JP6072579B2 - Blower - Google Patents

Description

  The present invention relates to a structure of an air blower provided with an ion generator.

  Various effects of sterilizing bacteria on ions and physiological effects on the human body have been reported, and many air conditioners and blowers equipped with ion generators are on the market. For example, Patent Document 1 discloses a structure in which an ion generator is provided in a base portion for storing a swing mechanism in a fan including a swing device.

  Patent Document 2 discloses a fan in which a small room for storing an ion generator is provided on the upper part of a casing that houses a fan drive motor. An opening is arranged in the front-rear direction of the small room, the air sent by the fan is guided into the small room, and ions are sent together with the air current.

JP 2003-293984 A JP-A-2005-240556

  The fan is used indoors, but it is unexpectedly easy to collect dust on the fan guard to ensure the safety of the fan and the user. It is often necessary for the person to clean. For this reason, recent fans have a structure in which the front side of the guard part can be easily removed, and not only the structure in which the fan is exposed when the guard is removed, but also the fan itself can be easily removed. So you can easily clean guards and fans.

  The electric fan equipped with the above-mentioned ion generator basically has the same structure, and the ion generator can be easily cleaned even though the fan and guard can be easily cleaned. It is not.

  This is because the ion generation device generates ions by applying a high voltage of several kV (kilovolts) between the discharge electrode and the counter electrode to generate ions, giving priority to safety. The structure is such that it cannot be easily touched by the householder. Despite the fact that dust often adheres to the fan or guard and feels the need for cleaning, even if dust adheres to the ion generator, it cannot be cleaned.

  This invention is made | formed in view of such a situation, and it aims at providing the air blower which can be easily cleaned as needed, mounting an ion generator safely.

An air blower according to the present invention includes a motor, a fan attached to an output shaft of the motor, an ion generator, and a casing that accommodates these, and is configured so that a front portion of the casing can be removed, and the ion generator. a casing for housing the can, outlet for delivering ions are provided from gaps between a plurality of blades and vanes provided in the fan, characterized by Rukoto visible ion-emitting portion of the ion generating device .

In the present invention, the outlet provided in the casing that houses the ion generator is located above the motor and behind the fan .

  Moreover, in this invention, the ion generation part of an ion generator can be visually recognized from the ion delivery opening provided in the casing.

  Further, the present invention is characterized in that the needle-like discharge electrode of the ion generator is installed so as to coincide with the air flow delivery direction.

According to the present invention, since the ion generating device is provided inside the casing in which the fan motor is stored, the ion generating device is not exposed unnecessarily, and it is safe and space saving can be achieved.
Moreover, according to this invention, the ion emission part of an ion generator can be easily cleaned as needed.

It is a front view of the air blower which concerns on this Embodiment. It is a side view of the air blower concerning this embodiment. It is sectional drawing in the III-III line in FIG. FIG. 4 is a partially enlarged view of FIG. 3. It is an external appearance schematic diagram of the ion generator which concerns on this Embodiment. It is a block diagram which shows the structure of the control system of the air blower which concerns on this Embodiment. It is a perspective view which shows the position of the ion delivery opening of the air blower which concerns on this Embodiment.

  Hereinafter, the present invention will be specifically described with reference to the drawings showing embodiments thereof. 1 is an external front view of a blower device 1 according to the present embodiment, FIG. 2 is a side view thereof, FIG. 3 is a cross-sectional view taken along line III-III in FIG. 1, and FIG. FIG. The blower device 1 according to the present embodiment is configured as a floor-standing fan. 1-4, the attitude | position from which the ventilation direction by the air blower 1 becomes a horizontal direction is shown.

  The blower 1 includes a stand 14 placed on the floor, and a casing 20 that is rotatably supported by the stand 14. The stand 14 is provided on a pedestal portion 141 that is formed in a circular shape in plan view, a support column 142 that is erected vertically from the rear side from the center of the pedestal component 141, and an upper side of the support column 142. And a casing 20 in which the fan motor 12 is accommodated, and a casing support portion 143 that rotatably supports the casing 20. The casing 20 houses a fan motor 12 that drives the fan 11 for generating an air flow, a swing mechanism portion 30 that enables the casing 20 to swing in the vertical direction, and the like.

  The central portion of the casing 20 has a rotating shaft 10 for allowing the casing 20 to swing vertically, and the casing support portion 143 has a pair of left and right shafts that support the rotating shaft 10. A bearing portion is provided. In the casing 20, a swing mechanism unit 30 including a swing motor 31 is provided, and a driving force by the swing motor 31 is transmitted to the rotary shaft 10 through a plurality of gears such as a reduction gear 32. By rotating the casing 20 around the rotation shaft 10, the casing 20 is swung in the vertical direction, and the blowing direction by the fan 11 is changed in the vertical direction.

  The casing support part 143 is configured to be movable in the vertical direction with respect to the support column part 142. By operating a button 143 a provided on the support column part 142, the casing support part 143 is moved up and down, and the casing 20 It is configured so that the height can be set. Moreover, the casing support part 143 is pivotally supported by the support | pillar part 142 so that rotation in the left-right direction is possible. Thus, the casing 20 can be swung in the left-right direction, and the blowing direction by the fan 11 can be changed in the left-right direction. The blower device 1 includes a motor 143b for rotating the casing support part 143 around the axial direction of the support column 142 at the lower part of the casing support part 143 in order to automatically swing the left and right direction. .

  The fan 11 of the blower 1 includes, for example, three blade members, and is attached to the output shaft 121 of the fan motor 12 with a fixture 11b. The fan 11 is driven by the fan motor 12 to rotate in a predetermined direction, for example, clockwise when viewed from the front, and generate an air flow on the side opposite to the fan motor 12. That is, in the side view shown in FIG. 2, the air flow generated by the fan 11 is configured to be sent to the left side of the fan 11. Hereinafter, the downstream side in the blowing direction is the front side of the casing 20, and the upstream side in the blowing direction is the rear side of the casing 20.

  The casing 20 includes a motor housing portion 21 in which the fan motor 12 and the vertical swing mechanism portion 30 are provided, a fan guard portion 22 that covers the outer periphery and the rear of the fan 11, and a front guard portion 23 that covers the front of the fan 11. Is done. The motor housing portion 21 and the fan guard portion 22 are integrally formed, and the front guard portion 23 is detachably attached to the fan guard portion 22.

  The motor housing portion 21 includes a first housing portion 211 that houses the fan motor 12 and a second housing portion 212 that houses the swing mechanism portion 30. In addition, the blower device 1 according to the present embodiment includes an ion generation device 40, and the motor housing portion 21 accommodates the ion generation device 40 in addition to the first accommodation portion 211 and the second accommodation portion 212. The 3rd accommodating part 213 for doing is provided.

  The first accommodating portion 211 is provided in the vicinity of the front center of the motor housing portion 21 and includes an opening 211 a that projects the output shaft 121 of the fan motor 12 toward the fan guard portion 22. The fan motor 12 is fixed in the first housing portion 211 with the output shaft 121 protruding forward from the opening 211a.

  The second housing part 212 is provided in the vicinity of the center on the rear side of the motor housing part 21 and behind the first housing part 211, and houses the swing mechanism part 30 that rotates the casing 20 in the vertical direction. In the present invention, the rotating shaft 10 of the casing 20 is disposed at a position separated from the fan motor 12 on the side opposite to the fan 11 mounting side, that is, behind the fan motor 12.

  The third accommodating portion 213 is provided on the front upper side of the motor housing portion 21 and on the upper side of the first accommodating portion 211, and accommodates the ion generator 40 therein. The front wall of the third housing portion 213 is integral with the front wall 21 a of the motor housing portion 21. The rear side of the third housing portion 213 is closed so that no objects can enter, and a space is formed between the motor housing portion 21 and the portion 21b that extends rearward in an eave-like shape. It is a gripping part for carrying. In addition, an ion outlet 213a for sending out ions generated by the ion generator 40 is provided on the front wall of the third housing portion 213.

  The fan guard part 22 has a circular opening edge 221 in front view on the front side, and the front guard part 23 is detachably attached through the opening edge 221. Further, the motor housing portion 21 described above is integrally formed on the rear side of the fan guard portion 22. A slit 222 is provided in the outer peripheral part and the rear part of the fan guard part 22, and when the fan 11 is driven, air outside the apparatus is taken into the fan guard part 22 through the slit 222, and the air is generated by the rotation of the fan 11. It is configured to generate a flow.

  The front guard portion 23 is formed in a circular shape when viewed from the front, and includes a large number of wind-cutting members 231, 231, 231,... Provided radially from the center, as shown in FIG. The blower device 1 is configured to change the direction of the wind to be diffused forward and outward by the fan 11 by the wind-cutting member 231 provided in the front guard portion 23 to improve the straightness in the blowing direction.

  The front guard portion 23 has an opening edge portion having an outer diameter that is slightly larger than the outer diameter of the opening edge portion 221 of the fan guard portion 22. A plurality of locking grooves are formed in the circumferential direction on the inner peripheral surface of the opening edge. Further, the same number of locking projections as the locking grooves are formed on the opening edge portion 221 on the front side of the fan guard portion 22. The user aligns the locking groove on the front guard part 23 side with the locking projection on the fan guard part 22 side, and the locking groove on the front guard part 23 side becomes the locking protrusion on the fan guard part 22 side. Inserting and rotating the front guard portion 23 in the circumferential direction engages both to attach the front guard portion 23 to the fan guard portion 22.

  Further, the front guard portion 23 has a partition wall 233 having a diameter smaller than the inner diameter of the outer peripheral surface of the front guard portion 23, and the partition wall 233 is provided in an annular shape so as to face the outer peripheral surface. As shown in FIG. 1, the inner diameter of the partition wall 233 is configured to be larger than the outer diameter of the fan 11. The air flow generated by the rotation of the fan 11 passes through the inside of the partition wall 233 and is sent out of the blower 1.

  On the other hand, an annular gap formed by the fitting portion of the front guard portion 23 and the partition wall 233 is an opening through which air flows from the outside of the blower 1 to the inside of the casing 20. In other words, in the present embodiment, the air flow in the downstream direction by the fan 11 and the air flow in the upstream direction flowing from the outside of the apparatus are separated by the partition wall 233. Thereby, since interference between the air flow flowing from the outside of the apparatus and the air flow in the downstream direction by the fan 11 is reduced, the air flow by the fan 11 is weakened or the straightness in the air blowing direction is reduced. It is avoided.

  FIG. 5 is an external perspective view showing the shape of the ion generator 40 used in the present invention. The ion generator 40 includes a housing 40a and ion generators 40b and 40c. The housing 40a stores a drive circuit that receives power supply from the outside and generates high-voltage electricity to be supplied to the ion generators 40b and 40c. The ion generators 40b and 40c basically have the same structure, and the needle-like discharge electrodes 401b and 401c at the center and the counter electrode 402b formed by a perforated flat plate arranged so as to surround the needle-shaped discharge electrodes 401b and 401c, 402c and a substrate that supports them.

  In the ion generators 40b and 40c to which high-voltage electricity is applied by the drive circuit, discharge occurs from the tips of the discharge electrodes 401b and 401c toward the counter electrodes 402b and 402c, and gas molecules in the air are ionized to generate various ions. Occur. In the ion generator 40 used in the present invention, the tips of the discharge electrodes 401b and 401c are arranged so as not to protrude from the surfaces of the counter electrodes 402b and 402c, which are metal flat plates. 401b and 401c are accelerated toward the front end and released.

In the ion generator 40 used in the present embodiment, positive ions H ⁺ (H ₂ O) m (m is an arbitrary natural number) from the ion generator 40b, and negative ions O ₂ ⁻ (H ₂ O) from the ion generator 40c. n (n is an arbitrary natural number) is generated. When positive ions H ⁺ (H ₂ O) m (m is an arbitrary natural number) and negative ions O ₂ ⁻ (H ₂ O) n (n is an arbitrary natural number) are generated and released, they float in the air. Positive ions and negative ions attach to the surface of bacteria and viruses that cause chemical reactions and generate active radicals such as hydroxyl radicals and OH and hydrogen peroxide H ₂ O ₂ , and this oxidizing power activates bacteria and viruses. Lose.

  Positive and negative ions generated from the ion generator 40 are accelerated in the direction of the distal ends of the discharge electrodes 401b and 401c, and proceed to the inside of the fan guard portion 22 from the ion outlet 213a provided on the front wall of the third housing portion 213. The ions that have traveled into the fan guard 22 are transported into the room from between the plurality of wind-off members 231 provided on the front guard 23 by riding on the airflow generated by the fan 11.

  FIG. 6 is a block diagram showing the configuration of the control system of the blower 1 according to the present embodiment. The blower 1 includes an operation unit 101, a remote control signal receiving unit 102, a control unit 103, a first motor driver 104 and a second motor driver 105, a fan motor 12, a swing motor 31, an ion generation device 40, and an ion generation power supply unit 106. Is provided. In FIG. 6, the configuration of the control system for causing the horizontal swing is not shown.

  The operation unit 101 is provided on the front side of the pedestal unit 141, for example, and includes various operation buttons. The operation buttons included in the operation unit 101 include an operation button for starting or stopping air blowing, an air volume button for adjusting the air volume, a vertical swing button for starting or stopping the vertical swing of the casing 20, and a horizontal direction of the casing 20 A left / right swing button for starting or stopping the swing, a timer button for setting a timer operation time, an ion button for starting or stopping the operation of the ion generator 40, and the like are included. When any one of the buttons other than the operation button is pressed by a user operation during the operation of the blower 1, the operation unit 101 outputs a signal indicating that to the control unit 103. The operation button is configured to receive an input for starting operation even when the blower 1 is stopped.

  The remote control signal receiving unit 102 receives an infrared signal transmitted from a remote controller (remote controller) (not shown). As with the operation unit 101, the remote controller includes an operation button for starting or stopping air blowing, an air volume button for adjusting the air volume, a vertical swing button for starting or stopping the vertical swing of the casing 20, and the left and right sides of the casing 20 Examples include a left / right swing button for starting or stopping the swing of the direction, an ion button for starting or stopping the operation of the ion generator 40, and the like. When any operation button is turned on or off by a user operation, the remote controller transmits an infrared signal indicating that fact. When receiving the infrared signal from the remote controller, the remote control signal receiving unit 102 decodes the infrared signal and outputs a signal corresponding to the operation by the remote controller to the control unit 103.

  The control unit 103 includes, for example, a microprocessor. When the control unit 103 receives a signal output from the operation unit 101 or the remote control signal receiving unit 102, the control unit 103 performs control according to the received signal. For example, when the control unit 103 receives a signal indicating a blow start instruction during the stop from the operation unit 101 or the remote control signal receiving unit 102, the control unit 103 outputs a control signal for instructing the drive start of the fan motor 12 that is a DC motor. Output to the driver 104. The first motor driver 104 that has received this control signal turns on the current to the fan motor 12 and starts driving the fan motor 12.

  In addition, when the control unit 103 receives a signal indicating a blow stop instruction from the operation unit 101 or the remote control signal receiving unit 102 during the blow operation, the control unit 103 sends a control signal to stop the drive of the fan motor 12 to the first motor driver 104. Output. The first motor driver 104 that has received this control signal turns off the current to the fan motor 12 and stops driving the fan motor 12.

  In addition, when the control unit 103 receives a signal indicating a blow start instruction from the operation unit 101 or the remote control signal receiving unit 102 during the stop, the ion generation power supply unit 106 that supplies power to the ion generator 40 along with the operation of the fan motor 12. Output a signal to The ion generation power supply unit 106 that has received this control signal supplies power to the ion generation device 40. In the ion generator 40, an internal drive circuit generates a high voltage by supplying power and applies the high voltage to the ion generators 40b and 40c. Thus, the ion generator 40 starts releasing positive ions and negative ions.

  In addition, when the control unit 103 receives a signal indicating an instruction to stop blowing during the blowing operation from the operation unit 101 or the remote control signal receiving unit 102, the ion generating power supply that supplies power to the ion generator 40 along with the operation stop of the fan motor 12 An operation stop signal is output to the unit 106. The ion generation power supply unit 106 that has received this control signal stops supplying power to the ion generation device 40. As a result, the ion generator 40 stops emitting positive ions and negative ions.

  Similar to the control of the ion generator 40, the control unit 103 is a stepping motor when receiving a signal indicating an up / down swing instruction from the operation unit 101 or the remote control signal receiving unit 102 during operation of the fan motor 12. A control signal for instructing to start driving a certain swing motor 31 is output to the second motor driver 105. Upon receiving this control signal, the second motor driver 105 alternately outputs a pulse signal for rotating the output shaft of the swing motor 31 forward by a predetermined angle and a pulse signal for rotating the output shaft by a predetermined angle in the reverse direction. The swing of the casing 20 in the vertical direction by the swing motor 31 is performed.

  The control unit 103 instructs to stop driving the swing motor 31 when receiving a signal indicating an up / down swing instruction from the operation unit 101 or the remote control signal receiving unit 102 during operation of the fan motor 12. A signal is output to the second motor driver 105. At this time, the second motor driver 105 stops outputting the pulse signal for driving the swing motor 31.

  In addition to the above, when the control unit 103 receives a signal indicating an instruction to start various operations from the operation unit 101 or the remote control signal receiving unit 102 during the operation of the fan motor 12, the control unit 103 instructs the start of driving various functions. Similarly, when a signal indicating the stop or release of various functions is received from the operation unit 101 or the remote control signal receiving unit 102 during the operation of the fan motor 12, the various functions are stopped or released. Driving or stopping the fan motor 12 is executed with priority over driving or stopping various functions.

  Cleaning of the blower 1 configured as described above will be described. As shown in FIGS. 3 and 4, the ion generator 40 is provided with ion outlets 213a and 213a on the surface extending the front wall 21a of the motor housing portion 21 upward, and the released ions are Then, it passes through the ion outlets 213a and 213a and reaches the space between the fan guard part 22 and the fan 11. Further, the ions are sent to the front of the fan 11 so as to be scraped off from the ion outlets 213a and 213a by a plurality of blades provided in the fan 11, and are sent out from the gap between the wind-cut members 231 provided in the front guard portion 23. At the same time, it is sent out indoors.

  Since the ion delivery ports 213a and 213a are provided on the front wall 21a of the motor housing portion 21, the ions emitted from the ion generator 40 are sent forward by the fan 11 immediately after the emission. Even if the user swings left and right or swings up and down, the ions emitted from the ion generator 40 are sent out toward the tip of the output shaft 121 of the fan motor 12 soon after the generation, so the blower It is possible to allow ions having a high concentration to reach the airflow delivery direction of 1.

  When the accumulated usage time of the blower 1 becomes longer, dust adhesion to the fan guard part 22 and the front guard part 23 and the fan 11 becomes conspicuous. When the front guard portion 23 is rotated in the counterclockwise direction by a predetermined angle when the cleaning is required in this way, the locking portion with the fan guard portion 22 is released, and the front guard portion 23 can be easily removed. . FIG. 7 shows a state where the front guard portion 23 is removed in this way. The dust adhering to the front guard portion 23 can be cleaned by applying running water from the inside or wiping with a dust cloth.

  Similarly, when the accumulated usage time becomes longer, dust may also adhere to the tips of the discharge electrodes 401b and 401c of the ion generator 40. As shown in FIG. 7, when the front guard portion 23 is removed, two ion delivery ports 213a and 213a can be seen from the gaps between the plurality of blades of the fan 11 side by side. The distance between the surface of the front wall 21a of the motor housing portion 21 in which the fan motor 12 is housed and the fan 11 is about 2 cm, and the distance between the blades of the fan 11 is about 5 to 6 cm. 213a and 213a can be touched. In such a state, the discharge electrodes 401b and 401c at the back of the ion delivery ports 213a and 213a can be cleaned with a cotton swab or the like, and thus can be easily cleaned.

  Because of the control characteristics, the fan 11 rotates when the operation of the blower 1 is instructed. Therefore, the power cord (not shown) is pulled out in advance or the operation button on the operation unit 101 is operated to stop the operation. However, in the stop state, not only the fan 11 does not rotate but also energization to the ion generator 40 is prevented, and the cleaning operation can be performed safely.

  Further, since the fan 11 is simply fastened to the output shaft 121 of the fan motor by the fixing tool 11b, the fan 11 can be easily removed by removing the fixing tool 11b. In this case, since the ion delivery ports 213a and 213a are exposed to the entire surface, the discharge electrodes 401b and 401c can be more reliably cleaned.

  Even if the fan 11 and the front guard part 23 are not removed, the ion outlets 213a and 213a can be seen between the blades of the fan 11, so that the front guard 23 can be winded with a long cotton swab or the like. The discharge electrodes 401 b and 401 c can be cleaned from the gap between the members 231.

  In the structure of the present invention, there is a front wall 21 a of the motor housing portion 21 immediately in front of the ion generator 40, and the front wall 21 a is also a front wall of the third storage portion 213 at the same time. Airflow is generated on the surface of 21a in the same direction as the rotation of the fan. This air current enters from the ion outlets 213a and 213a, collides with the discharge electrodes 401b and 401c, exits from the ion outlets 213a and 213a again, and finally the airflow of the blower 1 together with the airflow sent by the fan 11 Sent forward. For this reason, since an air current more intense than the conventional electric fan is brought to the ion generator, adhesion of dust to the discharge electrodes 401b and 401c is suppressed.

  Further, when the blades of the fan 11 pass through the front surfaces of the ion outlets 213a and 213a and when the gap between the blades passes, the pressure applied to the ion outlets 213a and 213a fluctuates, so Air vibration is generated along with the rotation, and this also suppresses the adhesion of dust to the discharge electrodes 401b and 401c. For this reason, not only the need for maintenance by the user is reduced, but also the possibility that the discharge electrodes 401b and 401c of the ion generator 40 are damaged due to the maintenance can be reduced.

    In the above description, the number of blades of the fan 11 of the blower device 1 is described as three. However, there is no limitation on the number of blades as long as there is a gap for inserting a cleaning tool between the blades. . Moreover, although the ion generator has a needle-like discharge electrode, the structure is not particularly limited as long as it has a structure that can be cleaned with a cotton swab or the like.

The above-described embodiment is an example in all respects, and should be considered not restrictive. The scope of the present invention is not intended to include the above-described meanings, but is intended to include meanings equivalent to the claims and all modifications within the scope of the claims. In addition, as long as the effect of the present invention is obtained, the blower 1 may include components that are not disclosed in the embodiment.

DESCRIPTION OF SYMBOLS 1 Air blower 11 Fan 12 Fan motor 14 Stand 20 Casing 40 Ion generator

Claims (4)

A casing that houses a fan and a motor that drives the fan;
And an ion generator for generating ions from the discharge electrode by discharging in the air,
In a blower comprising:
The ion generator is installed in the casing,
The casing may have a ion delivery port for delivering ions the ion generator occurs,
The fan has a plurality of blades;
Discharge electrodes of the ion generating device, blower, characterized that you have placed visibly from the gap between the blades and the blades of the fan. The blower according to claim 1, wherein the ion delivery port is located above the motor and behind the fan.   The blower according to claim 1 or 2, wherein the discharge electrode is installed so as to be visible through the ion delivery port. The discharge electrode of the ion generator is formed in a needle shape,
The blowing device according to any one of claims 1 to 3 , wherein the standing direction is an air flow sending direction.