EP3726066B1 - Ensemble de tête de ventilateur pour appareil de soufflage d'air sans pale, appareil de soufflage d'air sans pale, tête pour ventilateur sans pale et ventilateur sans pale - Google Patents
Ensemble de tête de ventilateur pour appareil de soufflage d'air sans pale, appareil de soufflage d'air sans pale, tête pour ventilateur sans pale et ventilateur sans pale Download PDFInfo
- Publication number
- EP3726066B1 EP3726066B1 EP18890517.8A EP18890517A EP3726066B1 EP 3726066 B1 EP3726066 B1 EP 3726066B1 EP 18890517 A EP18890517 A EP 18890517A EP 3726066 B1 EP3726066 B1 EP 3726066B1
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- European Patent Office
- Prior art keywords
- air
- air channel
- guide
- section
- guide surface
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
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- 230000007704 transition Effects 0.000 claims description 89
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Images
Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04F—PUMPING OF FLUID BY DIRECT CONTACT OF ANOTHER FLUID OR BY USING INERTIA OF FLUID TO BE PUMPED; SIPHONS
- F04F5/00—Jet pumps, i.e. devices in which flow is induced by pressure drop caused by velocity of another fluid flow
- F04F5/14—Jet pumps, i.e. devices in which flow is induced by pressure drop caused by velocity of another fluid flow the inducing fluid being elastic fluid
- F04F5/16—Jet pumps, i.e. devices in which flow is induced by pressure drop caused by velocity of another fluid flow the inducing fluid being elastic fluid displacing elastic fluids
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04D—NON-POSITIVE-DISPLACEMENT PUMPS
- F04D25/00—Pumping installations or systems
- F04D25/02—Units comprising pumps and their driving means
- F04D25/08—Units comprising pumps and their driving means the working fluid being air, e.g. for ventilation
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04F—PUMPING OF FLUID BY DIRECT CONTACT OF ANOTHER FLUID OR BY USING INERTIA OF FLUID TO BE PUMPED; SIPHONS
- F04F5/00—Jet pumps, i.e. devices in which flow is induced by pressure drop caused by velocity of another fluid flow
- F04F5/44—Component parts, details, or accessories not provided for in, or of interest apart from, groups F04F5/02 - F04F5/42
Definitions
- the disclosure relates to the field of domestic appliances, and particularly to a fan head component for a bladeless blowing device, a bladeless blowing device, a head for a bladeless fan, and a bladeless fan.
- a bladeless fan generates high-pressure air through a drive system, and the high-pressure air enters an air channel and is emitted through nozzles.
- the existing bladeless fan after the high-pressure air enters the air channel from an air inlet, the closer the air emitted from the nozzle to the lower side of the air channel, the larger the flow rate, and the closer the air emitted from the nozzle to the upper side of the air channel, the lower the flow rate.
- the flow rates of the air emitted from the nozzles are not uniform in the vertical direction in which the nozzles extend, and the user experience is poor.
- CN 106762852 A discloses a fan head for a bladeless fan, characterized in having a sound proof part in the inner side of the exhaust passage.
- the air channel of the fan head is provided with an inclined wind-guiding face, which inclines towards to exhaust passage in the direction of air-flow, in order to strengthen the flow rate of emitted air.
- the bladeless ring fan assembly disclosed in GB 2509760 A is in particularly used for a ceiling fan.
- the separation of the upper wall and lower wall of the interior passage for air to flow through is designed to decrease gradually from one end to the other end of the interior passage, in order to maintain a substantially constant air stream velocity within the outlet section.
- KR 101203378 B1 provides a ring nozzle for bladeless electric fan.
- a series of jet guide plates are disposed inside the inner passage through where the air flows through, and as a combined result of the multiple jet guide plates, the space within the inner passage where air can flow through decrease in the direction of air-flow, so as to emit a uniform wind from the injection nozzle area.
- CN 102661294 A depicts a nozzle ring for a vaneless fan, whose inner circular passage for air to flow through is waned gradually from lower to upper, therefore on the one hand, ensuring the gas velocity squirted from the opening of the nozzle ring is the same; and on the other hand, achieving the characterized shape of a dropping water to the nozzle ring.
- the embodiments of the disclosure are expected to provide a fan head component for a bladeless blowing device, a bladeless blowing device, a head for a bladeless fan, and a bladeless fan to improve the uniformity of the flow rates of the air emitted from nozzles and enhance the user experience.
- a fan head component for a bladeless blowing device includes an air output portion.
- the air output portion includes an air inlet, a nozzle and an air channel, both the air inlets and the nozzle are communicated with the air channel.
- the air channel has a variable cross-section portion, an air flow area corresponding to the variable cross-section portion varies continuously in a vertical direction. The air flow area corresponding to a lower end of the variable cross-section portion is greater than the air flow area corresponding to an upper end of the variable cross-section portion.
- variable cross-section portions are positioned at an upper part and/or a middle part of the air channel.
- a side wall of the air output portion is tapered inwardly in the vertical direction to form the variable cross-section portion.
- the nozzle extends along the vertical direction of the air channel.
- the fan head component includes a guide device disposed in the air channel.
- the guide device includes a first guide member having a first guide surface which obliquely extends downward to block a part of intake air.
- the air flow area of the air channel corresponding to the lower end of the first guide surface is greater than the air flow area of the air channel corresponding to the upper end of the first guide surface.
- a corresponding part of the air channel between the lower end and the upper end of the first guide surface is the variable cross-section portion.
- the first guide member is of plate shape, and the first guide member obliquely extends downward from the upper end of the air channel.
- the first guide surface faces toward the nozzle to guide a part of intake air to the nozzle.
- the nozzle is disposed at the first side of the air output portion.
- the first guide member is disposed at the second side of the air output portion opposite to the first side. The edge of the first guide member is tightly connected with the inner wall of the second side of the air output portion.
- the first guide surface faces toward the side wall of the air output portion, and the edge of the first guide member is tightly connected with the side wall of the air output portion.
- the guide device further includes a second guide member positioned above the first guide member.
- the second guide member has a second guide surface which obliquely extends upward.
- the lower end of the second guide surface is connected with the upper end of the first guide surface.
- the air flow area of the air channel at the lower end of the second guide surface is less than the air flow area of the air channel at the upper end of the second guide surface.
- the second guide surface is a flat surface, an arc surface or a combination of a flat surface and an arc surface
- the first guide surface is a flat surface, an arc surface or a combination of a flat surface and an arc surface.
- the air flow area of the corresponding air channel gradually increases.
- the guide device includes a third guide member having a third guide surface, and the second guide surface is in smooth transition connection with the first guide surface through the third guide surface.
- the air output portion includes a front air output member and a rear air output member.
- the front air output member and the rear air output member together define the air channel.
- the nozzle is disposed at a front side of the front air output member, and the guide device is tightly connected to a rear side of the rear air output member.
- the guide device is integrated with the rear air output member.
- one of the front air output member and the rear air output member is provided with a positioning slot, the other one is provided with a positioning protrusion matching with the positioning slot.
- the front air output member and the rear air output member are connected to one another through ultrasonic welding or gluing.
- the fan head component further includes a housing covering the outside of the air output portion.
- the air flow area of the corresponding air channel gradually decreases.
- the air output portion further includes reinforcing ribs disposed in the air channel. Two ends of the reinforcing ribs are fixedly connected with the inner walls of the left and right sides of the air channel.
- the nozzle extend along the vertical direction of the air channel.
- the plurality of guide devices are disposed along the vertical direction of the air channel and spaced from one another, and the plurality of guide devices are disposed to correspond to the nozzle.
- a fan head component for a bladeless blowing device includes an air output portion which comprises an air inlet, a nozzle and an air channel. Both the air inlet and the nozzle are communicated with the air channel.
- the air channel comprises a first end and a second end.
- An air flow direction is a direction from the first end to the second end of the air channel.
- the air channel comprises a variable cross-section portion.
- An air flow area of the variable cross-section portion continuously varying along the air flow direction. The air flow area corresponding to an end of the variable cross-section portion adjacent to the first end being greater than the air flow area corresponding to an end of the variable cross-section portion adjacent to the second end.
- the side wall of the air output portion is tapered inward to form the variable cross-section portion.
- the nozzle extends along the air flow direction of the air channel.
- the fan head component includes a guide device disposed in the air channel.
- the guide device includes a first guide member having a first guide surface.
- the first guide surface obliquely extends relative to the air flow direction to block a part of intake air.
- a part of the air channel at a position corresponding to the first guide surface is the variable cross-section portion.
- the first guide surface faces toward the nozzle to guide a part of intake air to the nozzle.
- the guide device further includes a second guide member positioned adjacent to the second end.
- the second guide member has a second guide surface which obliquely extends relative to the air flow direction.
- the second guide surface is connected with the first guide surface.
- the air flow area of the air channel corresponding to the end of the second guide surface adjacent to the first guide surface is less than the air flow area of the air channel corresponding to the end of the second guide surface away from the first guide surface.
- the air flow area of the air channel corresponding to the second guide surface gradually increases along the air flow direction.
- a bladeless blowing device includes a base, a drive system disposed in the base, and any one of the above fan head components.
- the fan head component is connected with the base to receive the intake air generated by the drive system through the air inlet and emit the intake air through the nozzle.
- the bladeless blowing device is any one of a bladeless fan, a bladeless blower, a bladeless heater, a bladeless humidifier and a bladeless cooler.
- a head for a bladeless fan is provided.
- An air channel is formed in the head, the air channel has a first end and a second end.
- the first end of the air channel is provided with an air inlet.
- An air flow direction is a direction from the first end to the second end of the air channel.
- the wall of the air channel is provided with an air outlet which passes through the wall of the air channel in a direction perpendicular to the air flow direction.
- the air outlet is arranged along the air flow direction.
- a transition section is formed between the first end and the second end of the air channel. The flow area of the transition section gradually varies in the air flow direction.
- the transition section includes a first sub-section, and the flow area of the first sub-section gradually decreases in the air flow direction.
- one end of the first sub-section extends to the first end of the air channel or is spaced from the first end of the air channel, and the other end of the first sub-section extends to the second end of the air channel.
- the first sub-section is spaced from the second end of the air channel.
- the transition section further includes a second sub-section. One end of the second sub-section is connected with the first sub-section, the other end of the second sub-section extends toward the second end of the air channel. The flow area of the second sub-section gradually increases in the air flow direction.
- the length of the second sub-section in the air flow direction is greater than the length of the first sub-section in the air flow direction.
- the transition section directly faces at least a part of the air outlet.
- the wall of the air channel protrudes toward an inside of the air channel to form the transition section.
- the head includes a first air channel member and a second air channel member.
- the air channel is formed in each of the first air channel member and the second air channel member.
- One end of the first air channel member is connected and communicated with one end of the second air channel member, or one end of the first air channel member is connected with one end of the second air channel member by a connector.
- the air channel in the first air channel member is spaced from the air channel in the second air channel member.
- the head includes a first air channel member, a second air channel member and a connector.
- the first air channel member extends along a vertical direction.
- the second air channel member also extends along the vertical direction.
- the first air channel member and the second air channel member are spaced from one another in a left-right direction and parallel to each other and are parallel to each other.
- One end of the connector is connected with an upper end of the first air channel member and another end is connected with the upper end of the second air channel member.
- the air channel is formed in each of the first air channel member and the second air channel member.
- the lower end of the air channel is the first end, and the upper end of the air channel is the second end.
- a bladeless fan includes a base, a head and an air generation device.
- the head is any one of the above heads for a bladeless fan and is installed on the base.
- the air generation device is disposed in the base and configured to supply air into the air channel.
- the flow rate of the intake air is increased during the intake air flows through the variable cross-section portions, so that the flow rates of the air emitted from the nozzle located at corresponding position of the variable cross-section portion are relatively uniform, and the user experience is enhanced.
- orientation words “upper”, “lower”, “front”, “rear”, “left”, “right”, and the like used in the specific implementation of the disclosure refer to the orientation words under the normal use of a bladeless blowing device.
- “Front” refers to the side facing a user
- “rear” refers to the side facing away from the user.
- FIG. 5 As an example, "front” is an outward direction perpendicular to the plane of the paper shown in FIG. 5 , “rear” is an inward direction perpendicular to the plane of the paper shown in FIG. 5 , “upper” and “lower” are vertical direction shown in FIG. 5 , and “left” and “right” are left and right directions shown in FIG. 5 .
- an “ejection angle” is an angle between the direction of the air emitted from the nozzle and the horizontal direction shown in FIG. 5 .
- the “air flow area” refers to the area of the air output portion 10 in the cross section along the horizontal direction shown in FIG. 5 , through which the intake air flows upward in the air channel 11.
- the “first side” and the “second side” refer to directions.
- the “side walls of the air output portion” refer to all side walls of the housing of the air output portion 10 that form the air channel 11, and include a left side wall 101a, a right side wall 101b, a front side wall and a rear side wall of the air channel 11.
- the specific implementation of the disclosure provides a bladeless blowing device, including a base (not shown), a drive system (not shown) disposed in the base, and a fan head component.
- the fan head component is connected with the base to receive the intake air generated by the drive system and emit the intake air outward.
- a bladeless fan as an example of the bladeless blowing device.
- the type of the bladeless blowing device is not limited to the bladeless fan.
- the bladeless blowing device may also be any one of a bladeless blower, a bladeless heater, a bladeless humidifier and a bladeless cooler.
- the fan head component includes an air output portion 10 and a housing 30.
- the air output portion 10 includes air inlets 13, nozzles 12 and air channels 11, and both the air inlets 13 and the nozzles 12 are communicated with the air channels 11.
- the overall shape of the air output portion 10 is not limited, and may be a circular ring shape, an ⁇ shape, a polygonal shape, and the like.
- a cavity inside the air output portion 10 forms the air channel 11, and the shape of the air channel 11 matches with the shape of the air output portion 10.
- the air output portion 10 is substantially in a bilaterally symmetrical n-shaped structure, the number of the air inlets 13 is two, and an air inlet 13 is respectively formed at the lower part of each of the air channels 11 at the left and right sides of the ⁇ -shaped air output portion 10.
- the nozzle 12 of the air output portion 10 is disposed at the first side of the air output portion 10, and the first side may be a front side of the air output portion 10 facing a user or a rear side facing away from the user.
- the nozzle 12 may extend along the vertical direction of the first side and is in a long slit structure with a small width.
- the drive system in the base generates intake air with pressure, the intake air enters the air channel 11 from the base through the air inlet 13. During the movement of the intake air from bottom to top in the air channel 11, the intake air will be continuously emitted from the nozzle 12.
- the air output portion 10 is not limited.
- the left side wall 101a, the right side wall 101b, the front side wall and the rear side wall of the air output portion 10 may be integrally formed.
- the air output portion 10 in order to facilitate demolding during production, includes a front air output member 14 and a rear air output member 15, the front air output member 14 and the rear air output member 15 are tightly jointed to one another, the inside of each of the front air output member 14 and the rear air output member 15 is a hollow cavity, and the two hollow cavities together define the above air channel 11.
- the nozzle 12 is disposed at the front side of front air output member 14, that is, the first side of the air output portion 10.
- the corresponding positions of the front air output member 14 and the rear air output member 15 are provided with a positioning slot 141 and a positioning protrusion 151 which are matched to each other.
- the positioning protrusion 151 is clamped into the positioning slot 141, that is, the relative positions of the front air output member 14 and the rear air output member 15 are preset, so as to facilitate the subsequent hermetic connection.
- the front air output member 14 and the rear air output member 15 may be connected to one another by gluing or ultrasonic welding at the joint position.
- the air output portion 10 since the air output portion 10 generally has a flat thin-walled structure, when the air output portion 10 is subjected to external pressure, the shape of the internal air channel 11 easily changes, thereby affecting the fluid distribution in the air channel 11. Therefore, referring to FIG. 5, FIG. 6 and FIG. 7 , the air output portion 10 further includes reinforcing ribs 16 disposed in the air channel 11, and two ends of the reinforcing ribs 16 are fixed between the left side wall 101a and the right side wall 101b of the air channel 11. Specifically, the reinforcing ribs 16 are disposed on the side walls of the left and right sides in the front air output member 14 and/or the rear air output member 15.
- the housing 30 covers the outside of the air output portion 10. Specifically, the housing 30 covers the outside of the front air output member 14 and the rear air output member 15 to play a role in beautifying the fan component.
- the housing 30 may be connected with the air output portion 10 by means of bolts, screws or clamping.
- the air channel 11 has variable cross-section portions, the air flow areas corresponding to the variable cross-section portions continuously vary from bottom to top, and the air flow area corresponding to the lower end of the variable cross-section portion is greater than the air flow area corresponding to the upper end of the variable cross-section portion.
- the "continuous vary” means that there is no larger sudden vary in the value of the air flow area.
- the variable cross-section portion is substantially in a form with a large lower part and a small upper part.
- the air flow area of the variable cross-section portion may gradually decrease linearly, or may be in a substantially decreasing trend in a slower curve.
- the intake air is continuously squeezed, and the air flow rate is continuously increased to reduce the flow rate difference of the air emitted from the nozzle 12 in the vertical direction, so that the rate of the air emitted from the nozzle 12 in the vertical direction corresponding to the variable cross-section portion is relatively uniform, and the user experience is improved.
- variable cross-section portion refers to the air channel 11 with a variation in a cross-section of air flow area along the vertical direction of the air channel 11.
- variable cross-section portion may be positioned at the upper part or the middle part of the air channel 11, or both the upper part and the middle part of the air channel 11 are provided with variable cross-section portions.
- variable cross-section portion may be provided, or a plurality of variable cross-section portions may be provided and are spaced from one another along the vertical direction of the air channel 11.
- the side wall 101 of the air output portion 10 may be tapered inward to form the variable cross-section portion.
- the left side wall 101a and/or the right side wall 101b of the air output portion 10 may incline to the inside of the air channel 11 to form the variable cross-section portion
- the front side wall and/or the rear side wall of the air output portion 10 may incline to the inside of the air channel 11 to form the variable cross-section portion.
- the "front side wall of the air output portion 10" is a side wall corresponding to the first side of the air output portion 10
- the "rear side wall of the air output portion 10" is a side wall corresponding to the second side opposite to the first side. Referring to FIG. 6 , in the second embodiment provided by the specific implementation I, the right side wall 101b of the air output portion 10 inclines to the inside of the air channel 11.
- a guide device is additionally disposed in the air channel 11 in the air output portion 10 to form the variable cross-section portion.
- the fan head component further includes a guide device 20 disposed in the air channel 11.
- the guide device 20 includes a first guide member 21.
- the first guide member 21 has a first guide surface 21a.
- the first guide surface 21a obliquely extends downward in the air channel 11 to block a part of intake air.
- the air flow area of the air channel 11 corresponding to the lower end of the first guide surface 21a is greater than the air flow area of the air channel 11 corresponding to the upper end of the first guide surface 21a, and the corresponding part of the air channel 11 between the lower end and the upper end of the first guide surface 21a is the variable cross-section portion. Further, the first guide surface 21a faces toward the nozzle 12 to guide part of intake air from the air inlet 13 to the nozzle 12.
- the first guide surface 21a may face toward any direction of the air output portion 10. Referring to FIG. 7 , in the third embodiment provided by the specific implementation I, the first guide surface 21a faces toward the left side wall 101a and/or the right side wall 101b of the air output portion 10. Specifically, the first guide member 21 is in a plate shape with a longer length, the first guide member 21 in the plate shape is positioned at the second side of the air output portion 10 adjacent to the upper part, the first guide member 21 obliquely extends gradually downward from the upper end of the air channel 11, and the periphery in a plate shape is tightly connected with the inner wall of the air output portion 10.
- the intake air of a bladeless fan enters an air channel from an air inlet and then is emitted obliquely upward from a nozzle at a higher speed and a larger ejection angle, instead of being blown to a user in a horizontal direction, resulting in poor user experience.
- the first guide surface 21a is disposed facing toward the nozzle 12. Under the guide action of the first guide surface 21a, the movement direction of a part of intake air gradually varies from vertical upward movement to movement in a direction facing toward the nozzle 12.
- the intake air is continuously squeezed and guided toward the nozzle 12, and then, a part of intake air may be emitted from the nozzle 12 at a smaller ejection angle under the guide action of the first guide surface 21a, so as to effectively improve the phenomenon that the intake air is emitted obliquely upward from the nozzle 12 to enhance the user experience. Since the ejection angle of the air emitted from the nozzle 12 is reduced, the turbulence phenomenon may be effectively inhibited, and the user experience may be further enhanced.
- the first guide surface 21a On the first guide surface 21a, the disturbance to the air by structures, such as sharp corners, should be avoided as much as possible.
- the first guide surface 21a may be a flat surface, an arc surface, or a combination of a flat surface and an arc surface.
- the position of the first guide member 21 is not limited.
- the first guide member 21 may be disposed on the left side wall 101a or the right side wall 101b of the air output portion 10, or may be disposed on the inner wall of the second side of the air output portion 10, that is, the rear side wall of the air output portion 10, and the edge of the first guide member 21 is tightly connected with the inner wall of the second side of the air output portion 10.
- the first guide member 21 is disposed at the rear side of the rear air output member 15, and is tightly connected with the inner wall of the rear side of the rear air output member 15.
- the first guide member 21 is integrally formed on the inner wall of the rear side of the rear air output member 15.
- the fan component is simple and compact in structure and convenient to produce and process.
- all the intake air flows through the space between the first guide member 21 and the first side of the air output portion 10, and the first guide surface 21a may achieve a better guide effect on the intake air.
- the number of the first guide members 21 may be set according to actual use needs, and may be one or more. Each of the first guide members 21 corresponds to a variable cross-section portion. For example, referring to FIG. 1 to FIG. 5 , in the first embodiment, the number of the first guide members 21 is two, and the two first guide members 21 are spaced from one another in a vertical direction in the air channel 11. Referring to FIG. 1 to FIG. 5 , in the first embodiment, the number of the first guide members 21 is two, and the two first guide members 21 are spaced from one another in a vertical direction in the air channel 11. Referring to FIG.
- the number of the first guide member 21 is one, the first guide member 21 is in plate shape with a longer length, the first guide surface 21a faces toward the nozzle 12, the first guide member 21 in the plate shape is positioned at the second side of the air output portion 10 adjacent to the upper part, the first guide member 21 obliquely extends gradually downward from the upper end of the air channel 11, and the periphery in a plate shape is tightly connected with the inner wall of the air output portion 10.
- the "plate shape” should be understood to include a straight plate shape and a slightly curved plate shape with a certain radian.
- the extension length of the first guide member 21 may be correspondingly changed according to actual needs.
- the guide device 20 further includes a second guide member 22, the second guide member 22 is positioned above the first guide member 21, the second guide member 22 has a second guide surface 22a which obliquely extends upward, the lower end of the second guide surface 22a is connected with the upper end of the first guide surface 21a, and the connection may be direct connection or smooth transition connection through an intermediate structure.
- the guide device 20 further includes a third guide member 23, the third guide member 23 has a third guide surface 23a, and the first guide surface 21a is in smooth transition connection with the second guide surface 22a through the third guide surface 23a of the third guide member 23.
- the first guide surface 21a, the second guide surface 22a and the third guide surface 23a are in smooth transition connection to achieve a better guide effect.
- the second guide surface 22a may guide the intake air which continues to move upward after bypassing the first guide surface 21a, so as to prevent the occurrence of the vortex phenomenon at the upper position of the first guide member 21.
- the air flow area of the air channel 11 corresponding to the lower end of the second guide surface 22a is less than the air flow area of the air channel 11 corresponding to the upper end of the second guide surface 22a, so as to achieve a damping effect on the upward moving intake air. Further, the air flow area of the corresponding part of the air channel 11 between the lower end of the second guide surface 22a and the upper end of the second guide surface 22a gradually increases. That is, in the present embodiment, the air flow area of the air channel 11 at the corresponding position of the guide device gradually is tapered from bottom to top and then gradually expands.
- the shape of the second guide surface is not limited.
- the second guide surface may be a flat surface, an arc surface, or a combination of a flat surface and an arc surface.
- the position of the second guide member 22 needs to be matched with the position of the first guide member 21.
- the second guide member 22 is also correspondingly disposed at the rear side of the rear air output member 15.
- the number of the second guide member 22 is determined according to actual needs. When there are a plurality of second guide members 22, a plurality of second guide members 22 are spaced from one another in the vertical direction of the air channel 11. It should be noted that the first guide member 21 of the disclosure does not need to be disposed in one-to-one correspondence with the second guide member 22. That is, the first guide member 21 may have a matched second guide member 22, or may have no matched second guide member 22.
- the guide device 20 may be in a split type structure or an integrated structure.
- the first guide member 21 may be in a split type structure or an integrated structure
- the second guide member 22 may be in a split type structure or an integrated structure.
- the first guide member 21, the second guide member 22 and the rear side of the rear air output member 15 are in an integrated structure.
- the working processes of the fan head component according to the embodiment of the disclosure are as follows:
- the intake air from the air inlet 13 enters the air channel 11, when the intake air enters the first variable cross-section portion, that is, encounters the first guide surface 21a of the guide device 20, the intake air is continuously squeezed, the air flow rate continuously increases, the flow rate of the air emitted from the nozzle 12 in the vertical direction corresponding to the first variable cross-section portion is relatively uniform, and the flow direction of the intake air is changed under the action of the first guide surface 21a, so that a part of intake air is emitted from the nozzle 12 at a smaller ejection angle.
- the intake air which is not emitted from the nozzle 12 bypasses the first guide surface 21a and continues to move upward to encounter the second guide surface 22a, the air flow area increases to achieve a damping effect on the intake air, the intake air continues to move upward to encounter the first guide surface 21a of the second guide device 20, and similarly, the function analysis of the second guide device 20 is the same as above and will not be described here.
- the guide device 20 should be disposed in this region.
- the air channel 11 includes a first end and a second end, and the air flow direction is from the first end to the second end of the air channel 11.
- the direction from bottom to top in the above specific implementation is the air flow direction in this specific implementation.
- the direction from bottom to top in FIG. 5 is the air flow direction
- the first end of the air channel is positioned below FIG. 5
- the second end of the air channel is positioned above FIG. 5 .
- the air flow area of the variable cross-section portion along the air flow direction continuously varies, and the air flow area corresponding to the end adjacent to the first end of the variable cross-section portion is greater than the air flow area corresponding to the end adjacent to the second end.
- the air flow direction substitutes for the direction from bottom to top in the above specific implementation I.
- Other structures are the same as those in the above embodiment, and will not be described here.
- the head 100 for the bladeless fan 1000 according to the embodiment of the first aspect in the specific implementation II will be described below with reference to FIG. 12 to FIG. 22 .
- air channels 11 are formed in the head 100 for the bladeless fan 1000 according to the embodiment of the first aspect.
- two ends in an extension direction of the air channel 11 are a first end 10A and a second end 10B.
- the first end 10A of the air channel 11 is provided with air inlets 13, and the air flow direction is from the first end 10A to the second end 10B of the air channel 11.
- the wall of the air channel 11 is provided with air outlets 101 communicated with the air channel 11 and arranged along a direction from the first end 10A to the second end 10B.
- the air outlets 101 penetrate through the wall of the air channel 11 along a direction perpendicular to the air flow direction, and the air outlets 101 are arranged along the air flow direction.
- a transition section 103 is formed between the first end 10A and the second end 10B of the air channel 11, and the flow area of the transition section 103 (the internal areas of cross sections perpendicular to the air flow direction) gradually varies in the air flow direction.
- the head 100 for the bladeless fan 1000 is provided with the transition sections 103, so that internal air distribution of the air channel 11 may be improved, the noise is reduced, the exhausted air of the head 100 may be more uniform on the overall air output plane, the air output effect of the head 100 is effectively improved, and the user experience is greatly enhanced.
- the air outlet 101 may be a long hole extending from the first end 10A to the second end 10B, or may be a plurality of small holes spaced along the direction from the first end 10A to the second end 10B.
- the air may enter the air channel 11 from the first end 10A and move along the air channel 11 toward the second end 10B, and a part of air may be ejected through the air outlet 101 at the same time while moving from the first end 10A to the second end 10B.
- the sudden variation in the flow area means that the flow area suddenly changes.
- the arrangement of a step surface in the air channel 11 will cause a sudden variation in the flow area at the corresponding position of the air channel 11.
- the flow area of the section M firstly keeps an initial value F1 unchanged along the direction from the first end 10A to the second end 10B, then suddenly changes to a value F2 and continues to keep the value F2 unchanged, and then suddenly changes to another value F3 and continues to keep the value F3 unchanged, thereby indicating that the flow area of the M section may not take any one of the values F1 and F2, also may not take any one of the values F2 and F3, and may only take the three values F1, F2 and F3.
- the flow area of the M section gradually changes along the direction from the first end 10A to the second end 10B, for example, from the value F1 to the value F3, it indicates that the flow area of the M section may take any one of the values F1, F2 and F3.
- the concept of the "flow area" is well known to those skilled in the art, and will not be described in detail here.
- the air channel 11 may be a transition section 103 as a whole, or a part of the air channel 11 may form the transition section 103. If only a part of the air channel 11 forms the transition section 103, at this time, the flow area of one section or more sections of the air channel 11 except the transition section 103 is unchanged, and the flow area from the transition section 103 to the non-transition section 103 also gradually varies (non-sudden variation).
- the air channel 11 may be vertically disposed.
- the air channel 11 may be absolutely vertically disposed at an included angle of 90° crossing the horizontal plane, the air channel 11 may also be non-absolutely vertically disposed at an included angle greater than 45° crossing the horizontal plane, and the air channel 11 may also be set to have a variable included angle with the horizontal plane. Therefore, all-round air supply may be formed.
- the disclosure is not limited thereto.
- the air channel 11 may also be horizontally disposed (the embodiment is not shown in figures).
- the air channel 11 may be absolutely horizontally disposed at an included angle of 0° crossing the horizontal plane, and the air channel 11 may also be non-absolutely horizontally disposed at an included angle less than 45° crossing the horizontal plane.
- the air channel 11 is taken as an example for description. After reading the following technical solutions, those skilled in the art may think of the technical solutions for the horizontal disposition of the air channel 11.
- the ratio of the interval between each of the transition sections 103 and the first end 10A (that is, the distance between the end point of the transition section 103 closest to the first end 10A and the first end 10A) to the length of the air channel 11 (X1/L and X2/L shown in FIG. 15 , X3/L shown in FIG. 19 , X4/L and X5/L shown in FIG. 20 , and X6/L shown in FIG. 21 ) is greater than or equal to 1/8, thereby indicating that the transition section 103 is not tightly adjacent to the first end 10A and is not connected with the first end 10A.
- the interval between the inlet end of the transition section 103 and the air inlet of the air channel 11 is not less than a preset ratio of the length of the air channel 11.
- the preset ratio may be 1/8, or the preset ratio may be set to any value between 1/10 and 4/5.
- the preset ratio may be set to 1/8, 1/7, 1/6, 1/5, 1/4, and the like.
- the air channel 11 includes transition sections 103, the flow area of each of the transition sections 103 gradually changes in the direction from the first end 10A to the second end 10B, and the flow area of at least one section of each of the transition sections 103 gradually decreases in the direction from the first end 10A to the second end 10B.
- each transition section 103 includes a first sub-section, and the flow area of the first sub-section (not shown) in the air flow direction gradually decreases.
- one end of the first sub-section extends to the first end 10A of the air channel 11.
- the first sub-section may also be spaced from the first end 10A of the air channel 11.
- one end of the first sub-section is disposed at the middle part between the first end 10A and the second end 10B of the air channel 11; or, one end of the first sub-section extends to be spaced from the first end 10A or the second end 10B of the air channel 11 by 1/8L, wherein L is the length of the air channel 11.
- the other end of the first sub-section may extend to the second end 10B of the air channel 11.
- At least one of the other end of the first sub-section dooes not extend to the second end 10B of the air channel 11.
- the other end of the first sub-section is spaced from the second end 10B of the air channel 11.
- a second sub-section needs to be disposed to achieve smooth transition of the air.
- the first sub-section is spaced from the second end 10B of the air channel 11
- the transition section 103 further includes a second sub-section (not shown), one end of the second sub-section is connected with the first sub-section, the other end of the second sub-section extends toward the second end 10B of the air channel 11, and the flow area of the second sub-section in the air flow direction gradually increases.
- the length of the second sub-section in the air flow direction is greater than the length of the first sub-section in the air flow direction.
- the second sub-section is gentler than the first sub-section.
- the transition section 103 directly faces at least a part of the air outlet 101.
- the transition section 103 is disposed in a region on the air channel 11 with the air outlet 101.
- a plurality of transition sections 103 are also arranged to be spaced from one another along the air flow direction.
- the transition section 103 is disposed in at least one of the midstream side of the air flow direction of the air channel 11, the upstream side of the air flow direction of the air channel 11, the downstream side of the air flow direction of the air channel 11, and the like.
- different lengths of the transition section 103 may be selected, so as to achieve more uniform air output.
- the lengths of a plurality of transition sections 103 are set to be exactly the same.
- the lengths of a plurality of transition sections 103 may be different or partially different.
- the length of the transition section 103 refers to the size of the transition section 103 along the air flow direction.
- the lengths of a plurality of transition sections 103 are the same or different.
- the interval between every two adjacent transition sections 103 may be the same or different.
- the three transition sections are respectively expressed as A, B and C.
- the interval between A and B is A-B
- the interval between B and C is B-C
- the interval A-B and the interval B-C may be the same or different.
- the interval between two transition sections 103 refers to the gap between two transition sections 103, or the interval between adjacent ends of two adjacent transition sections 103 in the air flow direction.
- the interval between two transition sections 103 refers to the interval between the upper end of the lower one of the two transition sections 103 and the lower end of the upper one.
- transition section 103 in the disclosure may be formed by the wall of the air channel 11 protruding toward the inside of the air channel 11, or may be of a protruded structure formed on the inner surface of the air channel 11.
- a convex surface protruding toward the inside of the air channel 11 may be formed on the air channel 11 to form the transition section 103.
- the convex structure 5 is disposed at a position opposite to the air outlet 101.
- the convex structure 5 is formed on the inner surface between the first end 10A and the second end 10B of the air channel 11, the convex structure 5 directly faces at least a part of the air outlet 101, the convex structure 5 protrudes toward the air outlet 101, and the transition section 103 is formed by the convex structure 5.
- the surface opposite to the air outlet 101 in the air channel 11 extends smoothly along the air flow direction.
- the convex structure 5 directly faces the air outlet 101.
- the air outlet 101 is formed on the front side wall of the air channel 11, the convex structure 5 is positioned inside the rear side wall of the air channel 11, and the convex structure 5 directly faces the air outlet 101.
- the air channel 11 includes at least one convex structure 5, each of the convex structures 5 at least includes a first sub-convex surface 51, and the first sub-convex surface 51 inclines toward the air outlet 101 in the air flow direction.
- the first sub-convex surface 51 may be in a flat shape, or may be in a shape that gradually changes from a concave surface to a convex surface in the air flow direction.
- F(x)' represents the first derivative of the function F(x)
- F(x)" represents the second derivative of F(x).
- one end of the first sub-convex surface 51 extends to the first end 10A of the air channel 11.
- the first sub-convex surface 51 may also be spaced from the first end 10A of the air channel 11.
- one end of the first sub-convex surface 51 is disposed at the middle part between the first end 10A and the second end 10B of the air channel 11; or, one end of the first sub-convex surface extends to be spaced from the first end 10A or the second end 10B of the air channel 11 by 1/8L, wherein L is the length of the air channel 11.
- first sub-convex surface 51 may extend to the second end 10B of the air channel 11.
- the other end of the first sub-convex surface 51 may not extend to the second end 10B of the air channel 11.
- the other end of the first sub-convex surface 51 is spaced from the second end 10B of the air channel 11.
- a second sub-convex surface 52 needs to be disposed to achieve smooth transition of the air.
- the transition section 103 further includes a second sub-convex surface 52, one end of the second sub-convex surface 52 is connected with the first sub-convex surface 51, the first sub-convex surface 51 and the second sub-convex surface 52 are in smooth transition, the other end of the second sub-convex surface 52 extends toward the second end 10B of the air channel 11, and the second sub-convex surface 52 inclines toward a direction away from the air outlet 101 in the air flow direction.
- the length of the second sub-convex surface 52 in the air flow direction is greater than the length of the first sub-convex surface 51 in the air flow direction. In other words, the second sub-convex surface 52 is gentler than the first sub-convex surface 51.
- the convex structure 5 is disposed on the surface of one side away from the air outlet 101 in the air channel 11, so that the air channel 11 includes at least one transition section 103.
- the flow area of each of the transition sections 103 gradually changes in the direction from the first end 10A to the second end 10B, and the flow area of at least one section of each of the transition sections 103 gradually decreases in the direction from the first end 10A to the second end 10B.
- the ratio of the interval between each of the transition sections 103 and the first end 10A that is, the distance between the end point of the transition section 103 closest to the first end 10A and the first end 10A
- the ratio of the interval between each of the transition sections 103 and the first end 10A that is, the distance between the end point of the transition section 103 closest to the first end 10A and the first end 10A
- the convex structure 5 since the convex structure 5 is disposed in the air channel 11 to occupy the space inside the air channel 11, the convex structure 5 may cause the variation of the flow area at the corresponding position in the air channel 11. Specifically, along the direction from the first end 10A to the second end 10B, if the space occupied by the convex structure 5 in the air channel 11 gradually increases, the flow area of this section of the air channel 11 will gradually decrease, so that the rate of the air flowing through this section will gradually increase. Along the direction from the first end 10A to the second end 10B, if the space occupied by the convex structure 5 in the air channel 11 gradually decreases, the flow area of this section of the air channel 11 will gradually increase, so that the rate of the air flowing through this section will gradually decrease.
- the convex structure 5 is in the shape of an inclined surface (that is, a flat surface which is not parallel to the extended center line of the air channel 11) or a curved surface.
- a corresponding convex structure 5 may be designed in the air channel 11 according to air distribution needs, and then, the air ejected from the air outlet 101 in the overall extension direction is uniform. More specifically, since the flow parameters (such as rate, pressure and direction) of the air flowing through the convex structure 5 may continuously change, rather than suddenly change, the problem of vortex generation around the convex structure 5 may be improved, and the disturbance resistance caused by the convex structure 5 to the air is reduced, so as to ensure that the air may smoothly travel and change in the air channel 11 and reduce the aerodynamic noise.
- the flow parameters such as rate, pressure and direction
- the convex structure 5 is disposed away from the air outlet 101 and the first end 10A, when the air flows through the convex structure 5, the air will flow out of the air outlet 101 after changing the flow parameters at a position away from the air outlet 101 and the first end 10A, thereby improving the effectiveness of the convex structure 5 in functioning. Moreover, the convex structure 5 is disposed away from the air outlet 101, and then, the problem that the convex structure 5 induces vortex at the air outlet 101 and disturbs the normal ejection of the air from the air outlet 101 is avoided, thereby improving the reliability of air output.
- the distribution (including rate distribution, pressure distribution, direction distribution, and the like) of the air in the air channel 11 may be changed by adjusting the shape of the convex structure 5 in the air channel 11, so as to adjust the rate and angle of the air ejected from the air outlet 101, so that the air ejected by the head 100 on the overall blowing plane is uniform.
- the rate and angle of the air ejected in the vertical direction by the head 100 shown in FIG. 12 are uniform, and the problem of turbulence of the air in the vertical direction and convergence of the air in front of the head 100 will not occur, so that the air supply distance and air supply volume of the head 100 may be effectively improved, and the user experience may be improved.
- the convex structure 5 in the air channel 11
- internal air distribution of the air channel 11 may be improved, the disturbance effect of the convex structure 5 on the air is reduced, the noise is reduced, the exhausted air of the head 100 may be more uniform on the overall air output plane, the air output effect of the head 100 is effectively improved, and the user experience is greatly enhanced.
- a plurality of convex structures 5 may be arranged to be spaced from one another in the air flow direction.
- the lengths of a plurality of convex structures 5 may be set to be exactly the same.
- the length of the convex structure 5 refers to the size of the convex structure 5 along the air flow direction.
- the lengths of a plurality of convex structures 5 are the same.
- the interval between every two adjacent convex structures 5 may be the same or different.
- the three convex structures are respectively expressed as A, B and C.
- the interval between A and B is A-B
- the interval between B and C is B-C
- the interval A-B and the interval B-C may be the same or different.
- the interval between two convex structures 5 refers to the gap between two convex structures 5, or the interval between adjacent ends of two adjacent convex structures 5 in the air flow direction.
- the interval between two convex structures 5 refers to the interval between the upper end of the lower one of the two convex structures 5 and the lower end of the upper one.
- the convex structure 5 may be a circular arc surface or may be formed by smooth transition connection (such as chamfered transition connection) of a plurality of circular arc surfaces, and the convex structure 5 is in smooth transition connection (such as chamfered transition connection) with the surface of the air channel 11. Therefore, it may ensure that the flow area of the air channel 11 at the convex structure 5 continuously varies, and the convex structure 5 may have a smaller disturbance effect on the air, so as to further reduce the possibility of vortex generation and ensure that the air may circulate more smoothly in the air channel 11.
- the convex structure 5 may include a first sub-convex surface extending in a direction from the first end 10A to the second end 10B toward a direction adjacent to the air outlet 101, and a second sub-convex surface 52 extending in a direction away from the air outlet 101.
- the first sub-convex surface 51 is in a shape of a curved surface, and the first sub-convex surface 51 is in smooth transition connection with the second sub-convex surface 52 through the curved surface.
- the disclosure is not limited thereto.
- the first sub-convex surface 51 may also be in a shape of an inclined surface and includes a first inclined surface extending along the inclined surface in a direction from the first end 10A to the second end 10B toward a direction adjacent to the air outlet 101, and a second inclined surface extending along the inclined surface in a direction away from the air outlet 101.
- the flow area of the transition section 103 of the air channel 11 provided with the first sub-convex surface may decrease first and then increase in a direction from the first end 10A to the second end 10B.
- the flow rate may gradually increase, and the air flows toward the direction of the air outlet 101; and after passing through a transition curved surface between the first sub-convex surface and the second sub-convex surface 52, the air may move along the second sub-convex surface 52 toward the direction away from the air outlet 101, and the air rate will gradually decrease to enable the air to be in gentle contact with the wall surface of the air channel 11, thereby reducing the air disturbance and buffering the air so as to reduce the aerodynamic noise.
- two first sub-convex surfaces 51 are provided and are spaced from one another along a direction from the first end 10A to the second end 10B, the intervals between the two first sub-convex surfaces 51 and the first end 10AA are respectively 1/6 to 2/6 and 4/6 to 5/6 of the length of the air channel 11 (X1/L and X2/L shown in FIG. 15 ), and the length of each of the first sub-convex surfaces 51 is 1/6 to 2/6 of the length of the air channel 11 (D1/L and D2/L shown in FIG. 15 ). Therefore, the exhausted air of the head 100 is more uniform, and the air output effect is better.
- one first sub-convex surface 51 is provided, the interval between the first sub-convex surface and the first end 10A is 1/6 to 2/6 of the length of the air channel 11 (X4/L and X6/L shown in FIG. 20 and FIG. 21 ), and the length of the first sub-convex surface is 2/6 to 4/6 of the length of the air channel 11 (D4/L and D6/L shown in FIG. 20 and FIG. 21 ). Therefore, the exhausted air of the head 100 is more uniform, and the air output effect is better.
- the first sub-convex surface is disposed at the middle downstream side of the air channel 11, and then, the rate of the air at the middle downstream side of the air channel 11 may be increased so as to enable the overall air output effect of the air channel 11 to be more uniform.
- the air ejected from the air outlet 101 at the middle upstream side of the air channel 11 will be ejected toward the downstream direction of the air channel 11 at a larger inclination angle, and the air ejected from the air outlet 101 at the middle downstream side of the air channel 11 will be ejected toward the downstream direction of the air channel 11 at a smaller inclination angle.
- the inclination angle of the air ejected from the air outlet 101 at the middle upstream side of the air channel 11 may be reduced, so that the overall air output effect of the air channel 11 is more uniform.
- the air ejection angle of the middle upstream side may be reduced, and the air ejection rate of the middle downstream side may be increased, so that the overall air output effect of the air channel 11 is more uniform.
- the upstream side refers to a position adjacent to the first end 10A
- the downstream side refers to a position adjacent to the second end 10B.
- the convex structure 5 may include a second sub-convex surface 52 in a shape of a curved surface, and the second sub-convex surface 52 gradually extends along a direction from the first end 10A to the second end 10B toward the direction adjacent to the air outlet 101, and extends to the second end 10B. Therefore, the convex structure 5 is simpler in structure and more convenient to process.
- the second sub-convex surface 52 may also be in a shape of an inclined surface, and extends along the inclined surface in a direction from the first end 10A to the second end 10B toward the direction adjacent to the air outlet 101.
- the interval between the second sub-convex surface 52 and the first end 10A is 2/6 to 5/6 of the length of the air channel 11 (X3/L and X5/L shown in FIG. 19 and FIG. 20 ).
- the second sub-convex surface 52 may be disposed at the downstream side of the air channel 11 (third embodiment shown in FIG. 20 ), or extends from the middle upstream side of the air channel 11 to the downstream side of the air channel 11 (second embodiment shown in FIG. 19 ).
- the flow area adjacent to the downstream side of the air channel 11 gradually decreases, thus the air output rate of the downstream side of the air channel 11 may be effectively increased, and the air output rate of the upstream and downstream sides of the air channel 11 is uniform so as to improve the air output effect and the air output uniformity.
- the rate of the air at the downstream side of the air channel 11 is less than the rate of the air at the upstream side of the air channel 11, and the ejection angle of the air at the downstream side of the air channel 11 is less than the ejection angle of the air at the upstream side of the air channel 11.
- a head 100 according to multiple embodiments of the disclosure will be described below with reference to FIG. 12 to FIG. 21 .
- a head 100 includes a first air channel member 105 and a second air channel member 106, an air channel 11 is formed in each of the first air channel member 105 and the second air channel member 106, and one end of the first air channel member 105 is connected and communicated with one end of the second air channel member 106.
- the first air channel member 105 and the second air channel member 106 may be in an annular shape with an opening, and air inlets are disposed at two ends of the opening of the annular shape.
- a head 100 includes a first air channel member 105 and a second air channel member 106, an air channel 11 is formed in each of the first air channel member 105 and the second air channel member 106, one end of the first air channel member 105 is connected with one end of the second air channel member 106 by a connector, and the air channel 11 in the first air channel member 105 is spaced from the air channel 11 in the second air channel member 106.
- a head 100 includes a first air channel member 105, a second air channel member 106 and a connector 107, an air channel 11 is formed in each of the first air channel member 105 and the second air channel member 106, both the first air channel member 105 and the second air channel member 106 extend along an vertical direction, the first air channel member 105 and the second air channel member 106 are spaced along a left-right direction, and the first air channel member 105 and the second air channel member 106 are parallel to each other.
- the lower end of the air channel 11 is formed as the above first end 10A
- the upper end of the air channel 11 is formed as the above second end 10B.
- One end of the connector is connected with the upper end of the first air channel member 105 and another end is connected with the upper end of the second air channel member 106.
- the head 100 in the third embodiment may include a first splicing part 41 and a second splicing part 42.
- the first splicing part 41 includes a first inner ring plate 411 which is vertically disposed and has an inverted U shape and a first outer ring plate 412 which is vertically disposed and has an inverted U shape.
- the first outer ring plate 412 covers the outside of the first inner ring plate 411, and convex structures 5 are disposed in the first splicing part 41.
- the second splicing part 42 includes a second inner ring plate 421 which is vertically disposed and has an inverted U shape and a second outer ring plate 422 which is vertically disposed and has an inverted U shape.
- the second outer ring plate 422 covers the outside of the second inner ring plate 421.
- the second splicing part 42 is spliced at the front side of the first splicing part 41, so that the second sub-air channel 11 and the first splicing part 41 are spliced to form a first air channel member 105, a second air channel member 106 and a connector 107.
- An air outlet 101 is formed at the front side of the second splicing part 42.
- the head 100 further includes a third splicing part 43.
- the third splicing part 43 is vertically disposed and has an inverted U shape and covers the outside of the first splicing part 41 and the second splicing part 42.
- the convex structures 5 are disposed on the first outer ring plate 412 and are formed by inward indentation of the outer surface of the first outer ring plate 412.
- the third splicing part 43 may play a decorative role, and the overall appearance of the head 100 is beautiful.
- back recesses 50 of the convex structures 5 may be shielded so as to improve the overall aesthetics of the head 100.
- a plurality of reinforcing ribs 16 are disposed between the first inner ring plate 411 and the first outer ring plate 412, therefore, the volume of the first splicing part 41 may be ensured, and the working performance and working reliability of the head 100 may be improved.
- a plurality of reinforcing ribs 16 are also disposed between the second inner ring plate 421 and the second outer ring plate 422, therefore, the volume of the second sub-air channel 11 may be ensured, and the working performance and working reliability of the head 100 may be improved.
- the disclosure is not limited thereto. In other embodiments of the disclosure, the number of the reinforcing rib 16 may be only one, and the reinforcing rib 16 may also be disposed only in the first splicing part 41 or only in the second splicing part 42.
- the matching surfaces of the first splicing part 41 and the second splicing part 42 are spliced through a slot structure 44 and sealed by ultrasonic welding at the spliced position. Therefore, the assembly efficiency may be improved, the sealing reliability is high, and the defect rate may be reduced.
- the splicing manner of the "slot structure 44" is well known to those skilled in the art, and will not be described in detail here.
- the first splicing part 41 and the second splicing part 42 may also be connected at a screw installation structure 45 through screws or bolts, thereby facilitating subsequent ultrasonic welding.
- the disclosure is not limited thereto.
- the first splicing part 41 and the second splicing part 42 may also be fixed and sealed by gluing.
- a left air channel 11 and a right air channel 11 which are not communicated to each other are defined in the head 100.
- a convex structure 5 having a first sub-convex surface 51 and a second sub-convex surface 52 is respectively arranged at the middle upstream side and the middle downstream side in each of the air channels 11. In this way, after the air enters each of the air channels 11, the air may first pass through a convex structure 5 to change the flow rate, then pass through a gentle section 102 at the midstream of the air channel 11, and then flow to the next first sub-convex surface 51 to change the flow rate.
- the flow rate of the air at the lower part of the air channel 11 is higher, the rate direction is upward, a part of the air is ejected from the air outlet 101, the air ejection direction is obliquely upward, and the inclination angle is larger.
- the flow rate of the air at the upper part of the air channel 11 decreases, and the inclination angle of the air ejected from the air outlet 101 also becomes smaller. In this way, the air ejected from the upper air outlet 101 generates a greater disturbance to the air ejected from the lower air outlet 101, resulting in poor user experience and aerodynamic noise.
- the flow area at the corresponding position of the air channel 11 firstly gradually decreases and then gradually increases, resulting in that the rate of the air at the corresponding position firstly gradually increases and then gradually decreases.
- the air After passing through the gentle section 102 of the air channel 11, the air passes through the first sub-convex surface 51 of the upper convex structure 5, then, the flow rate gradually increases again, and the air moves toward the air outlet 101, so that the air rate at the corresponding air outlet 101 may be increased, and the air supply direction at this position may be improved. Therefore, the air rate on the overall air output plane is relatively uniform, the situation that the overall exhausted air is obliquely upward is well improved, the turbulence of the air on the air output plane is reduced, the noise is reduced, and the user experience is enhanced.
- the air output effect is greatly enhanced and improved.
- the difference in the convex structure 5 will change the air rate and air direction at different positions on the air output plane. Therefore, in the design height of the air channel 11 of the present embodiment, by disposing two convex structures 5, the air output is more uniform, the air output rate and angle are more comfortable, and the aerodynamic noise is lower.
- the structure of the present embodiment is substantially the same as that of the third embodiment.
- the convex structure 5 disposed in each of the air channels 11 only includes a first sub-convex surface, and the first sub-convex surface extends from the middle upstream side of the air channel 11 to the downstream side of the air channel 11. Therefore, the convex structure 5 is simple in structure and convenient to process, the flow rate in the overall air channel 11 is more uniform, and the air output effect of the head 100 is improved.
- the structure of the present embodiment is substantially the same as that of the third embodiment.
- two convex structures 5 are disposed in each of the air channels 11.
- One convex structure 5 extends from the middle upstream side of the air channel 11 to the middle downstream side of the air channel 11 and has a first sub-convex surface 51 and a second sub-convex surface 52, and the other convex structure 5 is disposed at the downstream side of the air channel 11 and may only have a first sub-convex surface 51. Therefore, the convex structure 5 is simple in structure and convenient to process, the flow rate in the overall air channel 11 is more uniform, and the air output effect of the head 100 is improved.
- the structure of the present embodiment is substantially the same as that of the third embodiment.
- a convex structure 5 is disposed in each of the air channels 11.
- the convex structure 5 extends from the middle upstream side of the air channel 11 to the middle downstream side of the air channel 11.
- the convex structure 5 has a first sub-convex surface 51 and a second sub-convex surface 52. Therefore, the convex structure 5 is simple in structure and convenient to process, the flow rate in the overall air channel 11 is more uniform, and the air output effect of the head 100 is improved.
- a bladeless fan 1000 according to the embodiments of the second aspect in the specific implementation of the disclosure will be described below with reference to FIG. 22 .
- the bladeless fan 1000 according to the embodiments of the second aspect in the specific implementation of the disclosure includes: a base 200, an air generation device and the head 100 according to the embodiments of the first aspect in the specific implementation of the disclosure.
- the head 100 is installed on the base 200.
- the air generation device is disposed in the base 200 and configured to supply air into the air channel 11.
- the bladeless fan 1000 may also include other components.
- an air guiding device such as a tee joint, may also be installed in the base 200.
- the high-rate air generated by the air generation device may enter the air channel 11 through the shunt of the tee joint.
- other compositions of the bladeless fan 1000 according to the embodiments of the disclosure such as control systems, and operations are known to those of ordinary skill in the art, and will not be described in detail here.
- the overall performance of the bladeless fan 1000 is improved.
- the head is equivalent to the fan head component
- the first sub-section in the transition section is equivalent to the variable cross-section portion
- the convex structure is equivalent to the guide device
- the first sub-convex surface is equivalent to the first guide member
- the second sub-convex surface is equivalent to the second guide member
- the first splicing part is equivalent to the rear air output member
- the second splicing part is equivalent to the front air output member
- the third splicing part is equivalent to the housing
- the air outlet is equivalent to the nozzle
- the air generation device is equivalent to the drive system
- the flow area is equivalent to the air flow area.
- orientations or position relationships indicated by terms “upper”, “lower”, “front”, “rear”, “top”, “bottom”, “inside”, “outside” and the like are based on orientations or position relationships shown in drawings, These terms are only for the convenience of describing the disclosure and simplifying the description, and do not indicate or imply that the specified device or component must have a specific orientation and must be constructed and operated in the specific orientation, so that it cannot be understood as a limitation to the disclosure.
- first and second are only for description of objectives, and cannot be understood as indicating or implying relative importance or implicitly indicating the number of the indicated technical features.
- the features defined as “first” and “second” may explicitly or implicitly include one or more of the features.
- the meaning of "a plurality of” is two or more, unless otherwise specifically limited.
- the terms “installation”, “connected with”, “connection”, “fixation” and the like should be broadly understood, and may be fixed connection, detachable connection, integration, direct connection, indirect connection through an intermediate, internal communication of two components, or interaction between two components. Those skilled in the art may understand the specific meanings of the above terms in the disclosure according to specific situations.
- the first feature “above” or “below” the second feature may be direct contact between the first feature and the second feature, or indirect contact between the first feature and the second feature through an intermediate.
- the first feature is “over”, “above” and “on” the second feature may be that the first feature is directly above or obliquely above the second feature, or simply means that the first feature is higher than the second feature in level.
- the first feature is “under”, “below” and “down” the second feature may be that the first feature is directly below or obliquely below the second feature, or simply means that the first feature is lower than the second feature in level.
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Claims (15)
- Composant de tête de ventilateur pour un dispositif de soufflerie sans pales, comprenant une portion de sortie d'air (10) comprenant une entrée d'air (13), une buse (12) et canal d'air (11), dans lequel à la fois l'entrée d'air (13) et la buse (12) communiquent avec le canal d'air (11), le canal d'air (11) présente une portion de section transversale variable, une aire d'écoulement d'air correspondant à la portion de section transversale variable variant continuellement dans une direction verticale, et l'aire d'écoulement d'air correspondant à une extrémité inférieure de la portion de section transversale variable étant supérieure à l'aire d'écoulement d'air correspondant à une extrémité supérieure de la portion de section transversale variable ;
caractérisé en ce que
le composant de tête de ventilateur comprend un dispositif de guidage (20) disposé dans le canal d'air (11) pour former la portion de section transversale variable, le dispositif de guidage (20) comprenant une premier élément de guidage (21), le premier élément de guidage (21) présentant une première surface de guidage (21a), la première surface de guidage (21a) s'étendant obliquement vers le bas pour bloquer une partie de l'air d'admission, l'aire d'écoulement d'air du canal d'air (11) correspondant à une extrémité inférieure de la première surface de guidage (21a) étant supérieure à l'aire d'écoulement d'air du canal d'air (11) correspondant à une extrémité supérieure de la première surface de guidage (21a), et une partie correspondante du canal d'air (11) entre l'extrémité inférieure et l'extrémité supérieure de la première surface de guidage (21a) étant la portion de section transversale variable ;dans lequel le dispositif de guidage (20) comprend en outre un deuxième élément de guidage (22) positionné au-dessus du premier élément de guidage (21), le deuxième élément de guidage (22) présentant une deuxième surface de guidage (22a) s'étendant obliquement vers le haut, une extrémité inférieure de la deuxième surface de guidage (22a) étant reliée à l'extrémité supérieure de la première surface de guidage (21a), et l'aire d'écoulement d'air du canal d'air (11) au niveau de l'extrémité inférieure de la deuxième surface de guidage (22a) étant inférieure à l'aire d'écoulement d'air du canal d'air (11) au niveau de l'extrémité supérieure de la deuxième surface de guidage (22a) ;dans lequel la buse (12) s'étend le long d'une direction verticale du canal d'air (11), une pluralité de portions de section transversale variables étant prévues, et la pluralité de portions de section transversale variables étant disposées le long de la direction verticale du canal d'air (11) et espacées les unes des autres ; etdans lequel un nombre du deuxième élément de guidage (22) est déterminé en fonction d'un besoin réel, le premier élément de guidage (21) n'ayant pas besoin d'être disposé en correspondance un-à-un avec le deuxième élément de guidage (22). - Composant de tête de ventilateur selon la revendication 1, dans lequel les portions de section transversale variables sont positionnées au niveau d'une partie supérieure et/ou d'une partie centrale du canal d'air (11) ; et/ou
dans lequel une paroi latérale de la portion de sortie d'air (10) est inclinée vers l'intérieur dans la direction verticale pour former la portion de section transversale variable. - Composant de tête de ventilateur selon la revendication 1 ou 2, dans lequel le premier élément de guidage (21) est en forme de plaque, et le premier élément de guidage (21) s'étend obliquement vers le bas à partir de l'extrémité supérieure du canal d'air (11), dans lequel la premier dispositif de guidage (21a) est de préférence tournée vers la paroi latérale de la portion de sortie d'air (10), et un bord du premier élément de guidage (21) étant de préférence relié étroitement à la paroi latérale de la portion de sortie d'air (10) ; et/ou
dans lequel la première surface de guidage (21a) est de préférence tournée vers la buse (12) de manière à guider une partie de l'air d'admission vers la buse (12), dans lequel la buse (12) est de préférence disposée sur un premier côté de la portion de sortie d'air (10), le premier élément de guidage (21) étant de préférence disposé sur un deuxième côté de la portion de sortie d'air (10) opposé au premier côté, et un bord du premier élément de guidage (21) étant de préférence relié étroitement à une paroi intérieure du deuxième côté de la portion de sortie d'air (10). - Composant de tête de ventilateur selon l'une quelconque des revendications 1 à 3, dans lequel la deuxième surface de guidage (22a) est une surface plane, une surface arquée ou une combinaison d'une surface plane et d'une surface arquée, et/ou la première surface de guidage (21a) est une surface plane, une surface arquée ou une combinaison d'une surface plane et d'une surface arquée ; et/ou
dans lequel, de l'extrémité inférieure de la deuxième surface de guidage (22a) à l'extrémité supérieure de la deuxième surface de guidage (22a), l'aire d'écoulement d'air du canal d'air (11) correspondant augmente progressivement, dans lequel le dispositif de guidage (20) comprend un troisième élément de guidage (23) présentant une troisième surface de guidage (23a), la deuxième surface de guidage (22a) étant en connexion de transition lisse avec la première surface de guidage (21a) par le biais de la troisième surface de guidage (23a). - Composant de tête de ventilateur selon l'une quelconque des revendications 1 à 4, dans lequel la portion de sortie d'air (10) comprend un élément de sortie d'air avant (14) et un élément de sortie d'air arrière (15), l'élément de sortie d'air avant (14) et l'élément de sortie d'air arrière (15) définissant conjointement le canal d'air (11), la buse (12) étant disposée sur un côté avant de l'élément de sortie d'air avant (14), et le dispositif de guidage (20) étant relié étroitement à un côté arrière de l'élément de sortie d'air arrière (15), dans lequel le dispositif de guidage (20) est de préférence intégré avec l'élément de sortie d'air arrière (15) ; et/oudans lequel l'un parmi l'élément de sortie d'air avant (14) et l'élément de sortie d'air arrière (15) est de préférence pourvu d'une fente de positionnement (141), l'autre étant de préférence pourvu d'une saillie de positionnement (151) correspondant à la fente de positionnement (141), et l'élément de sortie d'air avant (14) et l'élément de sortie d'air arrière (15) étant de préférence reliés l'un à l'autre par soudage ultrasonique ou par collage ; et/ou,dans lequel le composant de tête de ventilateur comprend de préférence en outre un boîtier (30) recouvrant un extérieur de la portion de sortie d'air (10).
- Composant de tête de ventilateur selon l'une quelconque des revendications 1 à 5, dans lequel, de l'extrémité inférieure de la première surface de guidage (21a) à l'extrémité supérieure de la première surface de guidage (21a), l'aire d'écoulement d'air du canal d'air (11) correspondant diminue progressivement ; et/oudans lequel la portion de sortie d'air (10) comprend en outre une nervure de renforcement (16) disposée dans le canal d'air (11), deux extrémités de la nervure de renforcement (16) étant reliées fixement à des parois intérieures de côtés gauche et droit du canal d'air (11) ; et/oudans lequel la buse (12) s'étend le long de la direction verticale du canal d'air (11), une pluralité de dispositifs de guidage (20) étant prévus, la pluralité de dispositifs de guidage (20) étant disposés le long de la direction verticale du canal d'air (11) et espacés les uns des autres, et la pluralité de dispositifs de guidage (20) étant disposés de manière à correspondre à la buse (12).
- Composant de tête de ventilateur pour un dispositif de soufflerie sans pales, comprenant une portion de sortie d'air (10) comprenant une entrée d'air (13), une buse (12) et un canal d'air (11), dans lequel à la fois l'entrée d'air (13) et la buse (12) communiquent avec le canal d'air (11), le canal d'air (11) comprenant une première extrémité (10A) et une deuxième extrémité (10B), une direction d'écoulement d'air étant une direction partant de la première extrémité (10A) vers la deuxième extrémité (10B) du canal d'air (11), le canal d'air (11) comprend une portion de section transversale variable, une aire d'écoulement d'air de la portion de section transversale variable variant continuellement le long de la direction d'écoulement d'air, et l'aire d'écoulement d'air correspondant à une extrémité de la portion de section transversale variable adjacente à la première extrémité (10A) étant supérieure à l'aire d'écoulement d'air correspondant à une extrémité de la portion de section transversale variable adjacente à la deuxième extrémité (10B) ;caractérisé en ce quele la buse (12) s'étend le long de la direction d'écoulement d'air du canal d'air (11), une pluralité de portions de section transversale variables étant prévues, et la pluralité de portions de section transversale variables étant disposées le long de la direction d'écoulement d'air du canal d'air (11) et espacées les unes des autres ;dans lequel le composant de tête de ventilateur comprend un dispositif de guidage (20) disposé dans le canal d'air (11) pour former la portion de section transversale variable, les dispositifs de guidage (20) comprenant un premier élément de guidage (21) présentant une première surface de guidage (21a), la première surface de guidage (21a) s'étendant obliquement par rapport à la direction d'écoulement d'air pour bloquer une partie de l'air d'admission, et une partie du canal d'air (11) au niveau d'une position correspondant à la première surface de guidage (21a) étant la portion de section transversale variable ;dans lequel la première surface de guidage (21a) est tournée vers la buse (12) pour guider une partie de l'air d'admission vers la buse (12) ;dans lequel le dispositif de guidage (20) comprend en outre un deuxième élément de guidage (22) positionné de façon adjacente à la deuxième extrémité (10B), le deuxième élément de guidage (22) présentant une deuxième surface de guidage (22a) s'étendant obliquement par rapport à la direction d'écoulement d'air, la deuxième surface de guidage (22a) étant reliée à la première surface de guidage (21a), et l'aire d'écoulement d'air du canal d'air (11) correspondant à l'extrémité de la deuxième surface de guidage (22a) adjacente à la première surface de guidage (21a) étant inférieure à l'aire d'écoulement d'air du canal d'air (11) correspondant à l'extrémité de la deuxième surface de guidage (22a) opposée à la première surface de guidage (21a), dans lequel l'aire d'écoulement d'air du canal d'air (11) correspondant à la deuxième surface de guidage (22a) augmente progressivement le long de la direction d'écoulement d'air ; etdans lequel un nombre du deuxième élément de guidage (22) est déterminé en fonction des besoins réels, le premier élément de guidage (21) n'ayant pas besoin d'être disposé en correspondance un-à-un avec le deuxième élément de guidage (22).
- Composant de tête de ventilateur selon la revendication 7, dans lequel une paroi latérale de la portion de sortie d'air (10) est inclinée vers l'intérieur pour former la portion de section transversale variable.
- Dispositif de soufflerie sans pales, caractérisé en ce que le dispositif de soufflerie sans pales comprend une base (200), un système d'entraînement disposé dans la base (200), et le composant de tête de ventilateur selon l'une quelconque des revendications 1 à 8, dans lequel le composant de tête de ventilateur est relié à la base (200) pour recevoir de l'air d'admission généré par le système d'entraînement par le biais de l'entrée d'air (13) et émettre de l'air d'admission par le biais de la buse (12), dans lequel le dispositif de soufflerie sans pales est de préférence l'un parmi un ventilateur sans pales (1000), une soufflerie sans pales, un chauffage sans pales, un humidificateur sans pales et un refroidisseur sans pales.
- Tête (100) pour un ventilateur sans pales (1000), un canal d'air (11) est formé dans la tête (100), le canal d'air (11) présente une première extrémité (10A) et une deuxième extrémité (10B), la première extrémité (10A) du canal d'air (11) étant pourvue d'une entrée d'air (13), une direction d'écoulement d'air étant une direction allant de la première extrémité (10A) à la deuxième extrémité (10B) du canal d'air (11), une paroi du canal d'air (11) étant pourvue d'une sortie d'air traversant la paroi du canal d'air (11) dans une direction perpendiculaire à la direction d'écoulement d'air, et la sortie d'air étant disposée le long de la direction d'écoulement d'air,dans laquelle une section de transition (103) est formée entre la première extrémité (10A) et la deuxième extrémité (10B) du canal d'air (11), une zone d'écoulement de la section de transition (103) variant graduellement dans la direction d'écoulement d'air ;caractérisée en ce quela section de transition (103) comprend une première sous-section, et la zone d'écoulement de la première sous-section diminuant graduellement dans la direction d'écoulement d'air,dans laquelle la première sous-section est espacée de la deuxième extrémité (10B) du canal d'air (11), et la section de transition (103) comprend en outre :une deuxième sous-section, dans laquelle une extrémité de la deuxième sous-section est reliée à la première sous-section, l'autre extrémité de la deuxième sous-section s'étendant vers la deuxième extrémité (10B) du canal d'air (11), et la zone d'écoulement de la deuxième sous-section augmentant graduellement dans la direction d'écoulement d'air, dans laquelle une longueur de la deuxième sous-section dans la direction d'écoulement d'air est supérieure à une longueur de la première sous-section dans la direction d'écoulement d'air ;dans laquelle il est prévu une pluralité de sections de transition (103) espacées les unes des autres le long de la direction d'écoulement d'air, et des longueurs de la pluralité de sections de transition (103) dans la direction d'écoulement d'air étant identiques.
- Tête (100) pour le ventilateur sans pales (1000) selon la revendication 10, dans laquelle une extrémité de la première sous-section s'étend vers la première extrémité (10A) du canal d'air (11) ou est espacée de la première extrémité (10A) du canal d'air (11), et l'autre extrémité de la première sous-section s'étend vers la deuxième extrémité (10B) du canal d'air (11).
- Tête (100) pour un ventilateur sans pales (1000) selon la revendication 10 ou 11, dans laquelle la section de transition (103) se trouve directement en face d'une partie au moins de la sortie d'air ; et/ou,dans laquelle la paroi du canal d'air (11) fait saillie vers un intérieur du canal d'air (11) pour former la section de transition (103) ; et/oudans laquelle il est prévu de préférence au moins trois sections de transition (103) espacées les unes des autres le long de la direction d'écoulement d'air, et un intervalle entre à chaque fois deux sections de transition (103) adjacentes parmi les au moins trois sections de transition (103) étant de préférence à chaque fois identique.
- Tête (100) pour le ventilateur sans pales (1000) selon l'une quelconque des revendications 10 à 12, dans laquelle la tête (100) comprend :un premier élément de canal d'air (105) ; etun deuxième élément de canal d'air (106), dans laquelle le canal d'air est formé dans chacun parmi le premier élément de canal d'air (105) et le deuxième élément de canal d'air (106) ;une extrémité du premier élément de canal d'air (105) est reliée à une extrémité du deuxième élément de canal d'air (106) et mise en communication avec celle-ci ; ou une extrémité du premier élément de canal d'air (105) est reliée à une extrémité du deuxième élément de canal d'air (106) par un connecteur (107), et le canal d'air (11) dans le premier élément de canal d'air (105) étant espacé du canal d'air (11) dans le deuxième élément de canal d'air (106).
- Tête (100) pour le ventilateur sans pales (1000) selon l'une quelconque des revendications 10 à 13, dans laquelle la tête (100) comprend :un premier élément de canal d'air (105), dans laquelle le premier élément de canal d'air (105) s'étend le long d'une direction verticale ;un deuxième élément de canal d'air (106), dans laquelle le deuxième élément de canal d'air (106) s'étend le long de la direction verticale, et le premier élément de canal d'air (105) et le deuxième élément de canal d'air (106) étant espacés l'un de l'autre dans une direction gauche-droite et parallèles entre eux ; etun connecteur (107), dans laquelle une extrémité du connecteur (107) est reliée à une extrémité supérieure du premier élément de canal d'air (105) et une autre extrémité est reliée à une extrémité supérieure du deuxième élément de canal d'air (106) ; etle canal d'air (11) est formé dans chacun parmi le premier élément de canal d'air (105) et le deuxième élément de canal d'air (106), une extrémité inférieure du canal d'air (11) étant la première extrémité (10A), et une extrémité supérieure du canal d'air (11) étant la deuxième extrémité (10B).
- Ventilateur sans pales (1000), comprenant :une base (200) ;une tête (100), dans lequel la tête (100) est la tête (100) pour le ventilateur sans pales (1000) selon l'une quelconque des revendications 10 à 14 et est installée sur la base (200) ; etun dispositif de génération d'air, dans lequel le dispositif de génération d'air est disposé dans la base (200) et configuré pour alimenter de l'air dans le canal d'air (11).
Applications Claiming Priority (5)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201721803860.4U CN207847976U (zh) | 2017-12-19 | 2017-12-19 | 一种用于无叶吹风设备的扇头组件以及无叶吹风设备 |
CN201711378783.7A CN107965458B (zh) | 2017-12-19 | 2017-12-19 | 一种扇头组件及无叶吹风设备 |
CN201721803727.9U CN208487066U (zh) | 2017-12-19 | 2017-12-19 | 无叶风扇及其机头 |
CN201711376203.0A CN108180175B (zh) | 2017-12-19 | 2017-12-19 | 一种扇头组件及无叶吹风设备 |
PCT/CN2018/121607 WO2019120180A1 (fr) | 2017-12-19 | 2018-12-17 | Ensemble de tête de ventilateur pour appareil de soufflage d'air sans pale, appareil de soufflage d'air sans pale, tête pour ventilateur sans pale et ventilateur sans pale |
Publications (3)
Publication Number | Publication Date |
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EP3726066A1 EP3726066A1 (fr) | 2020-10-21 |
EP3726066A4 EP3726066A4 (fr) | 2021-01-27 |
EP3726066B1 true EP3726066B1 (fr) | 2023-05-03 |
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ID=66994407
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
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EP18890517.8A Active EP3726066B1 (fr) | 2017-12-19 | 2018-12-17 | Ensemble de tête de ventilateur pour appareil de soufflage d'air sans pale, appareil de soufflage d'air sans pale, tête pour ventilateur sans pale et ventilateur sans pale |
Country Status (2)
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EP (1) | EP3726066B1 (fr) |
WO (1) | WO2019120180A1 (fr) |
Families Citing this family (1)
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CN114087237B (zh) * | 2021-12-17 | 2024-03-08 | 广东美的白色家电技术创新中心有限公司 | 无叶风扇 |
Family Cites Families (7)
Publication number | Priority date | Publication date | Assignee | Title |
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KR101203378B1 (ko) * | 2011-07-27 | 2012-11-21 | 이광식 | 무 블레이드 선풍기용 환형노즐 |
CN102661294B (zh) * | 2012-04-10 | 2014-10-29 | 宁波宏钜电器科技有限公司 | 一种无叶风扇 |
CN103375444A (zh) * | 2012-04-11 | 2013-10-30 | 江西维特科技有限公司 | 无叶风扇及其喷嘴 |
GB2502106A (en) * | 2012-05-16 | 2013-11-20 | Dyson Technology Ltd | Bladeless fan |
GB2509760B (en) * | 2013-01-14 | 2015-07-15 | Dyson Technology Ltd | A Fan |
CN106762852B (zh) * | 2016-11-15 | 2020-02-04 | 美的集团股份有限公司 | 扇头及无叶风扇 |
CN107477026A (zh) * | 2017-09-30 | 2017-12-15 | 广东美的环境电器制造有限公司 | 无叶风扇和机头 |
-
2018
- 2018-12-17 WO PCT/CN2018/121607 patent/WO2019120180A1/fr unknown
- 2018-12-17 EP EP18890517.8A patent/EP3726066B1/fr active Active
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WO2019120180A1 (fr) | 2019-06-27 |
EP3726066A4 (fr) | 2021-01-27 |
EP3726066A1 (fr) | 2020-10-21 |
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