upper surface of the said base 2, since the designated range can be listed, a ventilation range can be designated more easily. Furthermore, 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 designated, it is possible to designate the range of the air blow direction more clearly.

The adjusting means 27 and the specifying 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 designation means 28 also has an annular switch element (not shown) provided in the base 2 and an annular operation body 28d for operating the switch element. Note that these operating bodies 27d and 28d have translucency, and are configured to guide and emit light from the display LEDs 27c and 28c provided in the casing 7 of the base 2 to the outside. . And the said adjustment means 27 is divided | segmented into 24 segments by the circumferential direction on software corresponding to the said display LED27c. 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 corresponding to the display LED 28c. That is, in the designation means 28, one segment is in the range of 22.5 degrees. This is shown in the table below.

In addition, the slits 24 and 25 provided in the rotating body 18 of the position detecting means 12 and the locations where these slits are not provided, that is, the ON portion and the OFF portion correspond to the segments S _{0 to} S _15. Provided. The correspondence relationship between these segments S _{0 to} S ₁₅ and the on and off portions is as shown in the table below.

The slits 24 and 25 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 3 rotates forward from S ₀ to S ₁ , the output of the first sensor 19 is “OFF-OFF” and the output of the second sensor 20 is “ON-ON”. Thus, 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 during forward rotation and the second sensor 20 outputs “ON” for the second time, it is determined that the corresponding segment is currently S _1. Is done. Similarly, when the first sensor 19 outputs “OFF-OFF” and the second sensor 20 outputs “ON-OFF”, when the sensors 19 and 20 output the second time, corresponding segment is identified to be S _2. The same applies to the case where the blower 3 rotates in the reverse direction, and the combination of one segment and the adjacent segment is uniquely determined. The detection result twice by the two sensors 19 and 20 is, in other words, a 4-digit binary number, that is, a decimal number “0 to 15”, and is divided into 16 segments S _{0 to} S ₁₅ . One-to-one correspondence is possible. If the number of segment divisions exceeds 16, it cannot be represented by a 4-digit binary number, so it can be handled by moving by three segments or increasing the number of sensors. The binary numbers in the 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 a small number of sensors 19 and 20 and the minimum rotation of the blower unit 3.

  The support column 4 is formed in a hollow cylindrical shape. The lower end portion of the support column 4 is fixed to the upper end portion of the mounting shaft 10 coaxially with the mounting shaft 10. The arm portion 5 includes a retreating portion 29, a bending portion 30, and a standing portion 31. The retreating portion 29 is formed to extend rearward and obliquely upward. Further, the upright portion 31 is formed to extend obliquely forward and upward. In addition, the said bending part 30 and the standing part 31 are provided in left-right pair. An electric wiring (not shown) is passed through the support column 4 and the arm portion 5. Further, the blower body 6 is provided at the upper end portion of the upright portion 31 of the arm portion 5. The blower 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 part 32 has a swing mechanism (not shown) and is provided so that a manual tilting operation is possible with respect to the arm part 5. In this example, the hinge part 32 allows the blower body 6 to be tilted in a range from 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. The fan motor 34 is entirely provided in the motor casing 33 except for a rotating shaft 34 a protruding forward of the motor casing 33. 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 slightly larger than the outer diameter of the small diameter portion 37. For this reason, when the axial fan 35 is attached to the rotary shaft 34 a, the small diameter portion 37 enters the hub 38. Accordingly, a part of the fan motor 34 is located in 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. Accordingly, the fan motor 34 is located in the guard 36. Furthermore, the front-rear direction center of the guard 36 and thus the axial fan 35 disposed in the guard 36 is located on the central axis A in a state where the air blowing direction is horizontal as shown in FIG. As described above, a part of the fan motor 34 is located in the hub 38, and the entire fan motor 34 is located in the guard, and the hinge portion 32 provided behind the guard 36. The projecting dimension of the blower body 6 can be minimized, so that the blower body 6 can be thinned back and forth, and the center of gravity of the blower body 6 is close to the central axis A. Further, the distance Z from the central axis A of the support 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 can the deviation from the central axis A of the center of gravity of the air blowing unit 3 as a whole be minimized, but a fan with a general structure in which the guard is in front of the support and the guard from the left and right Compared with the structure of the supporting fan, the rotation radius of the blower main body 6 can be reduced, and the blower 3 can be stably rotated or reciprocated. Further, the radius R of the base 2 is smaller than the distance X described above. Therefore, when the air blower 3 is rotated, all elements of the electric fan 1 except for the power cord (not shown) are located inside the locus 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 a 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 in a dark manner. At the same time, the control circuit 17 operates the swing motor 13 to rotate the air blowing unit 3 in the forward direction, and the position detecting unit 12 specifies the direction in which the air blowing unit 3 is facing. That is, when the first sensor 19 outputs “OFF-OFF” and the second sensor 20 outputs “ON-ON”, when the sensors 19 and 20 output a second time, part 3 is identified that are oriented D _1. Similarly, when the first sensor 19 outputs “OFF-OFF” and the second sensor 20 outputs “ON-OFF”, when the sensors 19 and 20 output a second time, part 3 is identified that are oriented D _2. The control circuit 17 stops driving the swing motor 13 and stores the current direction of the blower 3 when the direction of the blower 3 is specified.

  In addition, you may make it perform such operation | movement for pinpointing the direction of the said ventilation part 3 when a power supply is turned ON. Further, in order to specify the direction of the blower unit 3, the blower unit 3 is rotated in the forward direction by two segments, and then the blower unit 3 is kept in that position in the reverse direction by two segments. You may make it rotate and return.

Next, the electric power of the electric fan 1 is turned on by touching and lightly pressing the adjusting means 27 also serving as the power switch 27a. The power switch 27a / adjusting means 27 may be pressed anywhere on the annular operating body 27d. When the electric power of the electric fan 1 is turned on, the control circuit 17 ends the dark blinking of the air volume display unit 27b, turns on the display LED 27c with the air volume display of the initial setting value, and causes the fan motor 24 to turn on. By supplying 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. The set air volume is expressed by the number of lighting of the display LED 27c. The number of display LEDs 27c to be lit 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 lighting of the display LED 27c of the air volume display section 27b is 4. On the other hand, at the time of the maximum air volume, as shown in FIG. 14, the number of lighting of the display LED 27c of the air volume display section 27b is 22. Since these display LEDs 27c are arranged in an annular shape, the number of lighting of these display LEDs 27c is the length of an arc. The display LED 27c that is lit rotates in the forward direction while maintaining the number, that is, while maintaining the length of the arc, unless the air volume is changed. For example, when the air volume is the initial set value, the number of display LEDs 27c that are lit is 12. Among these lit display LEDs 27c, the forward rear end display LED 27c is turned off, and at the same time, the display LED 27c adjacent to the front forward end display LED 27c is turned on. By repeating this, as shown in FIGS. 9 to 12, the light emission display of the air volume display unit 27 b rotates in the forward direction.

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

  Power is supplied from the control circuit 17 to the fan motor 34 through the slip ring 16 and lead wires (not shown) that are passed through the support column 4 and the arm portion 5. In this way, power is supplied from the control circuit 17 of the base 3 to the fan motor 34 of the blower 3 via the slip ring 16, so that the blower 3 is 360 with respect to the base 2. Even if the rotation is much higher than that, power can be safely supplied from the control circuit 17 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. Note that the child lock state can also be obtained by pressing the power switch 27a for a special operation, for example, three times. In the child lock state, the operation of the main body of the electric fan 1 can only be turned off by the operation of the power switch 27a / adjusting means 27 except for a special operation for releasing the child lock. The child lock state is released by a special operation of the child lock button on the remote controller or 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 in which the operating body 27d of the adjusting means 27 is traced with a finger. More specifically, the control circuit 17 determines whether the finger is traced in the forward direction or the reverse direction in the two segments touched first among the 24 segments of the adjusting means 27. That is, it is determined whether the first touched segment and the next touched segment are in a forward or 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 so as to increase the air volume. Conversely, when it is determined that the operating body 27d is traced in the reverse direction, the control circuit 17 controls the fan motor 34 so as to reduce the air volume. Then, after the first direction determination, it is detected how many segments have been traced. In the case of this example, the air volume setting is changed by one step per finger movement for one segment. In the case of this example, the second segment touched for direction detection is set as one stage of air volume setting. For example, a case where the minimum air volume state is changed 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 with a finger at an angle of 150 degrees for 10 segments. The breakdown uses 2 segments to detect the direction of finger tracing and for the first increase in airflow, and 8 segments for the remaining 8 airflow increases. Even if the finger exceeds 10 segments (150 degrees), the control circuit 17 ignores the 11th and subsequent segments. Further, for example, when the current air volume is the fifth stage and the air volume is increased to the maximum air volume, the control circuit 17 ignores the portion exceeding 6 segments (90 degrees). The same applies when operating to reduce the air volume.

  When the operating body 27d is traced with a finger for air volume adjustment, the starting point may be anywhere on the annular operating body 27d. That is, the air volume can be adjusted as long as it is determined that the finger is traced and the distance is traced. Therefore, the air volume can be adjusted in the same manner and intuitively from any direction of the electric fan 1. Further, in this example, the air volume can be adjusted by the distance in which the operating body 27d is traced with the finger. However, the air volume can be adjusted by the number of times in which the operating body 27d is traced with the finger. May be.

The case where the direction of the said ventilation part 3 is changed is demonstrated. The direction in which the air blowing unit 3 is directed is specified by the directing means 28 and the method in which the rotation or rotation is stopped during the rotation or rotation of the air blowing unit 3, from D ₀ to D _15. Either of these can be selected. And even if it designates with either of those methods, the direction which the said ventilation part 3 faces is specified. In the former method, since it is directly specified by the specifying means 28, it is obvious. In the latter method, since the air blowing unit 3 is driven by the swing motor 13 which is a stepping motor, it can be specified. That is, it was necessary when the air blower was rotated or rotated from the reference position to the current position, and the number of pulses N to be supplied to the swing motor 13 in order to move the air blower 3 by an angle corresponding to one segment. It can be specified from the number of pulses (however, the number of pulses when rotating or rotating in the forward direction is positive, and the number of pulses when rotating or rotating in the reverse direction is negative). For example, from a state where the blower 3 is oriented D ₃ corresponding to the end portion of the swinging range, after the pulse of 3N in the forward direction is supplied to the swing motor 13, the blower unit 3 times When stopping the motion, the direction in which the air blowing portion 3 is oriented, compared first direction D _{3 (segment} S _3), the corresponding direction D ₆ segments S ₆ is a position moved in the forward direction 3 segment content It is specified that there is. When the direction of the air blowing unit 3 is changed, information on the current direction of the air blowing unit 3 is stored in a storage unit of a microcomputer (not shown) of the control circuit 17. In this way, it is specified and stored which of D ₀ to D ₁₅ is the direction in which the blower 3 is facing. The direction of the blower 3 is controlled by the number of pulses of the current supplied to the swing motor 13, but is corrected by the position detection means 12. As described above, the rotation or rotation of the air blowing unit 3 can be accurately controlled by being corrected by the position detection unit 12.

A method for directly specifying the direction of the blower 3 by the specifying means 28 will be described in more detail. In a state where the blower unit 3 is not rotated or rotated, the user touches an arbitrary position on the operation body 28d of the annular designating means 28 and presses it lightly. As described above, since the segment of the designation means 28 is directly designated, the segment serving as the target position is specified. Further, since the current direction of the air blowing unit 3 is stored in a storage unit of a microcomputer (not shown), the segment that is the current position is also specified. Then, the control circuit 17 calculates whether the angle formed by the starting segment and the target segment with the central axis A as the center is smaller in forward rotation or reverse rotation, and swings the head around the smaller angle. By driving the motor 13, the air blowing unit 3 is rotated. For example, as shown in FIG. 15, when the starting segment corresponding to the current direction D ₀ of the air blowing unit 3 is S ₀ and S ₇ is designated as the target segment, the air blowing unit 3 is moved in the reverse direction by 202. Instead of rotating 5 degrees, it is rotated 157.5 degrees in the forward direction. In addition, when the target segment is opposite to the starting segment, the air blowing unit 3 may be rotated in either direction, but in this example, the air blowing unit when the rotation or rotation is finally stopped. The rotation or rotation direction of 3 is stored and this direction is adopted.

  In this way, when the direction of the blower 3 is specified, the angle between the forward rotation and the reverse rotation is calculated based on the relationship between the start segment and the target segment, and the angle is small. By rotating the air blower 3 around the angle, that is, the angle distance between the starting segment and the target segment becomes smaller, the air blower 3 can be directed in a desired direction in a short time, and the air blower It is possible to reduce useless electric power when rotating 3.

  In addition, the rotation angular velocity at the time of rotating the said ventilation part 3 to the designated direction is quicker than the rotation angular velocity at the time of ventilation mentioned later or a rotation angular velocity. However, as described above, not only the deviation from the central axis A of the center of gravity of the air blowing unit 3 as a whole is 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 at a distance, the air blowing section 3 can be stably and smoothly rotated without being fluctuated.

The case where air is blown while rotating or rotating the blower 3 will be described. The user can specify the air blowing range by the air blowing unit 3 by tracing the designating means 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 lit, the range of 67.5 degrees corresponding to the direction _{D 1} to the direction _{D 4} is one of the specified range _{F 1.} In this manner, the air blowing range can be specified intuitively by tracing the operating body 28d of the specifying means 28 formed in an annular shape around the support column 4 with a finger. Range is specified in, if the direction of the air blowing portion 3 is within the range of the specified range F _1, the control circuit 17, the blower 3, reciprocally rotated between it from the direction D ₁ of the D _4. On the other hand, when the range specification, if the direction of the air blowing portion 3 to the outside of the designated range F _1, the control circuit 17, the blower unit to the direction of the air blowing portion 3 becomes the direction D ₁ or D ₄ 3 is rotated and then reciprocated between directions D ₁ to D ₄ . The rotational angular velocity of the blower unit 3 when the blower unit 3 is pivoted from the initial direction to the direction D ₁ or D ₄ is the blower unit 3 when reciprocatingly pivoting between the directions D ₁ to D _4. It is faster than the rotational angular velocity. Thus, if the specified range F ₁ of 15 or less segments content is specified only one, the control circuit 17 reciprocally rotate the blower 3. Incidentally, as shown in FIG. 17, when one of the specified range F ₁ is specified over 16 segment content (i.e. the whole circumference), the control circuit 17 rotates the blower 3 in the forward direction.

A plurality of air blowing ranges can be designated. For example, as shown in FIG. 18, after designating the designated range F ₁ by tracing the segments S ₁ to S ₄ of the designating unit 28 with a finger, the segments S ₇ to S _{9 of} the designating unit 28 are traced with the finger. it is possible to specify the specified range F ₂ Te. 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 occur between the designated ranges F ₁ and F ₂ , respectively. 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} .

And the said control circuit 17 rotates or rotates the said ventilation part 3 according to the conditions of the designated ventilation range. Specifically, when there are a plurality of designated ranges and 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 larger than 180 degrees, the control circuit 17 The part 3 is rotated. On the other hand, when there are a plurality of designated ranges and 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 3. Rotate. In the case of FIG. 18, comparing the non-designated ranges B ₁ and B ₂ , B ₁ is 67.5 degrees and B ₂ is 180 degrees, so B ₂ = Bmax, and 180 degrees is subtracted from 360 degrees. Since the value is 180 degrees, the control circuit 17 reciprocates the air blowing 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 , 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 section 3. When organized, it looks like a table.

In the case of FIG. 18, the control circuit 17 causes the swing motor 13 to rotate the blower 3 in the forward direction at a low speed until the direction of the blower 3 changes from the direction D ₁ to the direction D _4. Drive. Next, the control circuit 17, the up direction of the blower unit 3 is made from a direction D ₄ in the direction D _7, the blower unit 3 so as to rotate in the forward direction at a high speed, driving the swing motor 13 To do. Next, the control circuit 17 drives the swing motor 13 so that the air blowing unit 3 rotates in the forward direction at a low speed until the direction of the air blowing unit 3 changes from the direction D ₇ to the direction D _9. To do. Next, the control circuit 17, the up direction of the blower unit 3 is in the direction D ₇ from the direction D _9, as the blower unit 3 is rotated in the reverse direction at a low speed, driving the swing motor 13 To do. Next, the control circuit 17, the up direction of the blower unit 3 is made from a direction D ₇ in the direction D _4, as the blower unit 3 is rotated in the reverse direction at a high speed, driving the swing motor 13 To do. Furthermore, the control circuit 17, the direction of the blower unit 3 from the direction D ₄ until the direction D _1, the blower unit 3 so as to rotate in the reverse direction at a low speed, driving the swing motor 13 . By repeating the series of operations, the blower unit 3 across the high-speed rotation in a non-specified range B _1, reciprocally rotates in a range of directions D ₉ from the direction D _1. In addition, while the air blower 3 is reciprocatingly rotated in this manner, the axial fan 35 continues to rotate (that is, blow) 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 swinging unit 3 so as to rotate the blowing unit 3 in the forward direction at a low speed until the direction of the blowing unit 3 changes from the direction D ₀ to the direction D _4. The motor 13 is driven. Next, the control circuit 17, the up direction of the blower unit 3 is made from a direction D ₄ in the direction D _7, the blower unit 3 so as to rotate in the forward direction at a high speed, driving the swing motor 13 To do. Next, the control circuit 17, the up direction of the blower unit 3 is in the direction D ₁₀ in the direction D _7, as the blower unit 3 is rotated in the forward direction at a low speed, driving the swing motor 13 To do. Furthermore, the control circuit 17, the direction of the blower unit 3 from the direction D ₁₀ until the direction D _0, the blower unit 3 so as to rotate in the forward direction at a high speed, driving the swing motor 13 . By repeating the series of operations, the blower unit 3 across the high-speed rotation in a non-specified range B ₁ and B _2, rotating in the forward direction. In addition, while the air blower 3 rotates in this way, the axial fan 35 continues to rotate (that is, blow) 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 the designated range regardless of whether the blower unit 3 is rotated in one direction or reciprocally rotated. It is faster than the rotational angular velocity or the rotational angular velocity. Specifically, the rotational angular velocity or the rotational angular velocity in the non-designated range is twice the rotational angular velocity or the rotational angular velocity in the designated range. Thus, the air blowing unit 3 wants to send wind by making the rotation angular velocity or the rotation angular velocity of the air blowing unit 3 in the non-designated range faster than the rotation angular velocity or the rotation angular velocity of the air blowing unit 3 in the designated range. You can shorten the time you are heading outside the range and send the wind to the range you want to send.

  The reason for switching between rotating or reciprocating rotation of the air blowing unit 3 according to the conditions of the specified range is as follows. In other words, when the wind is sent over a range wider than 180 degrees, or when the entire circumference is within the specified range, it can be considered that the wind is sent to the entire room by being installed at the center of the room. In such a case, the control circuit 17 rotates the blower unit 3 so that the wind is sent at regular intervals in a predetermined direction. On the other hand, when the wind is sent to a range of 180 degrees or less, it is conceivable that the electric 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 reciprocates the air blowing unit 3. In addition, when the designated range is one and larger than 180 degrees, the user's intention that the user does not want to send wind to the non-designated range B is seen. This is because, when there are a plurality of designated ranges, the air blowing unit 3 always blows air to the non-designated range even for a short time. Therefore, in this case, the control circuit 17 reciprocates the air blowing unit 3 so that air is blown only in the specified 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 long-pressed segment may be any of S ₇ , S ₈ , and S ₉ . Incidentally, if the direction of the air blowing portion 3 is within the specified range F _1, the control circuit 17 reciprocally rotate within it specified range F ₁ of the blower unit 3. On the other hand, if the direction of the blower unit 3 is in the specified range F ₁ outside, after the control circuit 17 is pivoted to a specified range F ₁ of the blower unit 3 at high speed, reciprocating rotation within a specified range F ₁ Let In addition, the said control circuit 17 operates the said ventilation part 3 as the following table by canceling | releasing the designated range.

  As described above, not only the deviation from the center axis A of the center of gravity of the air blowing unit 3 as a whole is minimized, but also the mounting shaft 10 to which the support column 3 is fixed has a vertical distance. By being pivotally supported vertically by the pair of bearings 8 and 9 provided at a distance, the air blowing unit 3 can be stably or smoothly rotated or reciprocated without fluttering.

  It should be noted that the direction of tracing the operating body 28d of the designation means 28 can be made to coincide with the direction of rotating the blower unit 3. That is, the control circuit 17 can rotate the blowing unit 3 in the forward direction by the user specifying the blowing range by tracing the designation means 28 with a finger 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 specifying the blower range by tracing the designation means 28 with the finger in the reverse direction. By doing in this way, the user can select the rotation direction of the said ventilation part 3 intuitively and easily.

  Further, as described above, the direction in which the blower unit 3 faces is specified by the number of pulses of the current supplied to the swing motor 13 that is a stepping motor and the position detection unit 12. And based on the specified direction, the direction which the said ventilation part 3 faces can be displayed on the said range display part 28b. The display LEDs 28c to be displayed on the range display unit 28b may be one segment (three) or may be one by one. Several methods for displaying the direction of the blower 3 are conceivable. One is to blink the display LED 28c of the segment corresponding to the direction in which the blower 3 is facing. One of the display LEDs 28c that are lit in the designated range is to turn off the display LEDs 28c of the segment corresponding to the direction in which the blower 3 is facing, and the display LED 28c that is turned off in the non-designated range. Among them, the display LED 28c of the segment corresponding to the direction in which the air blowing unit 3 faces is turned on. First, the display LED 28c of the range display unit 28b is a multicolor LED, and the display LED 28c of the segment corresponding to the direction in which the blower unit 3 is facing is turned on with a color different from the color for displaying the designated range. It is. In this way, by turning on or blinking the display LED 28c of the range display section 28b so that the direction in which the blower section 3 is facing can be understood, the blower section 3 can be separated from a position using a remote controller or the like. When determining the direction, the position is a guide, so the direction of the blower 3 can be easily determined.

  When stopping the fan 35, 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 electric fan 1 is turned off. The setting immediately before turning off the electric power of the fan 1, that is, the direction or designated range of the air blowing unit 3 and the air volume are stored in the memory unit of the microcomputer of the control circuit 17, and the power plug (not shown) It is maintained as long as it is not removed or a power failure occurs. Then, the electric power of the electric fan 1 is turned on again by touching and pressing the adjusting means 27 also serving 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 settings stored in the storage unit of the microcomputer of the control circuit 17.

  As described above, the electric fan 1 as the air blower of the present invention includes the base 2 and the air blower 3 provided to be rotatable or rotatable with respect to the base 2 and provided with the axial fan 35 and the fan motor 34. In the electric fan 1 having the swing motor 13 for rotating or rotating the air blowing unit 3 with respect to the base 2, the air blowing unit 3 can rotate more than 360 degrees with respect to the base 2, and the base 2 In addition, designation means 28 for designating the blowing direction of the blowing section 3 is provided, and the blowing section is forwardly moved from the current direction of the blowing section 3 to the direction of the blowing section 3 designated by the designation means 28. As a control means for controlling the operation of the swing motor 13 so as to rotate the air blowing unit 3 in a direction in which the angle is reduced in comparison with the case where the air blower 3 is rotated in the opposite direction. Control circuit By 7 is provided not only be a short time directing the blower 3 in a desired direction, in which it is possible to reduce unnecessary power when rotating the blower 3.

  Moreover, the electric fan 1 as the air blower according to the present invention can intuitively specify the air blowing direction by the air blowing unit 3 by providing the designating unit 28 in an annular shape over the entire circumference of the base 2. In addition to being able to do this, it is possible to specify the blowing direction from any direction, and to reduce the time and power for directing the blowing unit 3 in the specified direction.

  Moreover, the electric fan 1 as the air blower of the present invention is provided with a base 2, a blower 3 provided so as to be rotatable or rotatable with respect to the base 2, and provided with an axial fan 35 and a fan motor 34. In the electric fan 1 having the swing motor 13 for rotating or rotating the blower 3 with respect to the base 2, a control circuit 17 as a control means for controlling the swing motor 13 based on a signal from the position detection means 12. The position detection means 12 includes sensors 19 and 20 and a rotating body 18 having an on portion and an off portion for turning on or off the outputs of the sensors 19 and 20. By configuring so that the arrangement of the two on-parts and the off-parts in the entire arrangement of the continuous on-parts and off-parts in the rotating body 18 is uniquely determined, the number of sensors 19, 20 One with minimal rotation of the blower unit 3, the current direction of the blower unit 3 can be identified.

  Furthermore, the electric fan 1 as the air blower of the present invention has a base portion 2 and a blower portion 3 provided with an axial fan 35 and a fan motor 34, and the base portion 2 has adjusting means for adjusting the air volume. 27 and an air volume display section 27b for displaying the air volume adjusted by the adjusting means 27, the air volume display section 27b is provided annularly and set over the entire circumference of the base 2. By providing a control circuit 17 as a control means for controlling the number of display LEDs 27c as a display element in the air volume display section 27b based on the air volume and controlling the display LEDs 27c to rotate in the circumferential direction. Since the display makes a round of the air volume display portion 27b at a predetermined time, the air volume display can be viewed from all directions without distinction of the front, rear, left and right of the fan 1. Can.

  In addition, this invention is not limited to the above embodiment, A various deformation | transformation implementation is possible within the range of the summary of invention. For example, in the above-described embodiment, the adjusting means is provided on the inner side and the specifying means is provided on the outer side. In short, since these may be arranged concentrically, the adjusting means is on the outer side and the specifying means is on the inner side. Good. In the above embodiment, the adjustment means is divided into 24 segments and the designation means is divided into 16 segments in terms of software. However, the number of divisions may be larger than this. Furthermore, in the said embodiment, although the air blower was made into the axial flow fan type electric fan, it is a tower type electric fan 1a which has the air blower 3a using the air blowers, such as a circulator, or a crossflow fan as shown in FIG. There may be.

1 Fan (Blower)
2 base 3 blower 12 position detection means 13 swing motor 17 control circuit (control part)
18 Rotating body 19, 20 Sensor 21 First shielding plate 22 Second shielding plate 23 Short cylindrical portion 24, 25 Slit (ON portion)
27 Adjusting means 27b Air volume display section 27c Display LED (display element)
28 Designating means 28b Range display section 28c Display LED
34 Fan motor 35 Axial fan (fan)

Claims (1)

A blower having a base, a blower provided to be rotatable or rotatable with respect to the base, and provided with a fan and a fan motor, and a swing motor for rotating or turning the blower with respect to the base. In
The rotating body includes a control unit that controls the swing motor based on a signal from a position detection unit, and the position detection unit includes a sensor and an on portion and an off portion that turn on or off the output of the sensor. The air blower is characterized in that a predetermined number of on- and off-portion arrangements are uniquely determined in the entire arrangement of continuous on- and off-portions in the rotating body. apparatus.

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