JP2017008905A - Device using fluid feeder - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a device using a fluid feeder which enables movable plates to be driven with a simple structure.SOLUTION: A blower 10 includes: a blower unit 21 which sends out air; and movable plates 31, each of which is provided so as to receive a force from the air sent by the blower unit 21 to continuously cross a cross section intersecting with the airflow.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an apparatus using fluid feed.

  In relation to a conventional apparatus using fluid feed, for example, Japanese Patent Application Laid-Open No. 2013-194614 aims to have a simple structure and a low manufacturing cost while having a wide blowing area. An electric fan has been disclosed (Patent Document 1). In the electric fan disclosed in Patent Literature 1, a stand to which a blower is pivotably attached and a movable louver are connected by a wire. When the swing of the electric fan approaches the left and right limits, the wire extends and moves the movable louver outward, so that the wind spreads beyond the swing angle of the electric fan.

  Japanese Utility Model Laid-Open No. 59-67599 discloses a blower for automatically recovering even when the rubber roller falls off the louver due to external force or the like, and to prevent this kind of failure. Is disclosed (Patent Document 2). The blower disclosed in Patent Document 2 has a louver for changing the wind direction to which power generated by an auxiliary motor is transmitted via a rubber roller. A cutout portion and an inclined surface are formed on a part of the inner peripheral end surface of the louver.

  Japanese Utility Model Laid-Open No. 60-118441 discloses a wind direction changing device for the purpose of easily discriminating the wind direction by visually confirming the direction of the louver even in the dark (Patent Document 3). ). The wind direction changing device disclosed in Patent Document 3 is a louver for changing the wind direction, a fan that rotates in response to the wind of a blower device, and the rotation of the fan is transmitted to the louver to swing the louver left and right. And a power transmission mechanism.

JP 2013-194614 A Japanese Utility Model Publication No. 59-67599 Japanese Utility Model Publication No. 60-118441

  As disclosed in Patent Documents 1 to 3 described above, various types of air blowers including a louver for changing a wind direction are known. In such a blower, it is required to drive the louver with a simple configuration.

  However, the fan disclosed in Patent Document 1 and the blower disclosed in Patent Document 2 require power for driving the louvers and a power transmission mechanism for transmitting the power to the louvers. Also in the wind direction changing device disclosed in Patent Document 3, a fan for receiving the wind of the blower device and a power transmission mechanism for transmitting the rotation of the fan to the louver are required.

  Accordingly, an object of the present invention is to solve the above-described problem and to provide an apparatus using a fluid feed capable of driving a movable plate with a simple configuration.

  The apparatus using the fluid feed according to the present invention continuously crosses the cross section intersecting the fluid flow by receiving the force from the fluid feed portion for sending the fluid and the fluid sent by the fluid feed portion. And a moving plate provided.

  Preferably, the device using fluid feed includes a plurality of moving plates that are arranged so as to be spaced apart from each other, and are provided so as to traverse in a cross section that intersects the fluid flow in order. The plurality of moving plates are arranged side by side in an annular shape. The apparatus using fluid feed further includes a support unit that rotatably supports a plurality of moving plates.

  Preferably, the device using fluid feed includes a plurality of moving plates that are arranged so as to be spaced apart from each other, and are provided so as to traverse in a cross section that intersects the fluid flow in order. The moving plate is inclined with respect to the fluid flow direction. When the angle formed by the flow direction of the fluid and the moving plate is referred to as an installation angle, the plurality of moving plates have different installation angles or different shapes so that the moving plate receives different forces from the fluid. A moving plate and a second moving body are included.

  Preferably, the device using fluid feed includes a plurality of moving plates that are arranged so as to be spaced apart from each other, and are provided so as to traverse in a cross section that intersects the fluid flow in order. The plurality of moving plates include a first moving plate and a second moving plate that are different from each other in distance from the fluid feeding portion in a cross section that intersects the fluid flow.

  Preferably, the apparatus using fluid feed is arranged on the circumference with a space between each other, and a plurality of moving plates provided so as to cross in a cross section intersecting the fluid flow in order, and a plurality of movements And a support portion that rotatably supports the plate. The moving plate has one end and the other end at both ends along the rotation center axis of the plurality of moving plates and extends non-parallel to the rotation center axis of the plurality of moving plates between the one end and the other end. Provided.

  Preferably, the apparatus using fluid feed is arranged on the circumference with a space between each other, and a plurality of moving plates provided so as to cross in a cross section intersecting the fluid flow in order, and a plurality of movements And a support portion that rotatably supports the plate. The rotation center axes of the plurality of moving plates are arranged so as to deviate from the center of the circumference where the plurality of moving plates are arranged.

  Preferably, the apparatus using fluid feed further includes a light source provided on the upstream side of the moving plate in the flow direction of the fluid fed by the fluid feed section. The fluid feeding unit is a blowing unit that sends out air. The moving plate adjusts the amount of light traveling outward from the light source.

  As described above, according to the present invention, an apparatus using a fluid feed capable of driving the movable plate with a simple configuration can be provided.

It is a figure which represents typically the air blower to which this invention was applied. In the air blower in FIG. 1, it is a figure which shows the state at the time of the movement plate stationary, and the state at the time of movement of a movement plate. It is sectional drawing which shows another example of the shape of the moving board in the air blower in FIG. It is a figure which shows another example of arrangement | positioning of the moving board in the air blower in FIG. In the air blower in FIG. 4, it is a figure which shows the state at the time of a stationary movement board, and the state at the time of rotation of a movement board. It is a figure which shows the 1st modification of the air blower in FIG. It is a figure which shows the 2nd modification of the air blower in FIG. It is a figure which shows the 3rd modification of the air blower in FIG. It is a figure which shows the 4th modification of the air blower in FIG. It is a figure which shows the 5th modification of the air blower in FIG. It is a figure which shows the 6th modification of the air blower in FIG. It is a perspective view which shows the air blower in Embodiment 1 of this invention. It is a front view which shows the air blower in FIG. It is a top view which shows the air blower seen from the direction shown by the arrow XIV in FIG. It is sectional drawing which shows the air blower along the XV-XV line | wire in FIG. It is sectional drawing which expands and shows the range enclosed with the dashed-two dotted line XVI in FIG. It is sectional drawing which shows the air blower along the XVII-XVII line | wire in FIG. It is sectional drawing which shows the 1st modification of arrangement | positioning of the moving plate in FIG. It is sectional drawing which shows the 2nd modification of arrangement | positioning of the moving board in FIG. It is a perspective view which shows the air blower in Embodiment 2 of this invention. It is a figure which expands and shows the wind direction change apparatus with which the air blower in FIG. 20 is provided. It is a perspective view which shows the illuminating device in Embodiment 3 of this invention. It is a front view which shows the illuminating device in FIG. It is a top view which shows the illuminating device seen from the direction shown by arrow XXIV in FIG. It is sectional drawing which shows the illuminating device along the XXV-XXV line | wire in FIG.

  Embodiments of the present invention will be described with reference to the drawings. In the drawings referred to below, the same or corresponding members are denoted by the same reference numerals.

(About the basic principle of the present invention)
The basic principle of the present invention will be described by taking a blower as an example. FIG. 1 is a diagram schematically showing a blower to which the present invention is applied. With reference to FIG. 1, the blower 10 includes a blower unit 21, a plurality of moving plates 31, and a support unit 32.

  The air blowing unit 21 is provided as a fluid feeding unit that feeds fluid. The blower unit 21 sends air as a fluid to the external space. The air blowing unit 21 includes a fan 22. The fan 22 is provided so as to be rotatable about the central axis 101. The blower unit 21 has a blower opening 23. The blower opening 23 is opened facing the external space. The air flow (airflow) formed with the rotation of the fan 22 is sent out to the external space through the air blowing port 23.

  The plurality of moving plates 31 and the support portion 32 constitute a wind direction changing device 30 that changes the blowing direction of the airflow generated by the blowing portion 21.

  The moving plate (guide plate) 31 has a plate shape. The moving plate 31 has a surface 31a constituted by one of two main surfaces of the plate shape. The surface 31a is a plane. The surface 31a is not limited to a flat surface, and may be a curved surface.

  The moving plate 31 is provided to be inclined with respect to the blowing direction of the airflow generated by the blowing unit 21 (the direction indicated by the arrow 111, hereinafter also referred to as the blowing direction from the blowing unit 21). The moving plate 31 is provided to be inclined with respect to the blowing direction from the blowing unit 21 at a position facing the blowing port 23. The moving plate 31 is provided so that the surface 31 a extends in an oblique direction with respect to the blowing direction from the blowing unit 21 at a position facing the blowing port 23. The moving plate 31 is disposed so that the surface 31 a faces the air blowing port 23 at a position facing the air blowing port 23.

  The moving plate 31 is provided so as to continuously cross the cross section intersecting with the air flow generated by the air blowing unit 21 by receiving a force from the air sent out from the air blowing unit 21. The moving plate 31 is provided so as to continuously move at a position facing the air blowing port 23 by receiving a force from the air sent from the air blowing unit 21. The moving plate 31 moves in a direction intersecting the blowing direction from the blowing unit 21 (more specifically, the orthogonal direction indicated by the arrow 113) when the air flow generated by the blowing unit 21 collides with the surface 31a. It is provided as follows.

  The plurality of moving plates 31 are arranged at intervals. The plurality of moving plates 31 are arranged at an equal pitch. The plurality of moving plates 31 are provided so that installation angles described later are equal to each other. The plurality of moving plates 31 have the same shape.

  The plurality of moving plates 31 are provided side by side on a straight line at a position facing the air blowing port 23. The plurality of moving plates 31 are provided side by side in a direction orthogonal to the air blowing direction from the air blowing unit 21 at a position facing the air blowing port 23. The plurality of moving plates 31 are provided so as to cross the cross section intersecting with the air flow generated by the blower unit 21 in order by receiving force from the air sent from the blower unit 21 at a position facing the blower port 23. Yes.

  The support unit 32 supports the plurality of moving plates 31 so that the moving plate 31 can continuously move in a cross section that intersects the airflow generated by the blower unit 21. The support portion 32 supports the plurality of moving plates 31 by means of rails or the like so that the moving plate 31 can continuously move at a position facing the air blowing port 23.

  FIG. 2 is a diagram illustrating a state when the moving plate is stationary and a state when the moving plate is moved in the air blower in FIG. 1.

  With reference to FIG. 1 and FIG. 2, at a position facing the air outlet 23, an angle formed by the air blowing direction from the air blowing unit 21 (direction indicated by the arrow 111) and the moving plate 31 (surface 31 a) is set as an installation angle. That's it. When the air flow generated by the air blowing unit 21 passes through the wind direction changing device 30, the air blowing direction from the air blowing unit 21 is rectified from the direction indicated by the arrow 111 to the direction indicated by the arrow 112 by the installation angle of the moving plate 31. . At this time, the moving plate 31 receives the force of the component that intersects the blowing direction from the air blowing unit 21 from the airflow (more specifically, the force of the orthogonal component), so that the plurality of moving plates 31 are moved to the arrow 113. Move in the direction shown.

  The angle formed by the blowing direction before the rectification by the wind direction changing device 30 (the direction indicated by the arrow 111) and the blowing direction after the rectification (the direction indicated by the arrow 112) is referred to as a rectification angle. The commutation angle is different when the moving plate 31 is stationary and when the moving plate 31 is moving. When the rectification angle when the moving plate 31 is stationary is a, and the rectification angle when the moving plate 31 is moving is b, the relationship of the rectification angle a> the rectification angle b is established. Assuming that the installation angle formed by the blowing direction from the blower unit 21 and the moving plate 31 is A, the rectification angle a when the moving plate 31 is stationary is substantially equal to the installation angle A. On the other hand, when the moving plate 31 moves, the moving plate 31 passes across the airflow before rectification, so that the rectifying effect by the moving plate 31 is reduced.

  From such a principle, in the blower device 10, it is possible to obtain the blowing direction when the moving plate 31 is stationary and the blowing direction when the moving plate 31 is moving. A brake mechanism may be provided for the moving plate 31 in order to obtain the blowing direction when the moving plate 31 is stationary at an arbitrary timing.

  In the blower 10, the magnitude of the force that the moving plate 31 receives from the airflow (that is, the driving force of the moving plate 31) changes according to the installation angle of the moving plate 31. More specifically, the driving force of the moving plate 31 increases as the installation angle of the moving plate 31 increases, and the driving force of the moving plate 31 decreases as the installation angle of the moving plate 31 decreases. For this reason, the moving speed of the moving plate 31 can be arbitrarily set through the installation angle of the moving plate 31.

  The direction of rectification by the wind direction changing device 30 includes the installation angle of the moving plate 31, the shape and size of the moving plate 31, the number of moving plates 31 that are simultaneously arranged at positions facing the air blowing ports 23, and the distance between adjacent moving plates 31. The aperture ratio, the moving speed of the moving plate 31, the weight of the wind direction changing device 30, the resistance such as the friction force generated when the moving plate 31 is moved, and the like.

  In addition, although the air blower 10 which drives the movement board 31 using the airflow generated by the ventilation part 21 was demonstrated here, as a fluid for obtaining the drive force of a movement board, in addition to air, water etc. It is also possible to use a liquid, gel, or a refrigerant that changes phase in the system. Although the moving plate 31 functioning as a wind direction changing plate has been described here, the moving plate in the present invention is not limited to such a plate that changes the behavior of the fluid itself. The moving plate in the present invention may have a function of changing the behavior of, for example, one that moves with the fluid or one that is propagated by the fluid (for example, ions, fragrance, mist, etc.).

  FIG. 3 is a cross-sectional view showing another example of the shape of the moving plate in the blower in FIG. Referring to FIG. 3, in this example, a moving plate 33 is used in place of moving plate 31 in FIG. The moving plate 33 has a blade cross-sectional shape.

  More specifically, the moving plate 33 has a front end portion 34 through which air flows and a rear end portion 35 through which air flows out. The moving plate 33 is disposed so that the front end portion 34 faces the air blowing port 23 in FIG. The moving plate 33 has a positive pressure surface 33a and a negative pressure surface 33b. The positive pressure surface 33 a and the negative pressure surface 33 b are arranged on the front and back sides, and extend between the front end portion 34 and the rear end portion 35.

  When the airflow generated by the blower 21 flows along the positive pressure surface 33a and the negative pressure surface 33b, a relatively large pressure acts on the positive pressure surface 33a, and a relatively small pressure acts on the negative pressure surface 33b. As a result, a force from the positive pressure surface 33 a toward the negative pressure surface 33 b acts on the moving plate 33 as a driving force, and the moving plate 33 moves in the direction indicated by the arrow 113.

  In the present invention, the moving plate does not necessarily have to be inclined with respect to the fluid flow direction. For example, by using a moving plate having a blade cross-sectional shape, the moving plate is arranged in parallel to the fluid flow direction. Even in this case, it is possible to realize a configuration in which the moving plate obtains a driving force.

  FIG. 4 is a diagram illustrating another example of the arrangement of the moving plates in the air blower in FIG. 1. Referring to FIG. 4, in this example, a plurality of moving plates 31 are arranged in a ring. The plurality of moving plates 31 are arranged side by side on the circumference 141. The plurality of moving plates 31 are provided so that the installation angles are equal to each other. The plurality of moving plates 31 are arranged at an equal pitch. The plurality of moving plates 31 have the same shape.

  The support portion 32 is provided so as to integrally support the plurality of moving plates 31 arranged on the circumference 141. The support part 32 supports the plurality of moving plates 31 so as to be rotatable about the rotation center axis 131. The moving plate 31 is disposed to be inclined with respect to the radial direction around the rotation center axis 131.

  The plurality of moving plates 31 that rotate about the rotation center shaft 131 form an apparently cylindrical rotating body. The air outlet 23 is disposed inside the rotating body. The blower opening 23 is opened on the inner side of the rotating body so as to face the outer side in the radial direction around the rotation center axis 131.

  FIG. 5 is a diagram illustrating a state in which the moving plate is stationary and a state in which the moving plate is rotated in the air blower in FIG. 4.

  Referring to FIGS. 4 and 5, the plurality of moving plates 31 are indicated by arrows 132 around the rotation center axis 131 by receiving a force from the air sent from the blowing unit 21 at a position facing the blowing port 23. Rotate in the direction. The rotational speed of the moving plate 31 converges to a constant speed according to the resistance of the airflow received by the moving plate 31, the frictional force accompanying the rotation of the moving plate 31, and the like. When the moving plate 31 is stationary, the airflow from the blowing unit 21 is rectified to the blowing range 133, and when the moving plate 31 is rotated, the airflow from the blowing unit 21 is rectified to the blowing range 134.

  In this example, while arrange | positioning the several moving board 31 concentrically, and arrange | positioning the ventilation port 23 inside it, the inside of the cross section which the moving board 31 cross | intersects the airflow generate | occur | produced by the ventilation part 21 is continuously provided. A crossing structure can be realized with a simple configuration. Since the plurality of moving plates 31 are provided so that the installation angles are equal to each other, they rotate continuously and stably. For this reason, when the moving plate 31 rotates, the airflow from the blower unit 21 can be rectified into a certain blower range.

  Next, a method for changing the wind direction by causing a dynamic change in the driving of the moving plate 31 in the above-described blowing device will be described. As such a method, a method of providing a difference in the installation angle of the moving plate 31, a method of providing a difference in the distance from the blower opening 23 to the moving plate 31, a method of providing a difference in the pitch between the moving plates 31, a moving plate There is a method of providing a difference in the shape of 31.

  FIG. 6 is a diagram illustrating a first modification of the blower device in FIG. 4. Referring to FIG. 6, in this modification, a plurality of moving plates 31 </ b> P and a plurality of moving plates 31 </ b> Q are provided as the plurality of moving plates 31.

  The plurality of moving plates 31P are arranged side by side in the circumferential direction around the rotation center axis 131. The plurality of moving plates 31Q are arranged side by side in the circumferential direction around the rotation center axis 131. The same number of the plurality of moving plates 31P and the plurality of moving plates 31Q are provided.

  The moving plate 31P and the moving plate 31Q are provided at different installation angles. The moving plate 31P is provided with an installation angle that forms a positive angle with respect to the blowing direction from the blowing unit 21, and the moving plate 31Q is provided with an installation angle that forms a negative angle with respect to the blowing direction from the blowing unit 21. It has been. That is, when the moving plate 31P is provided with the installation angle α and the moving plate 31Q is provided with the installation angle β, the installation angle α satisfies the relationship 0 ° <α <90 °, and the installation angle β is −90. Satisfies the relationship of ° <β <0 °. In particular, in the example shown in the figure, the absolute values of the installation angle α and the installation angle β are equal. For example, the installation angle α is 30 ° and the installation angle β is −30 °.

  The plurality of moving plates 31 rotate around the rotation center shaft 131 by receiving a force from the air sent from the blower unit 21 at a position facing the blower opening 23. At this time, while the moving plate 31P moves to the position facing the air outlet 23, a force in the direction indicated by the arrow 135 acts on the moving plate 31P, and the position where the moving plate 31Q faces the air outlet 23 is set. During the movement, a force in the direction indicated by the arrow 136 acts on the moving plate 31Q.

  As shown in the forward rotation diagram in FIG. 6, the moving plate 31 </ b> P receives force from the air sent out from the blower 21, so that the moving plates 31 rotate in the direction indicated by the arrow 135. Next, when the moving plate 31Q reaches a position facing the air blowing port 23, the force acting on the moving plate 31Q from the air sent out from the air blowing unit 21 serves as a brake, and the rotational speeds of the plurality of moving plates 31 are reduced. Eventually, the rotation of the plurality of moving plates 31 stops, and then starts to rotate in the direction indicated by the arrow 136 opposite to the direction indicated by the arrow 135, as shown in the reverse rotation diagram in FIG.

  That is, the plurality of moving plates 31 repeats forward rotation that rotates in the direction indicated by the arrow 135 and reverse rotation that rotates in the direction indicated by the arrow 136. During this time, at the timing when the moving plate 31P moves to the position facing the air outlet 23, the airflow from the blower unit 21 is rectified into the air blowing range 137, and at the timing when the moving plate 31Q moves to the position facing the air outlet 23, The airflow from the blower unit 21 is rectified to the blower range 138.

  As described above, in the present modification, the rotational speeds of the plurality of moving plates 31 do not converge to a constant speed, but are rotational movements that are slow and steep. The installation angle of the moving plate 31 arranged at a position facing the air outlet 23 is different between the moving plate 31P and the moving plate 31Q, and the moving speed of the moving plate 31 changes every moment. Can be formed.

  The plurality of moving plates 31 are not necessarily provided over a range of 360 °, and the plurality of moving plates 31 are arranged so as to repeat normal rotation and reverse rotation in a range of angles smaller than 360 °. May be. A moving plate 31 having an installation angle different from the installation angle α and the installation angle β may be provided at the boundary between the moving plate 31P and the moving plate 31Q.

  As another example, the moving plate 31P and the moving plate 31Q having the same sign and different installation angles may be arranged at random and at equal pitches. For example, a plurality of moving plates 31P having an installation angle of 30 ° may be continuously arranged in the circumferential direction, and a plurality of moving plates 31Q having an installation angle of 45 ° may be arranged at the remaining positions. In this case, due to the difference in installation angle, the force received by the moving plate 31 from the air current becomes non-uniform, and the rotational speed of the moving plate 31 does not converge to a constant speed. Depending on the difference in the moving speed of the moving plate 31 and the difference in installation angle, a dynamic change in wind direction in which the rectification direction is not constant can be created.

  As another example, the moving plate 31P and the moving plate 31Q having opposite installation angles with opposite positive values and different absolute values may be arranged at random and at equal pitches. For example, when a plurality of moving plates 31P with an installation angle of 30 ° and a plurality of moving plates 31Q with an installation angle of −20 ° are arranged, the force that the moving plate 31Q receives from the airflow is the force that the moving plate 31P receives from the airflow. In the opposite direction, the rotational motion acts like a deceleration. In this case, the rotational speeds of the plurality of moving plates 31 do not converge to a constant speed, but become a rotational motion with slowness. Similar to the above, a dynamic change in wind direction in which the rectification direction is not constant can be created by the difference in the moving speed of the moving plate 31 and the difference in the installation angle.

  FIG. 7 is a view showing a second modification of the blower in FIG. With reference to FIG. 7, in the present modification, a plurality of moving plates 31 are arranged side by side on a polygonal side 146. The plurality of moving plates 31 are arranged side by side on the hexagonal side 146.

  The plurality of moving plates 31 rotate and move in the direction indicated by the arrow 132 around the rotation center axis 131 by receiving a force from the air sent out from the blower unit 21 at a position facing the blower opening 23. Here, as the distance from the air blowing port 23 to the moving plate 31 is increased, the force (driving force) that the moving plate 31 receives from the airflow is reduced. In this case, the rotational speed of the moving plate 31 becomes slow, and the blowing range becomes wide. On the other hand, the smaller the distance from the blower opening 23 to the moving plate 31, the greater the force (driving force) that the moving plate 31 receives from the airflow. In this case, the rotational speed of the moving plate 31 is increased and the blowing range is narrowed.

  In this modification, the distance from the blower opening 23 to the moving plate 31 varies depending on the position of the polygonal side 146 where the moving plate 31 is disposed. More specifically, the distance from the blower opening 23 to the moving plate 31 increases as the moving plate 31 is located closer to the corner of the polygonal side 146, and is closer to the center of the polygonal side 146. The closer the moving plate 31 is located, the smaller the distance from the blower opening 23 to the moving plate 31. As the plurality of moving plates 31 rotate, the distance from the air blowing port 23 to the moving plate 31 changes every moment, so that a dynamic wind direction change can be formed.

  FIG. 8 is a view showing a third modification of the air blower in FIG. Referring to FIG. 8, the plurality of moving plates 31 are arranged side by side on a circumference 141. The support portion 32 is provided so as to integrally support the plurality of moving plates 31 arranged on the circumference 141. The support part 32 supports the plurality of moving plates 31 so as to be rotatable about the rotation center axis 131. In the present modification, the rotation center shaft 131 is arranged so as to be shifted from the center 139 of the circumference 141 in which the plurality of moving plates 31 are arranged.

  The plurality of moving plates 31 rotate around the rotation center shaft 131 by receiving a force from the air sent from the blower unit 21 at a position facing the blower opening 23. At this time, the distance from the air blowing port 23 to the moving plate 31 varies depending on the relative positional relationship between the rotation center shaft 131 and the center 139 of the circumference 141. More specifically, when the center 139 of the circumference 141 is on the back side of the air outlet 23, the distance from the air outlet 23 to the moving plate 31 is the smallest (the left figure in FIG. 8), and the center of the circumference 141 is obtained. When 139 is in front of the air outlet 23, the distance from the air outlet 23 to the moving plate 31 is the largest (right figure in FIG. 8). As the plurality of moving plates 31 rotate, the distance from the air blowing port 23 to the moving plate 31 changes every moment, so that a dynamic wind direction change can be formed.

  FIG. 9 is a view showing a fourth modification of the blower in FIG. Referring to FIG. 9, in this modification, a plurality of moving plates 31 </ b> P and a plurality of moving plates 31 </ b> Q are provided as the plurality of moving plates 31. The plurality of moving plates 31P are arranged side by side in the circumferential direction around the rotation center axis 131. The plurality of moving plates 31Q are arranged side by side in the circumferential direction around the rotation center axis 131. The plurality of moving plates 31P and the plurality of moving plates 31Q are provided at different pitches. The plurality of moving plates 31 have the same shape and are provided to have the same installation angle.

  The plurality of moving plates 31 rotate and move in the direction indicated by the arrow 132 around the rotation center axis 131 by receiving a force from the air sent out from the blower unit 21 at a position facing the blower opening 23. Here, the narrower the pitch between the moving plates 31, the higher the rotational speed of the moving plate 31, and the narrower the air blowing range. The wider the pitch between the moving plates 31, the lower the rotational speed of the moving plate 31, and the wider the blowing area.

  In this modification, a plurality of moving plates 31P provided at a relatively narrow pitch and a plurality of moving plates 31Q provided at a relatively wide pitch are alternately arranged at positions facing the air blowing ports 23. Therefore, a dynamic wind direction change can be formed.

  FIG. 10 is a diagram illustrating a fifth modification of the blower device in FIG. 4. Referring to FIG. 10, in this modification, a plurality of moving plates 31 </ b> P and a plurality of moving plates 31 </ b> Q are provided as the plurality of moving plates 31. The plurality of moving plates 31P are arranged side by side on the circumference 142, and the plurality of moving plates 31Q are arranged side by side on the circumference 143. Circumference 142 and circumference 143 are concentric and have different diameters.

  The support portion 32 is provided so as to integrally support the plurality of moving plates 31P and the plurality of moving plates 31Q. The support portion 32 supports the plurality of moving plates 31P and the plurality of moving plates 31Q so as to be rotatable about the rotation center axis 131.

  The moving plate 31 </ b> P and the moving plate 31 </ b> Q are provided at an installation angle that forms a positive angle with respect to the blowing direction from the blowing unit 21. The plurality of moving plates 31P are provided at a random pitch. The plurality of moving plates 31Q are provided at a random pitch. The plurality of moving plates 31 are provided at random installation angles. The plurality of moving plates 31 are provided so as to have irregular shapes such as thickness and length in the air flow direction.

  The plurality of moving plates 31 rotate and move in the direction indicated by the arrow 132 around the rotation center axis 131 by receiving a force from the air sent out from the blower unit 21 at a position facing the blower opening 23. At this time, with the rotation of the plurality of moving plates 31, the installation angle of the moving plate 31 that moves to a position facing the air blowing port 23, the distance from the air blowing port 23 to the moving plate 31, the shape of the moving plate 31, the moving plate Since the combination of pitches between 31 changes every moment, a dynamic wind direction change can be formed.

  As described above, the moving plate 31 can regulate the movement of the wind direction changing device 30 in one cycle by combining its arrangement method, shape, and the like. More specifically, by appropriately setting the diameter of the circumference where the moving plate 31 is arranged, the number, shape, pitch, rotational speed, etc. of the moving plate 31, the movement and wind of the moving plate 31 with a fixed period can be adjusted. Movement can be given, and a periodic wind can be reproduced.

Subsequently, an air blower including a plurality of wind direction changing devices will be described.
FIG. 11 is a view showing a sixth modification of the blower in FIG. Referring to FIG. 11, the air blower in the present modification includes a wind direction changing device 30A and a wind direction changing device 30B. The wind direction changing device 30A includes a plurality of moving plates 31P and a support portion 32P, and the wind direction changing device 30B includes a plurality of moving plates 31Q and a support portion 32Q.

  The plurality of moving plates 31P are arranged side by side on the circumference 147, and the plurality of moving plates 31Q are arranged side by side on the circumference 148. Circumference 147 and circumference 148 are concentric and have different diameters. The plurality of moving plates 31 </ b> P are provided at an installation angle that forms a negative angle with respect to the direction of air blowing from the air blowing unit 21. The plurality of moving plates 31 </ b> Q are provided at an installation angle that forms a positive angle with respect to the blowing direction from the blowing unit 21.

  The support portion 32P is provided so as to integrally support a plurality of moving plates 31P arranged on the circumference 147. The support portion 32P supports the plurality of moving plates 31P so as to be rotatable about the rotation center shaft 131. The support portion 32Q is provided so as to integrally support a plurality of moving plates 31Q arranged on the circumference 148. The support portion 32Q supports the plurality of moving plates 31Q so as to be rotatable about the rotation center shaft 131. The support portion 32P and the support portion 32Q support the plurality of moving plates 31P and the plurality of moving plates 31Q, respectively, independently of each other.

  The plurality of moving plates 31 </ b> P rotate and move in the direction indicated by the arrow 136 around the rotation center axis 131 by receiving a force from the air sent from the blowing unit 21 at a position facing the blowing port 23. The plurality of moving plates 31 </ b> Q rotate in the direction indicated by the arrow 135 around the rotation center axis 131 by receiving a force from the air sent from the blowing unit 21 at a position facing the blowing port 23.

  In the present embodiment, the plurality of moving plates 31P in the wind direction changing device 30A and the plurality of moving plates 31Q in the wind direction changing device 30B are arranged concentrically around the rotation center axis 131. For example, the rotation center shaft 131 may be arranged side by side.

(Embodiment 1)
In the following embodiments, the configuration of the blower described in the basic principle of the present invention will be described more specifically.

  FIG. 12 is a perspective view showing the air blowing device according to Embodiment 1 of the present invention. FIG. 13 is a front view showing the blower in FIG. FIG. 14 is a top view showing the air blower viewed from the direction indicated by the arrow XIV in FIG. FIG. 15 is a cross-sectional view showing the blower device along the line XV-XV in FIG. 13.

  With reference to FIG. 12 to FIG. 15, the blower device 50 in the present embodiment includes a blower unit 150, a plurality of moving plates 61, and a support unit 69.

  The blower unit 150 includes a base unit 51, a fan 52, a motor 53, and a neck unit 54. The base portion 51 is a substantially cylindrical case body and is placed on the ground. A fan 52 and a motor 53 are accommodated in the base portion 51. The fan 52 is provided to be rotatable about a central axis 156 parallel to the vertical direction. The motor 53 is provided as a power source for the fan 52. The base portion 51 has a bottom portion 51n arranged to face the ground. A suction port (not shown) is formed in the bottom 51n.

  The neck portion 54 is provided so as to extend in a cylindrical shape from the base portion 51 in the vertically upward direction. An air flow path communicating with the inside of the base portion 51 is formed inside the neck portion 54. A blower port 55 is provided at the tip of the neck portion 54 extending vertically upward. The air blowing port 55 opens in the horizontal direction.

  As the fan 52 rotates, air flows into the base 51 through the suction port provided in the bottom 51n. The air reaches the air blowing port 55 from the base portion 51 through the air flow path in the neck portion 54.

  The air blowing port 55 may be opened in a direction other than the horizontal direction (for example, obliquely upward). Moreover, in this Embodiment, in order to give straightness to ventilation, the shape which narrows an airflow to the ventilation port 55 is selected, However, The ventilation port 55 is not restricted to such a structure, For example, it is 360 degrees You may have the shape which ventilates to the perimeter.

  The plurality of moving plates 61 and the support unit 69 constitute a wind direction changing device 160 that changes the blowing direction of the airflow generated by the blowing unit 150.

  The plurality of moving plates 61 are arranged side by side on a circumference around a rotation center axis 157 parallel to the vertical direction. The support part 69 has a top part 62 and a bottom part 63 as its constituent parts. The top portion 62 is provided so as to connect the upper end portions of the plurality of moving plates 61 to each other. The bottom 63 is provided so as to connect the lower ends of the plurality of moving plates 61 to each other. An opening 64 into which the neck 54 is inserted is formed in the bottom 63.

  The air blowing port 55 is disposed inside the plurality of moving plates 61 arranged on the circumference. The moving plate 61 has a size that is equal to or greater than the height of the air blowing port 55 and is arranged so that it can receive all the airflow from the air blowing port 55.

  16 is an enlarged cross-sectional view showing a range surrounded by a two-dot chain line XVI in FIG. Referring to FIGS. 12 to 16, support portion 69 supports a plurality of moving plates 61 so as to be rotatable about rotation center axis 157.

  More specifically, the top portion 62 has a recess 62r. The concave portion 62r has a conical concave shape. The air blowing unit 150 further includes a shaft portion 56. The shaft portion 56 has a shape extending in a shaft shape from the neck portion 54 along the rotation center axis 157. The shaft portion 56 has a tip portion sharpened at the tip extending in the shape of a shaft. The support portion 69 is provided in point contact with the shaft portion 56 by fitting the tip portion of the shaft portion 56 to the recess 62r.

  The support part 69 further has a guide part 66 as a constituent part thereof. The guide portion 66 extends in a cylindrical shape from the top portion 62 and is provided so as to surround the shaft portion 56. When the moving plate 61 receives the airflow from the air blowing port 55, the wind direction changing device 160 rotates while shaking. In the present embodiment, by providing the guide portion 66 that functions as a bearing for the shaft portion 56, the wind direction changing device 160 can be stably rotated about the rotation center shaft 157.

  FIG. 17 is a cross-sectional view showing the blower device along the line XVII-XVII in FIG. 13. Referring to FIG. 17, the plurality of moving plates 61 are arranged in the same form as the plurality of moving plates 31 shown in FIG. That is, the plurality of moving plates 61 are provided such that the installation angles are equal to each other. The plurality of moving plates 61 are arranged at an equal pitch.

  The plurality of moving plates 61 rotate and move in the direction indicated by the arrow 132 around the rotation center shaft 157 by receiving a force from the air sent out from the air blowing unit 150 at a position facing the air blowing port 55. The rotational speeds of the plurality of moving plates 61 can be adjusted by the air volume, wind pressure, etc. of the air flow generated by the air blowing unit 150. If the air volume is increased, the rotation speed is increased, and if the air volume is decreased, the rotation speed is decreased. Further, the rotational speed of the plurality of moving plates 61 at a constant air volume can be set to some extent by the shape, installation angle, and pitch of the moving plates 61. Actually, it is influenced by the frictional force generated between the recess 62r and the shaft portion 56, the wind resistance received by the moving plate 61, and the like.

  When the plurality of moving plates 61 are stationary, the airflow rectification angle becomes maximum, and the plurality of moving plates 61 rotate, whereby the airflow rectification angle can be suppressed. As a result, with the rotation of the plurality of moving plates 61, the blowing direction (range) can be adjusted.

  The rotational speed of the plurality of moving plates 61 is also affected by the distance between the air blowing port 55 and the moving plate 61. If this distance is shortened, a large wind force can be received from the blower 150, while the number of moving plates 61 arranged at a position facing the blower port 55 is reduced. The plurality of moving plates 61 are preferably arranged so that the aperture ratio does not fall below 70%, and the thickness, width, installation angle, pitch, and number of the moving plates 61 are appropriately selected.

  FIG. 18 is a cross-sectional view showing a first modification of the arrangement of the moving plates in FIG. Referring to FIG. 18, in this modification, a plurality of moving plates 61P and a plurality of moving plates 61Q are provided as the plurality of moving plates 61. The plurality of moving plates 61P and the plurality of moving plates 61Q are provided in the same form as the plurality of moving plates 31P and the plurality of moving plates 31Q in FIG.

  By adjusting the installation angle and pitch of the moving plate 61, it is possible to make the rotation of the moving plate 61 have periodicity. In the figure, by replacing 16 moving plates 61 at equal pitches with 8 moving plates 61 whose installation angles are reversed, the plurality of moving plates 61 are rotated forward and reverse. Configure to repeat. Thereby, since the installation angle | corner of the moving plate 61 switches with rotation of the several moving plate 61, the ventilation range can be expanded.

  FIG. 19 is a cross-sectional view showing a second modification of the arrangement of the moving plates in FIG. Referring to FIG. 19, in this modification, the moving plate 61P and the moving plate 61Q described with reference to FIG. 18 are randomly arranged.

  Since the moving plate 61 whose installation angle is opposite to that of the moving plate 61 of the original installation angle obtains a reverse rotational force (driving force) as compared with the original installation angle of the moving plate 61, an apparent deceleration action is obtained. In the example shown in the figure, the obtained rotational force and the direction thereof are not constant, so that the rotational motion is slow and steep, and the ventilation is not stable and the wind is strong and weak. It is possible to create a wind with periodicity according to the arrangement of the plurality of moving plates 61 around the rotation center axis 157, and to reproduce arbitrary fluctuations. It is also possible to create a wind like “1 / f fluctuation” which is said to be comfortable due to fluctuations in the natural world.

  In order to keep the moving plate 61 rotating smoothly, it is preferable to provide a difference between the number of moving plates 61 having a positive installation angle and the number of moving plates 61 having a negative installation angle.

  If the rotational speed of the moving plate 61 can be adjusted, not only the stationary and rotating control of the plurality of moving plates 61, finer wind direction adjustment can be performed. For example, by providing a brake mechanism, it is possible to achieve a reduction in stationary speed and rotational speed. Examples of such a brake mechanism include a chuck structure that can generate a frictional force of an arbitrary size between the shaft portion 56 and the like.

  In addition, the air blower 50 in this Embodiment may further have an ion generator. The ion generator is installed in an air flow path from the fan 52 toward the air blowing port 55. In this case, the ion delivery direction can be changed as the moving plate 61 rotates.

(Embodiment 2)
FIG. 20 is a perspective view showing an air blower according to Embodiment 2 of the present invention. FIG. 21 is an enlarged view of the air direction changing device provided in the air blower in FIG.

  Referring to FIGS. 20 and 21, moving plate 61 has one end 61 j and the other end 61 k at both ends along rotation center axis 157. One end 61 j is connected to the top 62, and the other end 61 k is connected to the bottom 63.

  In the present embodiment, the moving plate 61 extends non-parallel to the rotation center axis 157 between the one end 61j and the other end 61k. One end 61j and the other end 61k of each moving plate 61 are arranged at phase positions shifted from each other around an axis centering on the rotation center axis 157. The moving plate 61 extends from the one end 61j toward the other end 61k while being inclined with respect to the vertical direction. The moving plate 61 extends while twisting from one end 61j toward the other end 61k. In the example shown in the figure, the angle θ formed by the moving plate 61 and the horizontal direction is set to 70 °. For example, the angle θ satisfies the relationship of 10 ° ≦ θ ≦ 170 °.

  According to such a configuration, the airflow from the air blowing unit 150 can have a vertical component. In particular, in the present embodiment, the airflow from the air blowing unit 150 is rectified in an obliquely upward direction.

(Embodiment 3)
FIG. 22 is a perspective view showing an illumination apparatus according to Embodiment 3 of the present invention. FIG. 23 is a front view showing the lighting device in FIG. FIG. 24 is a top view showing the lighting device as seen from the direction indicated by arrow XXIV in FIG. FIG. 25 is a cross-sectional view showing the illumination device along the line XXV-XXV in FIG.

  Referring to FIGS. 22 to 25, illumination device 80 in the present embodiment has basically the same structure as blower device 50 in the first embodiment.

  In the present embodiment, the wind direction changing device 160 has a spherical shape as a whole. The top portion 62 and the bottom portion 63 are configured to form a spherical surface vertically along the rotation center axis 157. Each moving plate 61 extends in an arc shape between the top 62 and the bottom 63 at a height facing the air blowing port 55.

  The lighting device 80 further includes a light source 82. The light source 82 includes, for example, an LED element and a lens that diffuses light from the LED element into a spherical shape. The light source 82 is provided on the upstream side of the moving plate 61 in the flow direction of the air sent out by the blower 150. The light source 82 is disposed inside the plurality of moving plates 61 arranged in the circumferential direction. The light source 82 is provided inside the spherical wind direction changing device 160.

  When the light source 82 emits light inside the wind direction changing device 160, the moving plate 61 acts as a light shielding plate that blocks light. When the plurality of moving plates 61 are rotated by receiving the air blown from the blower unit 150, it is possible to block light leaking around while rotating.

  The amount of light leaking to the surroundings can be adjusted by the installation angle, pitch, shape, etc. of the movable plate 33. In addition, by partially covering the gap between the moving plates 61 with Japanese paper, a diffusing material, etc., it is possible to produce soft light like a ghost. At this time, by adjusting the rotation speeds of the plurality of moving plates 61, it is possible to realize illumination that reproduces the sunbeams.

  A sound source capable of generating sound may be provided instead of the light source 82. When sound is generated from the sound source, the moving plate 33 functions as a sound insulating plate that blocks sound. When the plurality of moving plates 61 are rotated by receiving the air blown from the blower unit 150, it is possible to perform sound insulation while rotating the sound leaking to the surroundings. At this time, the volume leaked to the surroundings can be adjusted by the installation angle, pitch, shape, etc. of the moving plate 61.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

(Description of the present invention)
Hereinafter, the configuration of the present invention and the effects achieved by the configuration will be described together.

  The apparatus using the fluid feed according to the present invention continuously crosses the cross section intersecting the fluid flow by receiving the force from the fluid feed portion for sending the fluid and the fluid sent by the fluid feed portion. And a moving plate provided.

  According to the fluid feed device configured as described above, the moving plate is provided so as to continuously cross the cross section intersecting the fluid flow by receiving a force from the fluid fed by the fluid feed unit. Therefore, the moving plate can be driven with a simple configuration.

  Preferably, the device using fluid feed includes a plurality of moving plates that are arranged so as to be spaced apart from each other, and are provided so as to traverse in a cross section that intersects the fluid flow in order.

  According to the apparatus using the fluid feed configured as described above, the plurality of movable plates can be driven with a simple configuration.

  Preferably, the plurality of moving plates are arranged in a ring. The apparatus using fluid feed further includes a support unit that rotatably supports a plurality of moving plates. Preferably, the plurality of moving plates are arranged side by side on the circumference.

  According to the apparatus using the fluid feed configured as described above, it is possible to realize a structure in which a plurality of moving plates are provided so as to traverse the cross section intersecting the fluid flow in order with a simple configuration.

  Preferably, the moving plate is provided inclined with respect to the fluid flow direction. Preferably, the moving plate has a blade cross-sectional shape.

  According to the apparatus using the fluid feed configured as described above, the force received by the moving plate from the fluid can be used as a force (driving force) for driving the moving plate.

  Preferably, the moving plate has a surface that receives a force from the fluid sent out by the fluid feeding unit. The surface is a flat surface or a curved surface.

  According to the apparatus using the fluid feed configured as described above, the moving plate can be driven by receiving a force from the fluid on the surface of the moving plate that is a flat surface or a curved surface.

  Preferably, the device using fluid feed includes a plurality of moving plates that are arranged so as to be spaced apart from each other, and are provided so as to traverse in a cross section that intersects the fluid flow in order. The moving plate is inclined with respect to the fluid flow direction. When the angle formed by the fluid flow direction and the moving plate is referred to as an installation angle, the plurality of moving plates are provided so that the installation angles are equal to each other.

  According to the apparatus using the fluid feed configured as described above, the plurality of moving plates can be driven continuously and stably.

  Preferably, the device using fluid feed includes a plurality of moving plates that are arranged so as to be spaced apart from each other, and are provided so as to traverse in a cross section that intersects the fluid flow in order. The moving plate is inclined with respect to the fluid flow direction. When the angle formed by the flow direction of the fluid and the moving plate is referred to as an installation angle, the plurality of moving plates include a first moving plate having an installation angle α and a second moving plate having an installation angle β different from the installation angle α. Including.

  According to the apparatus using the fluid feed configured as described above, it is possible to cause a dynamic change in driving of the plurality of moving plates due to the difference in the installation angle of the moving plates.

  Preferably, the installation angle α satisfies the relationship 0 ° <α <90 °, and the installation angle β satisfies the relationship 0 ° <β <90 °. Preferably, the installation angle α satisfies a relationship of 0 ° <α <90 °, and the installation angle β satisfies a relationship of −90 ° <β <0 °.

  According to the apparatus using the fluid feed configured as described above, various dynamic changes can be generated in driving the plurality of moving plates.

  Preferably, the device using fluid feed includes a plurality of moving plates that are arranged so as to be spaced apart from each other, and are provided so as to traverse in a cross section that intersects the fluid flow in order. The plurality of moving plates include a first moving plate and a second moving plate that are different from each other in distance from the fluid feeding portion in a cross section that intersects the fluid flow.

  According to the apparatus using the fluid feed configured as described above, it is possible to cause a dynamic change in driving of the plurality of moving plates due to a difference in distance from the fluid feeding device to the moving plate.

  Preferably, the device using fluid feed includes a plurality of moving plates that are arranged so as to be spaced apart from each other, and are provided so as to traverse in a cross section that intersects the fluid flow in order. The plurality of moving plates include a first moving plate and a second moving plate having different shapes.

  According to the apparatus using the fluid feed configured as described above, it is possible to cause a dynamic change in driving of the plurality of moving plates due to the difference in the shape of the moving plates.

  Preferably, the device using fluid feed includes a plurality of moving plates that are arranged so as to be spaced apart from each other, and are provided so as to traverse in a cross section that intersects the fluid flow in order. The plurality of moving plates include a plurality of first moving plates arranged at a first pitch and a plurality of second moving plates arranged at a second pitch different from the first pitch.

  According to the apparatus using the fluid feed configured as described above, it is possible to cause a dynamic change in driving of a plurality of moving plates due to a difference in pitch between adjacent moving plates.

  Preferably, the apparatus using fluid feed is arranged on the circumference with a space between each other, and a plurality of moving plates provided so as to cross in a cross section intersecting the fluid flow in order, and a plurality of movements And a support portion that rotatably supports the plate. The moving plate has one end and the other end at both ends along the rotation center axis of the plurality of moving plates and extends non-parallel to the rotation center axis of the plurality of moving plates between the one end and the other end. Provided.

  According to the apparatus using the fluid feed configured as described above, the fluid can be sent out in an arbitrary direction on the basis of the rotation center axes of the plurality of moving plates.

  Preferably, the apparatus using fluid feed further includes a plurality of moving plates. The plurality of moving plates are arranged side by side on the first circumference with a space between each other, and the plurality of first moving plates provided in order to traverse the cross section intersecting the fluid flow in order. A plurality of second moving plates that are arranged concentrically with the first circumference and arranged side by side on a second circumference having a different diameter, and are provided so as to traverse the cross section intersecting the fluid flow in order . The apparatus using fluid feed further includes a support portion that rotatably supports the plurality of first moving plates and the plurality of second moving plates.

  According to the device using the fluid feed configured as described above, the distance from the fluid feed device to the moving plate is different between the first circumference and the second circumference. Dynamic changes in drive can occur.

  Preferably, the apparatus using fluid feeding is arranged side by side on a polygonal side at a distance from each other, and includes a plurality of moving plates provided so as to traverse in a cross section intersecting the fluid flow in order. And a support portion that rotatably supports the movable plate.

  According to the device using the fluid feed configured as described above, the distance from the fluid feed device to the moving plate varies depending on the position on the side of the polygon. Changes can be made.

  Preferably, the apparatus using fluid feed is arranged on the circumference with a space between each other, and a plurality of moving plates provided so as to cross in a cross section intersecting the fluid flow in order, and a plurality of movements And a support portion that rotatably supports the plate. The rotation center axes of the plurality of moving plates are arranged so as to deviate from the center of the circumference where the plurality of moving plates are arranged.

  According to the device using the fluid feed configured as described above, the distance from the fluid feed device to the moving plate varies depending on the timing of rotation of the plurality of moving plates. Changes can occur.

  Preferably, the fluid feeding unit is a blowing unit that sends out air. A moving board changes the direction of the ventilation from a ventilation part.

  According to the device using the fluid feed configured as described above, the direction of the air blown from the blower can be changed with the driving of the moving plate.

  Preferably, the apparatus using fluid feed further includes a light source provided on the upstream side of the moving plate in the flow direction of the fluid fed by the fluid feed section. The fluid feeding unit is a blowing unit that sends out air. The moving plate adjusts the amount of light traveling outward from the light source.

  According to the apparatus using the fluid feed configured as described above, the amount of light traveling from the light source to the outside can be changed as the moving plate is driven.

  The present invention is applied to a blower as an example.

  10, 50 Blower, 31, 31P, 31Q, 33, 61, 61P, 61Q Moving plate, 23, 55 Blower, 21,150 Blower, 22, 52 Fan, 30, 30A, 30B, 160 Wind direction changer, 32, 32P, 32Q, 69 Support portion, 31a surface, 33a positive pressure surface, 33b negative pressure surface, 34 front end portion, 35 rear end portion, 51 base portion, 51n, 53 motor, 54 neck portion, 56 shaft portion, 61j one end, 61k other end, 62 top, 62r recess, 63 bottom, 64 opening, 66 guide, 80 lighting device, 82 light source, 101, 156 central axis, 131, 157 rotation central axis, 133, 134, 137, 138 139 center, 141, 142, 143, 147, 148 circumference, 146 sides.

Claims (7)

A fluid feed section for delivering fluid;
An apparatus using fluid feed, comprising: a moving plate provided so as to continuously traverse the cross section intersecting the fluid flow by receiving a force from the fluid fed by the fluid feed section. A plurality of the moving plates provided at intervals so as to traverse in a cross-section in order crossing the fluid flow;
The plurality of moving plates are arranged in a ring,
The apparatus using fluid feed according to claim 1, further comprising a support portion that rotatably supports the plurality of moving plates. A plurality of the moving plates provided at intervals so as to traverse in a cross-section in order crossing the fluid flow;
The moving plate is provided inclined with respect to the fluid flow direction,
When the angle formed by the flow direction of the fluid and the moving plate is referred to as an installation angle, the plurality of moving plates have different installation angles or different shapes from each other so that the force received by the moving plate from the fluid is different. The apparatus using fluid feed according to claim 1, comprising different first moving plates and second moving bodies. A plurality of the moving plates provided at intervals so as to traverse in a cross-section in order crossing the fluid flow;
4. The plurality of moving plates include a first moving plate and a second moving plate that are different from each other in distance from the fluid feeding unit in a cross section intersecting with a fluid flow. 5. Equipment using fluid feed. A plurality of the moving plates, which are arranged side by side on the circumference at intervals, and are provided so as to traverse in a cross section intersecting the fluid flow in order,
A support portion for rotatably supporting the plurality of moving plates;
The moving plate has one end and the other end at both ends along the rotation center axis of the plurality of moving plates, and between the one end and the other end with respect to the rotation center axes of the plurality of moving plates. The apparatus using fluid feed according to claim 1, wherein the apparatus is provided so as to extend non-parallel. A plurality of the moving plates, which are arranged side by side on the circumference at intervals, and are provided so as to traverse in a cross section intersecting the fluid flow in order,
A support portion for rotatably supporting the plurality of moving plates;
The apparatus using fluid feeding according to any one of claims 1 to 5, wherein a rotation center axis of the plurality of moving plates is arranged to be deviated from a center of a circumference in which the plurality of moving plates are arranged. A light source provided on the upstream side of the moving plate in the flow direction of the fluid sent out by the fluid feed unit;
The fluid feeding part is a blowing part that sends out air,
The apparatus using fluid feed according to any one of claims 1 to 6, wherein the moving plate adjusts a light amount of light traveling outward from the light source.

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