DE112019001888T5 - Air ejector - Google Patents

Abstract

An air ejection device (1) comprises a duct (14) defining a flow passage (18) through which a flow of working air to be ejected toward an ejection target (2) passes, and a hole forming member (12) that has an air ejection hole (10 ) as an outlet of the working air flow on a downstream side of the duct in an air flow direction. The hole formation member has a vortex generation structure (20) configured to generate an auxiliary vortex having a vortex characteristic including a vortex rotating direction and a vortex axis direction. The vortex characteristic of the auxiliary vortex is different from that of a transverse vortex generated by the working air flow on a downstream side of the air discharge hole. The vortex generation structure is set up in the hole formation member so that the additional vortex collides with the transverse vortex in a state in which at least the vortex rotating direction and / or the vortex axial direction of the vortex characteristic is different from that of the transverse vortex.

Description

Cross reference to related registrations

This registration is based on the Japanese Patent Application No. 2018 - 076325 , filed on April 11, 2018, the Japanese Patent Application No. 2018-135299 , filed on July 18, 2018, the Japanese Patent Application No. 2018-199383 , which was filed on October 23, 2018, as well as the Japanese Patent Application No. 2018-240807 , which was submitted on December 25, 2018, the entire content of which is incorporated herein by reference.

Technical area

The present disclosure relates to an air ejection device that ejects a stream of air.

background

Conventionally, an air nozzle is known in which an auxiliary air outlet is provided around a main air outlet that forms a working air flow in order to form an auxiliary air flow that can reduce suction of the air drawn into the working air flow to increase a range of an air flow used as the working air flow (see, for example, Patent Document 1).

Citation

Patent document

Patent Document 1: JP 08-318176 A

Summary of the invention

The inventors of the present disclosure studied the air suction effect when the working air flow is blown out from the air outlet in order to further increase a range of the working air flow. As a result, it has been found that the air suction is caused by a transverse vortex generated by a shear force due to a velocity gradient of the working air flow when the working air flow is blown out of the air outlet. The transverse vortex is a vortex that has the center of the vortex perpendicular to the direction of flow of the working air flow. In the following, the center of the vortex is also referred to as the vortex axis.

Further investigation by the inventors of the present disclosure has revealed that in the vicinity of a downstream side of the air outlet, innumerable transverse vortices generated in the velocity boundary layer combine and develop into a large vortex, thereby increasing the air suction effect.

However, in the conventional technique described above, only the auxiliary air outlet around the air outlet is disclosed, and the findings of the present inventors are not described at all. For this reason, it is difficult to expect any further improvement in the range of the airflow.
An object of the present disclosure is to provide an ejection device that can suppress an air suction effect of a working air flow blown from an air outlet and increase a range of the working air flow.

Solution of the task

According to one aspect of the present disclosure, an air ejecting device includes a duct that defines a flow passage through which a working air flow to be ejected toward a discharge target passes, and a hole forming member that has an air ejection hole as an outlet of the working air flow on a downstream side of the duct limited in one air flow direction. The hole forming member has a vortex generation structure configured to generate an auxiliary vortex having a vortex characteristic including a vortex rotating direction and a vortex axis direction. The vortex characteristic of the auxiliary vortex is different from that of a transverse vortex generated by the working air flow on a downstream side of the air discharge hole. The vortex generation structure is set up in the hole forming element such that the additional vortex collides with the transverse vortex in a state in which at least the vortex rotating direction and / or the vortex axial direction of the vortex characteristic differs from that of the transverse vortex.

According to an aspect of the present disclosure, an air ejection device includes a passage that restricts a flow passage in which a working air flow flows, a hole formation member that delimits an air ejection hole as a working air flow outlet on a downstream side of the passage in an air flow direction, and a vortex generation structure that is configured to generate an auxiliary vortex having a vortex characteristic that includes a vortex rotating direction and a vortex axis direction. The vortex characteristic of the auxiliary vortex is different from that of a transverse vortex generated by the working air flow on a downstream side of the air discharge hole. The vortex generation structure includes a plurality of Vortex generating means arranged side by side along a peripheral edge of the hole forming member surrounding the air discharge hole. When the air flows around the vortex generating means, the additional vortex is generated which has a vortex characteristic that is different from at least one of the vortex rotation direction and / or a vortex axis direction of the transverse vortex.

In the air ejection device configured as above, a transverse vortex is generated downstream of the air ejection hole by the working air flow when the air flow is blown out of the air ejection hole. Further, in the air ejection device, when the air flow is ejected from the air ejection hole, an additional vortex is also generated by the vortex generation structure. Because the transverse vortex and the auxiliary vortex have different vortex characteristics, development of the transverse vortex is suppressed when the transverse vortex and the auxiliary vortex collide with each other. As a result, the suction effect of the air drawn into the working air flow is suppressed, and the decrease in the flow velocity of the working air flow is reduced. Therefore, it is possible to increase a range of the working air flow that is blown out from the air discharge hole. The reference characters in parentheses attached to the components and the like indicate an example of correspondence between the components and the like and certain components and the like described in an embodiment which will be described below.

Figure list

• 1 Fig. 13 is a schematic perspective view of an air ejecting device according to a first embodiment.
• 2 Fig. 13 is a schematic front view of the air ejecting device according to the first embodiment.
• 3 FIG. 13 is a sectional view taken along a III-III line in FIG 2 .
• 4th Fig. 13 is a diagram for explaining a velocity gradient of an air flow in a downstream area of a first air outlet according to a first comparative example.
• 5 Fig. 13 is a diagram for explaining a state of a lateral vortex and a working air flow in the downstream area of the first air outlet according to the first comparative example.
• 6th Fig. 13 is a diagram for explaining a velocity gradient of an air flow in a downstream area of an air ejection hole of an air ejection device according to a first embodiment.
• 7th Fig. 13 is a diagram for explaining states of a lateral vortex and an additional vortex of an air flow in a downstream area of the air discharge hole of the air discharge device according to the first embodiment.
• 8th Fig. 13 is a schematic perspective view of an air ejecting device according to a second embodiment.
• 9 Fig. 13 is a front view of the air ejecting device according to the second embodiment.
• 10 Fig. 13 is a diagram for explaining a potential core of a working air flow in a downstream area of the second air outlet according to a second comparative example.
• 11 Fig. 13 is a schematic perspective view of an air ejecting device according to a third embodiment.
• 12 Fig. 13 is a schematic front view of the air ejecting device according to the third embodiment.
• 13th Fig. 13 is a diagram for comparing an influence on a working air arrival rate in cases with and without auxiliary holes on a short edge of a hole forming member in the air ejecting device according to the third embodiment.
• 14th Fig. 13 is a diagram for comparing a soundproofing effect of air pressure in cases with and without the auxiliary holes on the short edge of the hole forming member in the air ejecting device according to the third embodiment.
• 15th Fig. 13 is a schematic front view of an air ejecting device according to a first modification of the third embodiment.
• 16 Fig. 13 is a schematic front view of an air ejecting device according to a second modification of the third embodiment.
• 17th Fig. 13 is a schematic perspective view of an air ejecting device according to a fourth embodiment.
• 18th Fig. 13 is a schematic front view of the air ejecting device according to the fourth embodiment.
• 19th FIG. 13 is a sectional view taken along a line XIX-XIX in FIG 18th .
• 20th Fig. 13 is a diagram for explaining a velocity gradient of an air flow in a downstream region of a Air discharge hole of an air discharge device according to a fourth embodiment.
• 21st Fig. 13 is a diagram for explaining states of a lateral vortex and an additional vortex of an air flow in a downstream area of the air discharge hole of the air discharge device according to the fourth embodiment.
• 22nd Fig. 13 is a diagram for explaining a state of an additional vortex of an air flow in a downstream portion of a vortex generating structure of the air ejecting device according to the fourth embodiment.
• 23 Fig. 13 is a schematic front view of an air ejecting device according to a first modification of the fourth embodiment.
• 24 Fig. 13 is a schematic front view of an air ejecting device according to a second modification of the fourth embodiment.
• 25th Fig. 13 is a schematic front view of an air ejecting device according to a third modification of the fourth embodiment.
• 26th Fig. 13 is a schematic front view of an air ejecting device according to a fourth modification of the fourth embodiment.
• 27 FIG. 10 is a sectional view taken along a line XXVII-XXVII in FIG 26th .
• 28 Fig. 13 is a schematic front view of an air ejecting device according to a fifth modification of the fourth embodiment.
• 29 FIG. 10 is a sectional view taken along a line XXIX-XXIX in FIG 28 .
• 30th Fig. 13 is a schematic front view of an air ejecting device according to a fifth embodiment.
• 31 FIG. 14 is a sectional view taken along a line XXXI-XXXI in FIG 30th .
• 32 Fig. 13 is a schematic perspective view of a vortex generating means according to a fifth embodiment.
• 33 Fig. 13 is a diagram for explaining an additional vortex generated downstream of the vortex generating means according to the fifth embodiment.
• 34 Fig. 13 is a schematic front view of an air ejecting device according to a first modification of the fifth embodiment.
• 35 FIG. 10 is a sectional view taken along a line XXXV-XXXV of FIG 34 .
• 36 Fig. 13 is a schematic front view of an air ejecting device according to a second modification of the fifth embodiment.
• 37 Fig. 13 is a schematic front view of an air ejecting device according to a third modification of the fifth embodiment.
• 38 Fig. 13 is a schematic front view of an air ejecting device according to a fourth modification of the fifth embodiment.
• 39 FIG. 13 is a sectional view taken along a line XXXIX-XXXIX in FIG 38 .
• 40 Fig. 13 is a schematic front view of an air ejecting device according to a fifth modification of the fifth embodiment.
• 41 Fig. 13 is a schematic perspective view of a vortex generating means according to a first modification of the fifth embodiment.
• 42 Fig. 13 is a schematic perspective view of a vortex generating means according to a second modification of the fifth embodiment.
• 43 Fig. 13 is a schematic perspective view of a vortex generating means according to a third modification of the fifth embodiment.
• 44 Fig. 13 is a schematic perspective view of a vortex generating means according to a fourth modification of the fifth embodiment.
• 45 Fig. 13 is a diagram for explaining an open shape of an air discharge hole of an air discharge device according to a sixth embodiment.
• 46 Fig. 13 is a diagram for explaining an air discharge hole according to a first modification of the sixth embodiment.
• 47 Fig. 13 is a diagram for explaining an air discharge hole according to a second modification of the sixth embodiment.
• 48 Fig. 13 is a diagram for explaining an air discharge hole according to a third modification of the sixth embodiment.
• 49 Fig. 13 is a diagram for explaining an air discharge hole according to a fourth modification of the sixth embodiment.
• 50 Fig. 13 is a diagram for explaining an air discharge hole according to a fifth modification of the sixth embodiment.
• 51 Fig. 13 is a diagram for explaining an air discharge hole according to a sixth modification of the sixth embodiment.

Precise description

Embodiments of the present disclosure will be described below with reference to the drawings. In the following embodiments, portions that are the same as or equivalent to those described in the above embodiments are denoted by the same reference numerals, and description of the same or equivalent portions may be omitted. In addition, when only a part of the components are described in the embodiment, the components described in the above embodiment can be applied to the other parts of the components. The following embodiments can partially be combined with one another, even if such a combination is not expressly described, as long as there is no disadvantage with regard to such a combination.

(First embodiment)

The present embodiment is described with reference to FIG 1 to 7th described. An air expulsion device 1 of the present embodiment is used for an air outlet of an air conditioning unit that air conditions a vehicle interior. The air outlet of the air conditioning unit is provided in an instrument panel or on the instrument panel.

As in the 1 to 3 shown is an air ejecting device 1 set up to a channel 14th having a flow passage 18th limited by a working air flow Waf that occurs toward an ejection target 2 to be ejected, and a hole forming member 12 that has an air exhaust hole 10 limited that as an air outlet of the working airflow Waf is used, as well as a flange 40 to include.

The channel 14th is a cylindrical element. The channel 14th has an upstream portion in an air flow direction inserted into an air outlet of an air conditioning unit (not shown) and a downstream portion in the air flow direction connected to an outer periphery of the hole formation member 12 connected is. A flow passage 18th is in the canal 14th educated.

The hole forming element 12 is downstream of the channel 14th arranged in the air flow direction. The hole forming element 12 is formed in a tubular shape so that air can be blown out.

An air exhaust hole 10 is as a single hole at one end of the hole forming member 12 open. The air exhaust hole 10 has an open shape that faces towards an ejection target 2 is open to the working airflow Waf toward the ejection destination 2 to eject.

The open shape of the air exhaust hole 10 is for example a flat shape. Here, the flat shape is a shape that has a pair of long edges 102 oriented in the direction of a short axis Ss and a pair of short edges 104 aligned in the direction of the long axis Ls are connected to each other. The short axis Ss is perpendicular to the long axis Ls. The air exhaust hole 10 is designed so that the length of the short edge 104 is shorter than the length of the long edge 102 . The short axis Ss is a center line passing through the midpoints of the long edges 102 which are opposite to each other, and the long axis Ls is a center line passing through the centers of the short edges 104 runs opposite each other.

The flat shape is, for example, an elliptical shape formed by combining arcs and straight lines, or an elliptical shape formed by connecting curved lines having a large radius of curvature and a small radius of curvature, or a polygonal shape such as hexagons formed by connecting straight lines or a rectangular shape with rounded corners. Furthermore, the shape of the long edge 102 and the short edge 104 not limited to a straight line or an arc, and may have an uneven surface with a concavity and a convexity.

As in 2 shown are a pair of long edges 102 each of which extends in the direction parallel to the long axis Ls, and a pair of short edges 104 each of which extends in an arc shape in the direction parallel to the short axis Ss, connected to the open shape of the air discharge hole 10 to train. The short edge 104 is a substantially semicircular arc and has a diameter that is smaller than the length of the long edge 102 is.

More specifically, is a peripheral edge portion 100 that the air exhaust hole 10 surrounds, by a first edge 102a and a second edge 102b facing each other at a predetermined distance, and third and fourth edges 104a , 104b set up, each having two ends of the first edge 102a and the second edge 102b connects. The third edge 104a connects ends of the first edge 102a and the second edge 102b . The fourth edge 104b connects the other ends of the first edge 102a and the second edge 102b .

The first edge 102a and the second edge 102b extend in a straight line with a predetermined distance therebetween. Both the first edge 102a as well as the second edge 102b has a length along the edge that is longer than that of the third edge 104a or the fourth edge 104b , and where is the distance between the first edge 102a and the second edge 102b is smaller than the distance between the third edge 104a and the fourth margin 104b . The first edge 102a and the second edge 102b form the pair of long edges 102 described above.

Furthermore, both the third edge 104a as well as the fourth margin 104b curved in an arch shape. Both the third edge 104a as well as the fourth margin 104b have a length along the edge that is shorter than that of the first edge 102a or the second edge 102b , and where is the distance between the third edge 104a and the fourth margin 104b is greater than the distance between the first edge 102a and the second edge 102b . The third edge 104a and the fourth margin 104b form a pair of short edges 104 described above.

In the hole forming member 12 is a multitude of additional holes 202a as a vortex generating structure 20th educated. More specifically, is the multitude of additional holes 202 along the pair of long edges 102 and from the pair of short edges 104 designed to be at regular intervals over the entire peripheral edge portion 100 of the air exhaust hole 10 To be arranged side by side.

The opening areas of the additional holes 202 are smaller than the opening area of the air discharge hole 10 . Furthermore, the additional hole has 202 a circular shape. As in 3 shown is the extra hole 202 formed to pass through the interior of the hole forming member 12 along a direction of extent of the flow passage 18th to penetrate. An upstream end of the hole forming member 12 in one air flow direction can be provided to become a flange 40 to extend. In this case the extra hole is 202 formed to pass through the hole forming member 12 from the outlet to the flange 40 to penetrate.

The flange 40 is on an outer edge of the channel 14th provided to get out of the canal 14th to protrude outwards. The flange 40 is formed from a rectangular element with rounded four corners. The flange 40 is an element that can be attached to an instrument panel (not shown). The flange 40 is fixed to the instrument panel by a connecting member such as a screw in a state in which a portion of an upstream side of the duct 4th inserted into the air outlet of the air conditioning unit. The flange 40 is with through holes 402 through which a connector such as a screw is inserted near the four corners.

Both the hole forming element 12 , the channel 14th as well as the flange 40 who have favourited the air ejector 1 set up are made of a resin. The hole forming element 12 , the channel 14th and the flange 40 are formed as an integrally molded product which is integrally molded by a molding technique such as injection molding. In addition, the hole forming element 12 , the channel 14th and the flange 40 partially furnished separately. The air expulsion device 1 set up as described above is installed on an instrument panel (not shown) as described above.

Here is the air ejection device 1 attached to an air conditioning unit in the instrument panel, which is installed in the foremost part of the vehicle interior. In this case, conditioned air, the temperature of which is adjusted by the air conditioning unit, becomes out of the air ejecting device 1 blown out. It may be necessary here for the conditioned air not only to be used for air conditioning an entire passenger compartment, but also to be expelled directly to a passenger in the passenger compartment. In this case, it is necessary to blow not only to a seated person in the front row of the driver's seat in the passenger compartment, but also to a seated person in the rear row of the rear seat, and therefore it is necessary that the working air flow Waf has a large area of effect (a large range).

Therefore, the inventors of the present disclosure have studied the factors affecting the effective range of the working air flow Waf shorten. In the vicinity of a downstream air portion of the air discharge hole 10 becomes a large number of transverse vortices Vt generated in the velocity boundary layer BL is combined and developed into a large vortex, so that the air suction effect, which is one of the factors affecting the effective range of the working air flow, becomes stronger Waf shorten.

The air suction is created by the transverse vortex Vt caused by the shear force due to the velocity gradient of the working air flow Waf is generated when the working air flow Waf from the air exhaust hole 10 is blown out. The following are the air suction and the transverse vortex Vt by the working air flow Waf is generated with reference to FIG 4th and 5 described.

4th Fig. 12 is a schematic diagram showing a first outlet which is a first comparative example of the air ejecting device 1 of the present embodiment. The open shape of the air exhaust hole 10 of the first outlet, like the first comparative example, is an elliptical shape formed by combining an arc and a straight line. In addition, in the first comparative example, is in the hole forming member 12 of the first outlet no hole is provided that the additional hole 202 corresponds.

As in 4th shown when the air flow from the air discharge hole 10 of the canal 14th is blown out, a difference in speed becomes between the flow of air from the air discharge hole 10 and the air around the air exhaust hole 10 standing is downstream of the outlet of the air discharge hole 10 causes. As a result, the speed boundary layer BL is formed.

The velocity boundary layer BL is in the air emerging from the air discharge hole 10 is blown out, a layer affected by the stagnant air.

In the speed boundary layer BL, as in 5 shown, an unlimited number of transverse vortices Vt generated by the shear force due to the velocity gradient. According to the study by the inventors of the present disclosure, it was found that the synthesis of innumerable transverse vortices Vt generated in the velocity boundary layer BL is made to develop to a large extent, so that the air suction (entrainment of air) becomes stronger.

The inventors of the present disclosure have studied that when an auxiliary vortex Vs which has a vortex characteristic that is different from that of the transverse vortex Vt is different, with the transverse vortex Vt collides in the velocity boundary layer BL of the working air flow Waf is generated, the development of the transverse vortex Vt can be suppressed, and the effective range of the working air flow Waf can be extended. Hence the vortex generating structure 20th to generate the additional vortex Vs in the hole forming member 12 educated.

Here, the vortex characteristic denotes a vortex flow state including a vortex rotating direction, a vortex axis direction, a vortex flow velocity, a fluid viscosity, a vortex radius and the like.

The state of the working airflow Waf downstream of the outlet of the air discharge hole 10 the air ejector 1 according to the first embodiment, referring to FIG 6th and 7th described.

At the air ejector 1 of the present embodiment, when the conditioned air, the temperature of which has been adjusted by the air conditioning unit, enters the duct 14th flows, the conditioned air flows into the air discharge hole 10 and the extra hole 202 through the flow passage 18th .

As in 6th is shown when the working airflow Waf from the air exhaust hole 10 is blown out, a speed boundary layer BL of the working air flow Waf downstream of the outlet of the air discharge hole 10 educated. The velocity boundary layer BL extends to from the inner wall surface 110 of the air exhaust hole 10 on a downstream side of the outlet of the air discharge hole 10 to be continuous. As a result, there are innumerable transverse vortices Vt on the downstream side of the outlet of the air discharge hole 10 generated.

As in 7th shown have the innumerable transverse vortices Vt that is downstream of the outlet of the air discharge hole 10 are generated, a vortex axis that is aligned with the flow direction of the working air flow Waf cuts and a rotary component from the inside of the air discharge hole 10 towards the outside, in addition to a straight component in the same direction as the flow direction of the working air stream Waf .

Further, when the auxiliary air flow Saf from the auxiliary holes 202 is blown out, the velocity boundary layer BL of the auxiliary air flow Saf becomes on the downstream side of the outlet of the auxiliary holes 202 educated. The velocity boundary layer BL extends to from the inner wall surface 210 of the additional hole 202 on the downstream side of the outlet of the auxiliary hole 202 to be continuous. As a result, there are countless additional eddies Vs on the downstream side of the outlet of the auxiliary holes 202 educated.

The countless transverse vortices Vs that is downstream of the outlet of the auxiliary hole 202 have a swirl axis intersecting with the flow direction of the auxiliary air flow Saf and a rotational component from the inside of the auxiliary hole 202 towards the outside, in addition to a straight component in the same direction as the flow direction of the auxiliary air stream Saf. Part of the additional vortex Vs differs from the transverse vortex Vt at least with regard to the direction of rotation of the vortex Vortex characteristics. The additional air flow Saf has the same flow direction as the working air flow Waf .

Therefore, the downstream of the outlet of the auxiliary hole collides 202 (that is, downstream of the outlet of the air discharge hole 10 ) the additional vortex Vs , which has a direction of rotation that of the transverse vortex Vt is different, with the transverse vortex Vt . When the transverse vortex Vt and the additional vortex Vs collide with each other, the transverse vortex Vt severely disturbed, and so it is for the transverse vortex Vt difficult to set up. That is, the development of the transverse vortex Vt , the downstream of the outlet of the air discharge hole 10 is generated is suppressed. As a result, the air suction effect in the working air flow Waf suppressed so that the working air flow Waf has a larger scope.

In the air ejecting device described above 1 becomes the vortex generating structure 20th through the additional holes 202 realized in the hole forming element 12 are trained. The suction effect of the air created by the working air flow is corresponding Waf is sucked, suppressed, and wherein the reduction in the flow rate of the working air flow Waf is reduced. Therefore, it is possible to adjust the working air flow area Waf to increase.

Further, when the conditioned air, the temperature of which is adjusted by the air conditioning unit, from the air discharge hole 10 than the working airflow Waf is blown out, the working air flow is suppressed Waf the air suction effect from the environment, so that the temperature change of the working air flow Waf can be reduced. That is, according to the air ejecting device 1 According to the present embodiment, an air flow having a suitable temperature can reach a desired location, and particularly this is particularly effective for realizing point air conditioning in the vehicle interior.

(Second embodiment)

Next, a second embodiment will be described with reference to FIG 8th to 10 described. The present embodiment differs from the first embodiment in that the plurality of additional holes 202 is designed to be on the edge side of the long edge 102 to be postponed. In the present embodiment, a different part from the first embodiment is mainly described, and description is omitted for a part similar to the first embodiment.

As in the 8th and 9 shown are a pair of long edges 102 each of which linearly extends in the direction parallel to the long axis Ls, and a pair of short edges 104 each of which extends in an arc shape in the direction parallel to the short axis Ss, connected to a shallow open shape of an air discharge hole 10 to train.

Furthermore, the number of the plurality of auxiliary holes is 202 running along the peripheral edge portion 100 are formed of the air discharge hole 10 surrounds, set so that the number of additional holes 202 running along the pair of long edges 102 is formed is larger than the number of additional holes 202 running along the pair of short edges 104 is trained. That is, an opening ratio of the plurality of auxiliary holes 202 in the hole forming member 12 is set so that the aperture ratio of the plurality of auxiliary holes 202 to a predetermined area of the entire long edges 102 is larger than the opening ratio of the plurality of auxiliary holes 202 to a predetermined area of the entire short margins 104 .

In a case where the open shape of the air discharge hole 10 is a flat shape, becomes a transverse vortex Vt on a downstream side of the short edge 104 and on a downstream side of the long rim 102 generated when the working air flow Waf from the air exhaust hole 10 is blown out. As a result of careful study by the inventors of the present disclosure, the transverse vortex deteriorates Vt that is on the downstream side of the short edge 104 is generated, the effective area of the working air flow Waf less compared to the transverse vortex Vt that is on the downstream side of the long rim 102 is produced.

This is because of the transverse vortex Vt that is on the downstream side of the short edge 104 is generated, further from a potential core P of the working air flow Waf away than the transverse vortex Vt that is on the downstream side of the long rim 102 is produced. The range of the working airflow Waf is made by the transverse vortex Vt that is on the downstream side of the long rim 102 is generated, the transverse vortex Vt that is on the downstream side of the short edge 104 is generated, as well as a distance from the potential core P of the working air flow Waf impaired. According to such an idea, the transverse vortex has Vt that is on the downstream side of the long rim 102 produced has a greater effect on the range of the working airflow Waf compared to the transverse vortex Vt that is on the downstream side of the short edge 104 is produced.

According to the inventors' studies of the present disclosure, a range of the working air flow becomes Waf approximately similar to a case where the auxiliary holes 202 along the entire peripheral edge portion 100 of the air exhaust hole 10 are formed, even if the additional holes 202 mainly on the edge side of the long rim 102 are trained.

The potential core P is described below with reference to FIG 10 described. 10 Fig. 13 is a diagram for explaining the potential core P of the working air flow on a downstream side of the second air outlet according to a second comparative example. The opening shape of the air discharge hole 10 of the outlet of the second comparative example is an elliptical shape formed by combining an arc and a straight line. The additional hole 202 is in a peripheral edge portion 100 an air discharge hole 10 of the second outlet not formed.

As in 10 is shown when the working airflow Waf from the air exhaust hole 10 is blown out, there are innumerable transverse vortices Vt downstream of the outlet of the air discharge hole 10 along the peripheral edge portion 100 of the air exhaust hole 10 generated. As the distance from the air discharge hole becomes larger 10 become innumerable transverse vortices Vt built up and developed, and the air suction effect becomes stronger. As a result, the flow velocity of the working air flow decreases Waf .

Here, a potential core P in which turbulence of the air flow is small and the air flow speed and air flow pressure are stable is in a central area on a downstream side of the air discharge hole 10 educated. The potential core P is an area that is not easily affected by the surrounding air. Therefore, the working airflow has Waf a flow velocity which is hardly reduced in the potential core P and has the greatest range in the potential core P.

In the present case, the cross-sectional area of the potential core P becomes in a direction perpendicular to the flow direction of the working air flow Waf with itself from the air exhaust hole 10 farther away potential core P is smaller. When the opening shape of the air discharge hole 10 is flat, the cross-sectional area of the potential core P converges from a flat shape to a circular shape toward the center of the flat shape as well as toward the downstream side of the working air flow Waf .

Because, on the other hand, the multitude of transverse vortices Vt that is downstream of the outlet of the air discharge hole 10 is generated along the inner wall surface 110 of the air exhaust hole 10 is formed, the plurality of transverse vortices Vt that have a flat shape similar to the shape of the air discharge hole 10 have effected and toward the downstream side of the working air flow Waf expanded. Hence the transverse vortex Vt that is downstream of the short edge outlet 104 is generated, formed at a position further from the potential core P than the transverse vortex Vt that is downstream of the long rim outlet 102 is produced.

The inventors of the present disclosure have studied that when an auxiliary vortex Vs which has a vortex characteristic that is different from that of the transverse vortex Vt is different, with the transverse vortex Vt collides, the one on the downstream side of the long rim 102 is generated, the effective range of the working air flow Waf can be enlarged. Hence the multitude of additional holes 202 in a staggered manner mainly on the edge side of the long edge 102 educated.

In the present embodiment, the transverse vortex Vt that is downstream of the short edge outlet 104 is generated, away from the potential core P of the working air flow Waf arranged compared to the transverse vortex Vt that is downstream of the long rim outlet 102 is generated because the opening shape of the air discharge hole 10 is flat. The transverse vortex Vt that is on the downstream side of the short edge 104 generated has a smaller effect on the range of the working air flow Waf compared to the transverse vortex Vt that is on the downstream side of the long rim 102 is produced.

The multitude of additional holes 202 is in a staggered manner on the marginal sides of the pair of long margins 102 educated. The additional vortex Vs , the downstream of the outlet of the auxiliary hole 202 is formed, collides with the transverse vortex Vt that is downstream of the outlet from the pair of long edges 102 is generated in a state where the vortex rotating directions are different. When the transverse vortex Vt which has a major impact on the range of the working airflow Waf has, with the additional vortex Vs collides, the transverse vortex Vt strongly disturbed, so that the structure of the transverse vortex Vt less likely to occur. As a result, the air suction becomes in the working air flow Waf suppressed so that the working air flow Waf has a larger scope.

If present the transverse vortex Vt with the additional swivel Vs collides, causes the transverse vortex to collide Vt and the additional vortex Vs an air noise. In the present embodiment, the number is the plurality of auxiliary holes 202 on the marginal sides of the pair of short margins 104 compared with those in the first embodiment. Therefore, the collision of the transverse vortex Vt and the additional vortex Vs compared with the case where the additional holes 202 along the entire peripheral edge portion 100 of Air exhaust hole 10 are trained to be suppressed. As a result, it is possible to reduce the air noise caused by the collision of the transverse vortex Vt and the additional vortex Vs is generated while reducing the range of the working airflow Waf is increased sufficiently.

(Modification of the second embodiment)

In the above-described second embodiment, an example has been described in which the auxiliary holes 202 that are the same shape and size, mainly on the edge side of the long edge 102 are formed, but the present disclosure is not limited thereto. For example, the shape and size of the additional hole 202 that on the short edge 104 is formed, on the shape and size of the auxiliary hole 202 be different, the one on the long edge 102 is designed so that the additional vertebra Vs on the marginal side of the pair of long holes 102 compared to the marginal side of the pair of short holes 104 is simply generated. More specifically, one of the additional holes 202 that is on the short edge 104 are formed to be larger, and the other may be smaller than the auxiliary hole 202 that in the long edge 102 is trained. Alternatively, this can be an additional hole 202 may be formed in a circular shape, and the other of the auxiliary holes 202 be formed in a polygonal shape.

The vortex characteristics of the transverse vortex Vt , the downstream of the outlet of the auxiliary hole 202 are formed differ depending on the shape and size of the auxiliary hole 202 . Therefore, it is desirable that the shape and size of the auxiliary hole 202 in accordance with the intended use of the air ejector 1 be determined in an appropriate manner.

(Third embodiment)

Next, a third embodiment will be described with reference to FIG 11 to 16 described. The present embodiment differs from the second embodiment in a plurality of additional holes 202 that are on the marginal sides of the long margins 102 are formed and on the marginal sides of the pair of short margins 104 are not trained. In the present embodiment, a different part from the second embodiment is mainly described, and description is omitted for a part similar to the second embodiment.

More precisely, as in the 11 and 12 shown are the edge sides of the pair of short edges 104 not with the extra holes 202 but are the additional holes 202 only the marginal sides of the pair of long margins 102 educated.

In the present embodiment, the additional vortex Vs running along the pair of long edges 102 is generated, brought about with the transverse vortex Vt to collide, the downstream of the outlet of the long edge 102 is generated, so that developing the additional vortex Vs that is downstream of the long rim outlet 102 generated can be suppressed.

13th shows an arrival rate (a range rate) of the working airflow Waf in a case where the additional holes 202 along the marginal sides of the pair of short margins 104 are formed, and in a case where the auxiliary holes 202 along the marginal sides of the pair of short margins 104 are not trained. The left graph of the 13th shows the rate of arrival of the working airflow Waf when the additional hole 202 is formed, and the right graph of 13th shows the rate of arrival of the working airflow Waf when the additional hole 202 is not trained. As in 13th shown is in both cases where the additional holes 202 along the marginal sides of the pair of short margins 104 are formed and are not formed, the arrival rate of the working air flow Waf roughly the same.

14th shows air noise caused by a collision of the transverse vortex Vt and the additional vortex Vs with and without the additional holes 202 is generated along the marginal sides of the pair of short margins 104 are trained. The left graph of the 14th shows an air noise when the additional hole 202 is formed, and the right graph of 14th shows an air noise when the additional hole 202 is not trained. As in 14th is shown when the additional holes 202 along the marginal sides of the pair of short margins 104 are not formed, the air noise can be reduced as compared with the case where the auxiliary holes 202 are trained.

In general, the instrument panel is required to be miniaturized from the point of view of the design and the extent of the vehicle interior. In addition, the instrument panel tends to install a large-sized information device for displaying the vehicle state and the like in a central portion in the vehicle width direction and / or a portion facing the occupant in the vehicle front-rear direction. Therefore, it is necessary to take measures such as reducing the width of the air discharge hole 10 to take.

According to this embodiment, the additional hole is 202 along the marginal sides of the pair of short edges 104 not trained. Therefore, required in the hole forming member 12 the pair of short edges 104 no training section for forming the auxiliary hole 202 . As a result, the hole forming member 12 and the channel 14th can be made smaller than those in the first and second embodiments, thereby providing flexibility of installation and flexibility of assembling the air ejecting device 1 be improved.

(Modification of the third embodiment)

In the third embodiment described above, an example was described in which the auxiliary hole 202 is formed in a circular shape, but the shape is not limited thereto. As, for example, in the first variant of the 15th is shown, the additional hole 202 be formed in a slot shape.

Further, the third embodiment describes an example in which the pair of long edges 102 extending straight in the direction parallel to the long axis Ls, and the pair of short edges extending in an arc shape in the direction parallel to the short axis Ss are connected to the open shape of the air discharge hole 10 to train; however, the present disclosure is not limited thereto. As in 16 shown can have a pair of long edges 102 each of which linearly extends in the direction parallel to the long axis Ls, and a pair of short edges 104 each of which linearly extends in the direction parallel to the straight axis Ss are connected to form a rectangular open shape of an air discharge hole 10 to train.

(Fourth embodiment)

Next, a fourth embodiment will be described with reference to FIG 17th to 22nd described. Compared with the first embodiment, the present embodiment has other points of vortex generation structure 20th where concave sections 206 and convex sections 208 along a peripheral edge portion 100 of the hole forming member 12 that has an air exhaust hole 10 limited, are arranged alternately. In the present embodiment, a different part different from the first embodiment will mainly be described, and a description will be omitted for a part similar to the first embodiment.

As in the 17th and 18th shown comprises the vortex generating structure 20th a variety of uneven sections 204 in which the concave sections 206 and the convex sections 208 along the peripheral edge portion 100 of the hole forming member 12 that the air exhaust hole 10 limited, are arranged alternately. Further, is the open shape of the air discharge hole 10 formed by a pair of sawtooth-shaped long edges 102 extending in the direction parallel to the long axis Ls, and a pair of short edges 104 extending in an arc shape with respect to the direction parallel to the short axis Ls. In the present case, the sawtooth shape is a shape in which the bases of a plurality of triangles are continuously connected to one another.

More specifically, the triangle is essentially an isosceles triangle that has a base and two equilateral sides, and with the base along the long edge 102 is arranged without a gap. Furthermore, the vertices of the substantially isosceles triangles are designed to move in the direction of the vertices of the substantially isosceles triangles of the opposite long edges 102 at the pair of long edges 102 to lead. The area of each substantially isosceles triangle is smaller than an opening area of the air discharge hole 10 to control the flow of the working airflow Waf coming out of the air exhaust hole 10 blown out, not affecting it.

Furthermore, the multitude of uneven sections 204 not along the marginal sides of the pair of short margins 104 but is only formed along the edge sides of the pair of long edges 102 educated.

However, the multitude of uneven sections can occur 204 along the short edge 104 in addition to the long edge 102 be trained.

A cross section of the air exhaust hole 10 is made with reference to 19th described. As in 19th shown is the plurality of uneven sections 204 formed in a plate shape having a thickness in the air flow direction. That is, the multitude of uneven sections 204 each have a rectangular shape in cross section.

The plate surface on the downstream air side of the plurality of uneven portions 204 is on the same surface as the end surface of the downstream air side of the peripheral edge portion 100 of the hole forming member 12 . In other words, with the large number of uneven sections 204 For example, the plate surface on the downstream side of the air flow is arranged on the same surface as the end surface of the hole forming member 12 , in which the air exhaust hole 10 opens.

The states of the working air flow Waf , of the transverse vortex Vt and the additional vortex Vs downstream of the outlet of the air discharge hole 10 the air ejector 1 according to the fourth embodiment are described with reference to FIG 20th to 22nd described.

At the air ejector 1 In the present embodiment, the conditioned air flows into the air discharge hole 10 through the flow passage 18th when the conditioned air whose temperature has been adjusted by the air conditioning unit enters the duct 14th flows.

As in 20th is shown when the working airflow Waf from the air exhaust hole 10 is blown out, the speed boundary layer BL is formed. As a result, there are innumerable transverse vortices Vt on the downstream side of the outlet of the air discharge hole 10 generated.

As in 21st shown have the innumerable transverse vortices Vt that is downstream of the outlet of the air discharge hole 10 are generated, a vortex axis that is aligned with the flow direction of the working air flow Waf cuts and a rotary component from the inside of the air discharge hole 10 towards the outside, in addition to a straight component in the same direction as the flow direction of the working airflow Waf .

Furthermore, if the working air flow Waf from the gaps between the plurality of uneven sections 204 is blown out with essentially isosceles triangles, there are countless additional vortices Vs on the downstream side of the airflow of the uneven sections 204 generated.

As in 22nd shown, there are countless additional vortices Vs on the downstream air side of the plurality of uneven portions 204 generated on the corresponding equilateral sides of the substantially isosceles triangles. The additional vortex Vs has a vortex axis that is perpendicular to the equilateral side of the isosceles triangle. Furthermore, the directions of rotation are the vortices of the additional vortex Vs , which are generated on the respective equilateral sides of the substantially isosceles triangles, opposite to each other. That means the countless additional vortices Vs differ from the transverse vortex Vt at least with regard to the direction of rotation of the vortex and the direction of the vortex axis of the vortex characteristics.

Therefore, on the downstream side of the outlet, the air discharge hole collides 10 that is downstream of the uneven section 204 is, the transverse vortex Vt with the additional swivel Vs , which has a direction of rotation and a vortex axis that is different from that of the transverse vortex Vt are different. When the transverse vortex Vt and the additional vortex Vs collide with each other, the transverse vortex Vt severely disturbed, and so it is for the transverse vortex Vt difficult to set up. That is, the development of the transverse vortex Vt , the downstream of the outlet of the air discharge hole 10 is generated is suppressed. As a result, the air suction effect in the working air flow Waf suppressed so that the working air flow Waf has a larger scope.

In the present embodiment, the plurality of uneven portions are 204 not along the marginal sides of the pair of short margins 104 but is only formed along the edge sides of the pair of long edges 102 educated. Therefore, the collision of the transverse vortex Vt and the additional vortex Vs compared with a case where the uneven portions 204 along the entire peripheral edge portion 100 of the air exhaust hole 10 are trained. Thus, it is possible to reduce the air noise caused by the collision of the transverse vortex Vt and the additional vortex Vs is generated while the range of the working airflow Waf is appropriately increased.

Further, because in the present embodiment, the plurality of uneven portions 204 only along the marginal sides of the pair of long margins 102 is formed, it is unnecessary to use the uneven portions 204 on the marginal sides of the pair of short margins 104 to train. Therefore, the hole forming member 12 and the channel 14th can be made smaller than a case where the plurality of uneven portions 204 along the entire peripheral edge portion 100 is formed, and thereby the air ejecting device 1 can be easily installed, and mountability of the air ejecting device 1 can be improved.

The multitude of uneven sections 204 is formed in a plate shape having a thickness in the air flow direction. In this case it is more likely that the additional vertebra Vs is generated when the air flow between the uneven sections 204 flows compared with, for example, a case where the plurality of uneven portions 204 are designed to attach to the flange 40 to stretch out. As a result, the air suction becomes in the working air flow Waf suppressed so that the working air flow Waf has a larger scope.

The plate shape on the downstream air side from the plurality of uneven portions 204 is on the same surface as the end surface on the downstream air side of the peripheral edge portion 100 of the hole forming member 12 . Accordingly, the position at which the additional vertebra approaches Vs through the uneven section 204 is generated, the position at which the transverse vortex Vt in the hole forming member 12 begins to perform. Therefore the additional vortex collides Vs simply with the cross swirl Vt , and where a development of the transverse vortex Vt can be sufficiently suppressed.

(Modification of the fourth embodiment)

In the fourth embodiment described above, an example was described in which the plurality of uneven portions 204 is formed in a sawtooth shape having substantially isosceles triangles arranged continuously, but the present disclosure is not limited thereto. As for example in a first modification of the 23 shown may be the shape of the plurality of uneven portions 204 be formed in a rectangular shape. Alternatively, as in a second modification of the 24 shown is the shape of the plurality of uneven portions 204 be formed in an arc shape. Alternatively, as in a third modification of the 25th shown is the shape of the plurality of uneven portions 204 be formed in a waveform. Further, the shape of the plurality of uneven portions 204 be formed in a shape of substantially equilateral triangles or a shape of substantially right triangles. Additionally, the shapes of the multitude of uneven sections can be used 204 be formed by combining triangular shapes, rectangular shapes, arc shapes, wave shapes and the like. Furthermore, the concave portion 206 and the convex section 208 Be formed side by side with a certain distance.

Further, the fourth embodiment described above describes an example in which the vertices of the substantially isosceles triangles of the plurality of uneven portions 204 are designed to move in the direction of the vertices of the approximately isosceles triangles of the opposite long edge 102 to preside; however, they are not limited to this. As for example in a fourth modification of the 26th shown, the vertices of the substantially isosceles triangles in the channel 14th be configured to move toward an upstream direction of airflow in the duct 14th to lead. More specifically, as in the cross section of the fourth modification shown in FIG 27 shown can be the multitude of uneven sections 204 be configured to move in the upstream direction of the airflow of the duct 14th to be inclined. Alternatively, as in a fifth modification of the 28 is shown the vertices of the substantially isosceles triangles in the channel 14th be configured to move toward a downstream direction of airflow in the duct 14th to lead. More specifically, as shown in the cross section of the fifth modification shown in FIG 29 shown can be the multitude of uneven sections 204 be configured to flow in the downstream direction of the air flow of the duct 14th to be inclined.

Further, in the fourth embodiment described above, an example was described in which the plurality of uneven portions 204 is formed in a plate shape, but the shape is not limited thereto. For example, if the shape of the multitude of uneven sections 204 on the opening side of the air discharge hole 10 is triangular, is the shape of the inner portion of the hole forming member 12 a triangular pyramid or a triangular prism, and wherein the end of the hole-forming element 12 within the channel 14th may extend towards the upstream side of the airflow.

Further, the shape of the multitude of uneven portions became 204 described as an example where the uneven sections 204 toward the inside of the air exhaust hole 10 protrudes, but the shape is not limited thereto. The multitude of uneven sections 204 may be formed to be from the peripheral edge 100 of the air exhaust hole 10 toward the outside of the discharge hole 10 to be recessed, or the multitude of uneven sections 204 may be arranged alternately to an inside of the air discharge hole 10 to protrude and to the outside of the air discharge hole 10 to be absorbed.

Further, in the fourth embodiment described above, the vortex generation structure was used 20th described in the case of the multitude of uneven sections 204 is formed, but is the vortex generating structure 20th not limited to that. The vortex generating structure 20th can have a variety of additional holes 202 shown in the first embodiment, in addition to the plurality of uneven portions 204 include.

(Fifth embodiment)

Next, a fifth embodiment will be described with reference to FIG 30th and 31 described. The present embodiment differs from the first embodiment in that the vortex generating structure 20th has a structure that has a plurality of vortex generating means 22nd includes. In the present embodiment, a description will mainly be given of a different part different from the first embodiment, and description will be omitted for a part similar to the first embodiment.

As in 30th shown is the vortex generating structure 20th from a variety of Vortex generating means 22nd formed side by side along the peripheral edge portion 100 of the hole forming member 12 that the air exhaust hole 10 limited, are arranged. In addition, the opening shape of the air discharge hole is 10 a flat shape and is characterized by a pair of straight long edges 102 and a pair of arcuate short edges 104 formed, which are connected to each other.

Any of a variety of vortex generating means 22nd is formed of a disk-shaped member that has a circular shape when facing from the opening direction of the air discharge hole 10 is looked at. The variety of vortex generating means 22nd is in the air discharge hole 10 equally spaced along the perimeter 100 of the air exhaust hole 10 arranged. The variety of vortex generating means 22nd has an area smaller than the opening area of the air discharge hole 10 to control the flow of the working airflow Waf not to affect the one from the air exhaust hole 10 is blown out. The variety of vortex generating means 22nd is in the air discharge hole 10 at equal intervals along the peripheral edge portion 100 of the air exhaust hole 10 arranged.

The variety of vortex generating means 22nd is in the air discharge hole 10 by a support section 23 which extends in a predetermined direction perpendicular to the opening direction of the air discharge hole 10 is around the peripheral edge portion 100 not to be touched directly. More specifically, each of the plurality of vortex generating means 22nd is with a tip portion of a rod-shaped support portion 23 connected from the peripheral edge portion 100 protrudes inwards.

Furthermore, the plurality of vortex generating means 22nd mainly on the marginal sides of the pair of long margins 102 compared to the marginal sides of the pair of short margins 104 arranged. More precisely, the multitude of vortex generating means 22nd is not along the marginal sides of the pair of short margins 104 but is merely along the marginal sides of the pair of long margins 102 arranged. However, the variety of vortex generating means 22nd along the short edge 104 in addition to the long edge 102 be trained.

As in 31 shown are the plurality of vortex generating means 22nd plate-shaped members having a thickness in the opening direction of the air discharge hole 10 . More precisely, as in 32 shown has each of the vortex generating means 22nd a circular shape when it is from the opening direction of the air discharge hole 10 is viewed, and has a disk-shaped member having a rectangular shape when viewed from a direction perpendicular to the opening direction of the air discharge hole 10 is.

The plate surface on the downstream air side of the plurality of vortex generating means 22nd is on the same surface as the end surface of the downstream air side of the peripheral edge portion 100 of the hole forming member 12 . In other words, with the plurality of vortex generating means 22nd , the plate surface on the downstream side of the airflow is arranged on the same surface as the end surface of the hole forming member 12 where the air exhaust hole is 10 opens.

At the air ejector 1 with the above structure, the conditioned air flows into the air discharge hole 10 through the flow passage 18th when the conditioned air whose temperature has been adjusted by the air conditioning unit enters the duct 14th flows. When the working airflow Waf from the air exhaust hole 10 is blown out, there are innumerable transverse vortices Vt downstream of the air discharge hole 10 generated.

At the air ejector 1 of the present embodiment is a plurality of vortex generating means 22nd in the air exhaust hole 10 arranged. Therefore, some of the conditioned air will pass through the flow passage 18th to the air exhaust hole 10 flows, blown into the passenger compartment after passing around the plurality of vortex generating means 22nd has streamed. When the conditioned air around the multitude of vortex generating means 22nd flows, the air flow separates along the plate surface of the vortex generating means 22nd flows, from the outer edge, so that all-round separating vortices with different vortex axes are generated. As a result, as in 33 shown is countless additional vertebrae Vs on the downstream side of the plurality of vortex generating means 22nd generated in the air stream. The additional vortex Vs becomes on the downstream side of the vortex generating means 22nd generated in the air stream. The additional vortex Vs differs from the transverse vortex Vt at least with regard to the direction of rotation of the vortex and the direction of the vortex axis of the vortex characteristics.

Therefore, on the downstream side of the outlet, the air discharge hole collides 10 the transverse vortex Vt with the additional swivel Vs , which has a direction of rotation and vortex axis that is different from that of the transverse vortex Vt are different. When the transverse vortex Vt and the additional vortex Vs collide with each other, the transverse vortex Vt severely disturbed, and so it is for the transverse vortex Vt difficult to build up. That is, the development of the transverse vortex Vt , the downstream of the outlet of the air discharge hole 10 is generated is suppressed. As a result, the air suction becomes in the working air flow Waf suppressed so that the working air flow Waf has a larger scope.

Furthermore, the plurality of vortex generating means 22nd along the marginal sides of the pair of long margins 102 and is not on the marginal sides of the pair of short margins 104 arranged. Therefore, the collision of the transverse vortex Vt and the additional vortex Vs can be suppressed compared with a case where the swirl generating means 22nd along the entire peripheral edge portion 100 of the air exhaust hole 10 are trained. This can cause air noise caused by the collision of the transverse vortex Vt and the additional vortex Vs is generated, be reduced. Further, it is possible to reduce the opening area of the air discharge hole 10 due to the addition of the plurality of vortex generating means 22nd to suppress.

If present the vortex generating means 22nd directly with respect to the peripheral edge portion 100 is formed, an air flow is formed at a contact portion where the vortex generating means 22nd and the peripheral edge portion 100 are in direct contact with each other, not generated, and the additional vortex can Vs are not generated at the contact portion.

In the present embodiment, the plurality of vortex generating means are 22nd in the air exhaust hole 10 through the support section 23 which extends in a predetermined direction perpendicular to the opening direction of the air discharge hole 10 extends around the peripheral edge portion 100 not to be touched directly. When the vortex generating means 22nd through the support section 23 is supported, the vortex generating means 22nd from the peripheral edge portion 100 be separated. In this case, the additional swivel Vs in almost the entire outer peripheral edge of the vortex generating means 22nd be generated. Therefore, even if the transverse vortex Vt between the vortex generating means 22nd and the peripheral edge portion 100 is generated, the additional vortex Vs , the one on the outer peripheral edge of the vortex generating means 22nd is generated, the development of the transverse vortex Vt suppress.

In addition, there are a variety of vortex generating means 22nd plate-shaped members having a thickness in the opening direction of the air discharge hole 10 to have. The additional vortex becomes accordingly Vs simply generated when the air flow between the vortex generating means 22nd flows. As a result, the additional vortex collides Vs simply with the cross swirl Vt so that the development of the transverse vortex Vt can be sufficiently suppressed.

The plate surface on the downstream air side of the plurality of vortex generating means 22nd is on the same surface as the end surface of the downstream air side of the peripheral edge portion 100 of the hole forming member 12 . Accordingly, the position at which the additional vertebra approaches Vs by the vortex generating means 22nd is generated, the position at which the transverse vortex Vt starts in the hole forming element 12 to occur. Therefore the additional vortex collides Vs simply with the cross swirl Vt , and where a development of the transverse vortex Vt can be sufficiently suppressed.

(Modification of the fifth embodiment)

The fifth embodiment described above exemplifies a case where the plurality of vortex generating means 22nd with the tip end of the rod-shaped support portion 23 is connected from the peripheral edge portion 100 protrudes inward, but the present disclosure is not limited thereto. As for example in a first modification of the 34 and 35 may be any of a variety of vortex generating means 22nd by an L-shaped support section 23 which extends in an L-shape from the inner wall surface of the channel 14th showing the flow passage 18th forms in the direction of the air discharge hole 10 extends.

The fifth embodiment described above exemplifies a case where each of the plurality of vortex generating means 22nd each by the separate support section 23 is based, however, the present disclosure is not limited thereto. For example, at least a part of the plurality of vortex generating means 22nd by a support section 23 be supported which extends along the direction of extension of the pair of long edges 102 extends, as in a second modification of the 36 is shown.

Alternatively, at least a portion of the plurality of vortex generating means may be used 22nd by a support section 23 extending in a direction perpendicular to the extending direction of the pair of long edges 102 is, as in a third modification of the 37 is shown.

Alternatively, as in a fourth modification of the 38 and 39 is shown in a case where one lamella 24 for adjusting the air flow direction or the air volume in the air discharge hole 10 or in the flow passage 18th is arranged, the lamella 24 be set up to a variety of vortex generating means 22nd to support. In this case, the slat represents 24 a support portion supporting the plurality of vortex generating means 22nd supports. Accordingly, even if the position of the slat 24 is changed to change the air flow direction or the like, the locations of the plurality of Vortex generating means 22nd the change of the slat 24 changed below. In this case, the layers of the plurality of vortex generating means 22nd can be changed in accordance with the change in the air flow direction without providing a dedicated mechanism.

In the fifth embodiment described above, the plurality of vortex generating means are 22nd established by plate-shaped members having a thickness in the opening direction of the air passage hole 10 have, and wherein the plate surfaces of the plurality of vortex generating means 22nd are arranged on the same surface as the end surface on which the air discharge hole is located 10 in the hole forming member 12 opens. However, the present disclosure is not limited to this. For example, even if the multitude of vortex generating means 22nd is formed from plate-shaped elements, the plate surfaces of the plurality of vortex generating means 22nd be arranged on a surface facing from the end face of the air discharge hole 10 in the hole forming member 12 is different. Alternatively, the plurality of vortex generating means 22nd Side by side in the opening direction of the air discharge hole 10 be arranged as in the fifth modification of the 40 is shown. In this case, the plurality of vortex generating means 22nd be arranged to face each other in the opening direction of the air discharge hole 10 to overlap, or may be arranged so as not to overlap each other.

In the fifth embodiment described above, each is the vortex generating means 22nd made of a disk-shaped member that has a circular shape when it comes out of the opening direction of the air discharge hole 10 is considered, but the present disclosure is not so limited. The variety of vortex generating means 22nd can for example be set up by an element in which the plurality of vortex generating means 22nd has an elliptical or polygonal shape when viewed from the opening direction of the air discharge hole 10 to be viewed as. Furthermore, the plurality of vortex generating means 22nd may be formed of, for example, a member that has a circular shape, a cone shape, or a polygon shape when viewed from a direction perpendicular to the opening direction of the air discharge hole 10 is.

For example, any of a variety of vortex generating means can be used 22nd from a ball 221 be designed, as in a first modification of the 41 is shown. Alternatively, any of the plurality of vortex generating means can be used 22nd by a polyhedron such as an octahedron 222 , which in a second modification of the 42 is shown and a hexahedron 223 , which in a third modification of the 43 is shown to be set up. In addition, the variety of vortex generating means 22nd from a net body 224 be made, which is formed in a network shape, as in a fourth modification of the 44 is shown.

Further, in the fifth embodiment described above, the vortex generation structure was used 20th described in which the variety of vortex generating means 22nd is formed, but is the vortex generating structure 20th not limited to that. The vortex generating structure 20th may be configured to include at least one of the plurality of auxiliary holes 202 or the multitude of uneven sections 204 in addition to the plurality of vortex generating means 22nd to include.

(Sixth embodiment)

Next, a sixth embodiment will be described with reference to FIG 45 described. The air expulsion device 1 This embodiment is different from the third embodiment in the opening shape of the air discharge hole 10 . In the present embodiment, a different part different from the third embodiment is mainly described, and a description of a part similar to the third embodiment is omitted.

As in 45 is the air discharge hole 10 set up to a first edge 102a and a second edge 102b who have favourited a pair of long edges 102 train, as well as a third edge 104a and a fourth margin 104b to encompass that a pair of short edges 104 form.

A distance between the first edge 102a and the second edge 102b is different in the direction of the long axis Ls. That is, the first edge 102a and the second edge 102b are curved so that the distance therebetween at the central portion in the direction of the long axis Ls is smaller than the distance therebetween at two ends in the direction of the long axis Ls.

On the other hand are the third margin 104a and the fourth margin 104b curved so that the distance therebetween at the central portion in the direction of the short axis Ss is longer than the distance therebetween at two ends in the direction of the short axis Ss. Both the third edge 104a as well as the fourth margin 104b have a length along the edge that is shorter than that of the first edge 102a or the second edge 102b , and where is the distance between the third edge 104a and the fourth margin 104b is greater than the distance between the first edge 102a and the second edge 102b .

The third edge 104a is with one end of the first edge 102a and one end of the second Edge 102b connected so that a connecting portion of the third edge 104a , the one with the first edge 102a or the second edge 102b connected, has a rounding. The fourth margin is similar 104b with the other end of the first edge 102a and the other end of the second edge 102b connected so that the connecting portion of the fourth edge 104a , the one with the first edge 102a or the second edge 102b connected, has a rounding.

The air exhaust hole 10 set up in this way has a deformed oval shape with rounded joints where the first edge 102a and the second edge 102b with the third margin 104a and the fourth margin 104b are connected. In this case, compared with a case where the air discharge hole 10 comprises a corner portion, the development of the transverse vortex Vt near the downstream side of the air discharge hole 10 can be suppressed more easily.

(Modification of the sixth embodiment)

In the sixth embodiment described above, the air discharge hole is 10 curved so that the distance between the middle sections of the first edge 102a and the second edge 102b is smaller than the distance between the first edge 102a and the second edge 102b at the two end sides in the long axis direction Ls; however, the present disclosure is not limited thereto.

For example, as in a first modification of the 46 shown can be the first edge 102a and the second edge 102b of the air exhaust hole 10 be curved so that the distance between the center distances of the first edge 102a and the second edge 102b is greater than the distance between the first edge 102a and the second edge 102b on the two end sides in the direction of the long axis Ls.

Alternatively, as in a second modification of the 47 shown can be the first edge 102a and the second edge 102b of the air exhaust hole 10 be curved so that the distance between the one end sides of the first edge 102a and the second edge 102b is greater than the distance between the other end faces of the first margin 102a and the second edge 102b .

Furthermore, for example, as in the third modification of 48 shown is the first edge 102a and the second edge 102b of the air exhaust hole 10 be curved in the same direction so that the distance between the first edge 102a and the second edge 102a is kept constant.

Alternatively, for example, as in a fourth modification of the 49 shown is the first edge 102a and the second edge 102b of the air exhaust hole 10 be bent in the same direction so that the distance between the first edge 102a and the second edge 102b is kept constant.

Alternatively, for example, as in a fifth modification of the 50 shown is the first edge 102a and the second edge of the air discharge hole 10 with depressions 102c and 102d be provided by the first edge 102a and the second edge 102b are absorbed away.

Alternatively, for example, as in a sixth modification of the 51 shown is the first edge 102a and the second edge 102b of the air exhaust hole 10 with protrusions 102e and 102f be provided that protrude from each other.

Here, the modifications described above exemplify a part of the open shapes of the air discharge hole 10 , and wherein a shape as the open shape of the air discharge hole 10 which is different from the above can be used.

Further, in the sixth embodiment and its modifications, there is the open shape of the air discharge hole 10 in the air ejector 1 , in which the vortex generating structure 20th from a variety of additional holes 202 is shown, but the present disclosure is not limited thereto. The open shape of the air exhaust hole 10 shown in the sixth embodiment and its modifications is also applied to the air ejecting device 1 applicable to the vortex generating structure 20th from a variety of uneven sections 204 or a variety of vortex generating means 22nd is made.

(Other embodiments)

The present disclosure is not limited to the typical embodiments of the present disclosure described herein, but may include various modifications such as the following configurations.

In the embodiment described above, an example has been described in which the auxiliary hole 202 is formed in a circular shape, but the shape is not limited thereto. The additional hole 202 can be formed in an elliptical shape or a polygonal shape, for example. In addition, as shown in the first modification of the third embodiment, the auxiliary hole 202 be formed in a slot shape.

Further, in the embodiment described above, an example in which a pair of straight long edges 102 and a pair of arcuate short edges 104 are connected to the open shape of the air discharge hole 10 to train, described; however, it is the open shape of the air discharge hole 10 not limited to that. For example, the open shape of the air discharge hole 10 be formed by a pair of arcuate long edges 102 and a pair of straight short edges 104 connected in turn. Further, as shown in the second modification of the third embodiment, the open shape of the air discharge hole can be made 10 be formed in a rectangular shape made up of a pair of straight long edges 102 and a pair of straight short edges 104 consists.

In the embodiment described above, an example has been described in which the open shape of the air discharge hole 10 is formed in a flat shape, but the shape is not limited thereto. For example, the open shape of the air discharge hole 10 be formed in a circular shape, an elliptical shape or a polygonal shape.

In the above-described embodiments, it goes without saying that the elements constituting the embodiments are not necessarily essential unless, in the case where these elements have been clearly indicated as being particularly essential, in the case in where these elements are obviously considered essential in principle, and the like.

In the above-described embodiments, the present disclosure is not limited to the specific number of components of the embodiments unless the numerical values such as the number, numerical values, amounts, ranges, and the like are mentioned, particularly when expressly stated are essential, and if they are obviously limited in principle to a certain number, and the like.

In the above-described embodiments, when reference is made to a specific shape, positional relationship, and the like of a component and the like, the present disclosure is not limited to those shape, positional relationship, and the like, unless specifically stated , the case where they are basically limited to a certain shape, positional relationship, and the like.

(Overview)

According to an aspect of the present disclosure described in part or all of the above-described embodiments and their modifications, an air ejection device includes a passage defining a flow passage through which a working air flow passes, and a hole forming member having an air ejection hole as an outlet the working air flow is limited at a downstream end of the duct in an air flow direction. The hole forming member has a vortex generating structure configured to generate an auxiliary vortex having a vortex characteristic including a vortex rotating direction and a vortex axis direction different from that of the transverse vortex. The vortex generation structure is provided in the hole forming member so that the auxiliary vortex collides with the transverse vortex in a state in which at least the vortex rotating direction and / or the vortex axial direction of the vortex characteristic is different from that of the transverse vortex.

According to a second aspect, the vortex generating structure includes a plurality of auxiliary holes that are provided side by side along a peripheral edge portion surrounding the air discharge hole, and wherein the plurality of auxiliary holes are configured to generate auxiliary vortices by blowing air flow from the plurality of auxiliary holes is blown out. The additional vortex differs from the transverse vortex at least in terms of one direction of rotation of the vortex. The additional vortex generated by this structure collides with the transverse vortex, so that development of the transverse vortex can be suppressed. As a result, the suction effect of the air sucked into the working air flow discharged from the air discharge hole is suppressed, and the working air flow discharged from the air discharge hole has a larger effective range.

According to a third aspect, the peripheral edge portion comprises a first edge and a second edge, which are opposite to each other and extend with a predetermined distance therebetween, a third edge connecting the one ends of the first edge and the second edge, and a fourth edge, the connecting the other ends of the first edge and the second edge. The first edge and the second edge establish a pair of long edges opposed to each other with a distance therebetween which is less than a distance between the third edge and the fourth edge. The third edge and the fourth edge establish a pair of short edges facing each other with a distance therebetween which is greater than the distance between the first Edge and the second edge. The plurality of auxiliary holes are provided in the peripheral edge portion mainly on the edge sides of the pair of long edges so that the plurality of auxiliary vortices are less likely to be generated on the edge sides of the pair of short edges than on the edge sides of the pair of long edges. Accordingly, the collision of the lateral vortex and the auxiliary vortex can be suppressed as compared with a case where the auxiliary holes are formed along the entire peripheral edge portion of the air discharge hole. In this case, a range of the working air flow can be made long while air noise generated by the collision of the auxiliary vortex and the lateral vortex can be reduced.

According to a fourth aspect, the air discharge hole has a shallow open shape, and wherein the peripheral edge portion of the air discharge hole includes a pair of long edges and a pair of short edges continuously connected to the pair of long edges. The plurality of auxiliary holes are provided to be staggered on peripheral sides from the pair of long edges. Therefore, the collision of the lateral vortex and the auxiliary vortex can be suppressed as compared with a case where the auxiliary holes are provided along the entire peripheral edge portion of the air discharge hole.

As a result, it is possible to reduce the air noise generated by the collision of the lateral vortex and the auxiliary vortex while properly increasing the range of the working airflow.

According to a fifth aspect, the plurality of auxiliary holes are provided on the edge sides of the pair of long edges and are not provided on the edge sides of the pair of short edges. Therefore, in the hole forming member, the pair of short edges does not require a forming portion for forming the auxiliary hole. As a result, it is possible to reduce air noise and the size of the hole formation member while sufficiently increasing the range of the working air flow, and it is possible to obtain an effect of improving flexibility of installing and flexibility of assembling the air ejecting device .

According to a sixth aspect, the vortex generation structure includes a plurality of uneven portions configured by alternately arranging concave portions and convex portions along the peripheral edge portion of the air discharge hole to generate additional vortices when air flows through between the concave portion and the convex portion. The auxiliary vortex has a vortex rotating direction and a vortex axis direction which are different from those of the transverse vortex. The additional vortex generated by this structure collides with the transverse vortex, so that development of the transverse vortex can be suppressed without severely disrupting the working air flow. As a result, the suction of the air sucked into the working air flow discharged from the air discharge hole is suppressed, and the working air flow discharged from the air discharge hole has a larger effective range.

According to a seventh aspect, the peripheral edge portion includes a first edge and a second edge which are opposite to each other and extend a predetermined distance therebetween, a third edge connecting ends of the first edge and the second edge, and a fourth edge connecting the others Connects ends of the first edge and the second edge. The first edge and the second edge establish a pair of long edges opposed to each other with a distance therebetween which is less than a distance between the third edge and the fourth edge. The third edge and the fourth edge establish a pair of short edges facing each other with a distance therebetween which is greater than the distance between the first edge and the second edge. The plurality of uneven portions are provided in the peripheral edge portion mainly on the edge sides of the pair of long edges so that the plurality of additional vortices are less likely to be generated on the edge sides of the pair of short edges than on the edge sides of the pair of long edges . Accordingly, the collision of the transverse swirl and the auxiliary swirl can be suppressed as compared with a case where the uneven portion is formed along the entire peripheral edge portion of the air discharge hole. In this case, the range of the working air flow can be made sufficiently long while air noise generated by the collision of the auxiliary vortex and the transverse vortex can be reduced.

According to an eighth aspect, the air discharge hole has a flat open shape, and wherein the peripheral edge portion of the air discharge hole includes a pair of long edges and a pair of short edges continuously connected to the pair of long edges. The plurality of uneven portions are provided to be provided on the edge sides of the pair of long edges. Therefore, the collision of the lateral vortex and the auxiliary vortex can be suppressed as compared with a case where the uneven portions along the whole Peripheral edge portion of the air discharge hole are provided. As a result, it is possible to reduce the air noise generated by the collision of the transverse vortex and the auxiliary vortex while sufficiently increasing the range of the working airflow.

According to a ninth aspect, the plurality of uneven portions are formed on the edge sides of the pair of long edges and are not formed on the edge sides of the pair of short edges. Therefore, in the hole forming member, the pair of short edges does not require a forming portion for forming the surrounding portion. As a result, it is possible to reduce the air noise and the size of the hole forming member while sufficiently increasing the range of the working air flow, and it is possible to obtain an effect of improving installation flexibility and assembling flexibility of the air ejecting device.

According to a tenth aspect, the plurality of uneven portions are formed in a plate shape having a thickness in the air flow direction. In this case, the auxiliary vortex is more likely to be generated when the air flows between the uneven portions, compared with a case where the plurality of uneven portions are formed to extend to a flange. As a result, the suction of the air sucked into the working air flow discharged from the air discharge hole is suppressed, and the working air flow discharged from the air discharge hole has a larger effective range.

According to an eleventh aspect, a plate surface on a downstream air side of the plurality of uneven portions is on the same surface as the end surface on the downstream air side of the peripheral edge portion of the hole forming member. Accordingly, the position where the auxiliary vortex is generated by the uneven portion approaches the position where the transverse vortex begins to occur in the hole forming member. Therefore, the auxiliary vortex easily collides with the lateral vortex, and development of the lateral vortex can be sufficiently suppressed.

According to a twelfth aspect, the swirl generating structure is configured to include a plurality of swirl generating means arranged side by side along the peripheral edge portion of the hole formation member defining the air discharge hole. The vortex generating structure is set up such that when air flows around the vortex generating means, the additional vortex, which is different from the transverse vortex with regard to at least the direction of rotation of the vortex and / or the direction of the vortex axis, is generated.

The additional vortex generated by this structure collides with the transverse vortex, so that development of the transverse vortex can be suppressed without severely disrupting the working air flow. As a result, the suction of the air sucked into the working air flow discharged from the air discharge hole is suppressed, and the working air flow discharged from the air discharge hole has a larger effective range.

According to a thirteenth aspect, the plurality of vortex generating means are supported by a support portion in the air discharge hole so as not to directly contact the peripheral edge portion. When the vortex generating means is supported by the support portion, the vortex generating means can be separated from the peripheral edge portion. It is possible to generate additional vortices also between the vortex generating means and the peripheral edge section. Thus, the development of the lateral vortex can be effectively suppressed even if a lateral vortex occurs between the vortex generating means and the peripheral edge portion.

According to a fourteenth aspect, the peripheral edge portion comprises a first edge and a second edge which are opposite to each other and extend with a predetermined distance therebetween, a third edge connecting the one ends of the first edge and the second edge, and a fourth edge which connecting the other ends of the first edge and the second edge. The first edge and the second edge establish a pair of long edges opposed to each other with a distance therebetween which is less than a distance between the third edge and the fourth edge. The third edge and the fourth edge establish a pair of short edges facing each other with a distance therebetween which is greater than the distance between the first edge and the second edge. The plurality of vortex generating means are provided in the peripheral edge portion mainly on the edge sides of the pair of long edges so that the plurality of auxiliary vortices are less likely to be generated on the edge sides of the pair of short edges than on the edge sides of the pair of long edges. Accordingly, the collision of the transverse swirl and the auxiliary swirl can be suppressed compared with a case where the swirl generating means are formed along the entire peripheral edge portion of the air discharge hole. In this case, a range of the working air flow can be made long while air noise caused by the collision of the auxiliary vortex and the lateral vortex can be reduced.

According to a fifteenth aspect, the plurality of vortex generating means are formed on the edge sides of the pair of long edges and are not formed on the edge sides of the pair of short edges. Thus, it is possible to suppress a decrease in the opening area of the air discharge hole due to the addition of the plurality of vortex generating means.

According to a sixteenth aspect, the plurality of swirl generating means are plate-shaped members that have a thickness in an opening direction of the air discharge hole. Accordingly, the additional vortex is easily generated when the air stream flows between the vortex generating means. As a result, the auxiliary vortex simply collides with the transverse vortex, so that the development of the transverse vortex can be sufficiently suppressed. The opening direction is the normal direction of the area surrounded by the edge of the air discharge hole.

According to a seventeenth aspect, a plate surface on the downstream air side of the plurality of vortex generating means is on the same surface as an end surface on the downstream air side of the peripheral edge portion of the hole forming member. Accordingly, the position at which the auxiliary vortex is generated by the vortex generating means approaches the position at which the transverse vortex starts to occur in the hole-forming member. Therefore, the auxiliary vortex easily collides with the lateral vortex, and development of the lateral vortex can be sufficiently suppressed.

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• JP 2018 [0001]
• JP 076325 [0001]
• JP 2018135299 [0001]
• JP 2018199383 [0001]
• JP 2018240807 [0001]
• JP 8318176 A [0004]

Claims (17)

Air ejection device, with: a duct (14) defining a flow passage (18) through which a flow of working air passes to be blown toward an ejection target (2); and a hole forming member (12) defining an air discharge hole (10) located on a downstream air side of the duct as an air outlet from which the working air flow is blown out, wherein the hole formation member has a vortex generation structure (20) configured to generate an auxiliary vortex having a vortex characteristic including a vortex rotating direction and a vortex axis direction different from that of a transverse vortex generated by the working air flow on a side of a downstream air of the Air discharge hole is generated, and the vortex generating structure is set up in the hole formation element such that the additional vortex collides with the transverse vortex in a state in which at least the vortex rotation direction and / or the vortex axial direction of the vortex characteristic of the additional vortex is different from that of the transverse vortex. Air ejector according to Claim 1 wherein the vortex generating structure comprises a plurality of auxiliary holes (202) arranged along a peripheral edge portion (100) of the hole formation member surrounding the air discharge hole, and wherein the plurality of auxiliary holes is configured to generate a plurality of the auxiliary vortices generated by the Transverse whirling is different in terms of at least the direction of rotation of the vortex and / or the axial direction of the vortex. Air ejector according to Claim 2 , wherein the peripheral edge portion of the hole formation member surrounding the air discharge hole has a first edge (102a) and a second edge (102b) which are opposite to each other and extend with a predetermined distance therebetween, a third edge which the one ends of the first edge and of the second edge, and includes a fourth edge connecting the other ends of the first edge and the second edge, the first edge and the second edge establish a pair of long edges opposed to each other with a distance therebetween which is less than one Distance between the third edge and the fourth edge, the third edge and the fourth edge establish a pair of short edges facing each other with a distance therebetween which is greater than the distance between the first edge and the second edge, and the A plurality of auxiliary holes in the peripheral edge portion of the hole forming member surrounding the air discharge hole, mainly I is provided on the marginal sides of the pair of long margins so that the plurality of additional vortices are less likely to be generated on the marginal sides of the pair of short margins than on the marginal sides of the pair of long margins. Air ejector according to Claim 2 wherein the air discharge hole has a flat open shape, the peripheral edge portion of the hole forming member surrounding the air discharge hole includes a pair of long edges (102) opposed to each other in a short axial direction and a pair of short edges (104) to each other opposed in a long axial direction and continuously connected with the pair of long edges, the short edge having a length smaller than a length of the long edge, the plurality of auxiliary holes in the peripheral edge portion of the hole forming member surrounding the air discharge hole mainly is provided in the pair of long edges so that the plurality of additional vortices are less likely to be generated on the edge sides of the pair of short edges than on the edge sides of the pair of long edges. Air ejector according to Claim 3 or 4th wherein the plurality of auxiliary holes are provided in the pair of long edges and are not provided in the pair of short edges. Air ejector according to Claim 1 or 2 wherein the vortex generating structure comprises a plurality of uneven portions (204) arranged by alternately arranging concave portions (206) and convex portions (208) along the peripheral edge portion of the hole formation member surrounding the air discharge hole to generate auxiliary vortices, which are different from the transverse vortices with respect to at least the vortex rotation direction and / or the vortex axial direction when an air flows through between the concave portion and the convex portion. Air ejector according to Claim 6 , wherein the peripheral edge portion of the hole formation member surrounding the air discharge hole has a first edge (102a) and a second edge (102b) which are opposite to each other and extend with a predetermined distance therebetween, a third edge which the one ends of the first edge and of the second edge and a fourth edge connecting the other ends of the first edge and the second edge, the first edge and the second edge establish a pair of long edges opposed to each other with a distance therebetween that is smaller as a distance between the third edge and the fourth edge, the third edge and the fourth edge establish a pair of short edges opposed to each other with a distance therebetween which is greater than the distance between the first edge and the second edge, and the plurality of uneven portions in the peripheral edge portion of the hole forming member surrounding the air discharge hole are mainly provided in the pair of long edges so that the plurality of auxiliary vortices are less likely to be on the edge sides of the pair of short edges than on the edge sides of the pair is created by long edges. Air ejector according to Claim 6 wherein the air discharge hole has a flat open shape, the peripheral edge portion of the hole forming member surrounding the air discharge hole includes a pair of long edges (102) opposed to each other in a short axial direction and a pair of short edges (104) to each other oppose in a long axial direction and are continuously connected to the pair of long edges, the short edge having a length smaller than a length of the long edge, the plurality of uneven portions in the peripheral edge portion of the hole forming member surrounding the air discharge hole, is mainly provided in the pair of long edges so that the plurality of additional vortices are less likely to be generated on the edge sides of the pair of short edges than on the edge sides of the pair of long edges. Air ejector according to Claim 7 or 8th wherein the plurality of uneven portions are provided in the pair of long edges and are not provided in the pair of short edges. Air ejection device according to one of the Claims 6 to 9 wherein the plurality of uneven portions are provided in a plate shape protruding into an interior of the air discharge hole. Air ejector according to Claim 10 wherein the plurality of uneven portions has a plate surface on a downstream air side disposed on the same surface as a surface of a downstream end of the peripheral edge portion of the air formation member surrounding the air discharge hole. Air ejection device, with: a duct (14) defining a flow passage (18) through which a flow of working air passes to be blown toward an ejection target (2); and a hole forming member (12) defining an air discharge hole (10) located on a downstream air side of the duct as an air outlet from which the working air flow is blown out, and a vortex generation structure (20) configured to generate an auxiliary vortex having a vortex characteristic including a vortex rotating direction and a vortex axis direction different from that of a transverse vortex generated by the working air flow on a downstream air side of the air discharge hole will, where the vortex generating structure comprises a plurality of vortex generating means arranged along a peripheral edge portion of the hole formation member surrounding the air discharge hole for generating the auxiliary vortex having a vortex characteristic different from at least one of the vortex rotating direction and / or a vortex axis direction of a transverse vortex when air flows around the vortex generating means. Air ejector according to Claim 12 wherein the plurality of vortex generating means is supported by a support portion (23, 24) in the air discharge hole so as not to directly contact the peripheral edge portion of the hole forming member defining the air discharge hole. Air ejector according to Claim 12 or 13th , wherein the peripheral edge portion of the hole formation member surrounding the air discharge hole has a first edge (102a) and a second edge (102b) which are opposite to each other and extend with a predetermined distance therebetween, a third edge which the one ends of the first edge and of the second edge, and a fourth edge connecting the other ends of the first edge and the second edge, the first edge and the second edge establish a pair of long edges opposed to each other with a distance therebetween which is less than a distance between the third edge and the fourth edge, the third edge and the fourth edge establish a pair of short edges facing each other with a distance therebetween which is greater than the distance between the first edge and the second edge, and the A plurality of swirl generating means in the peripheral edge portion of the hole forming member surrounding the air discharge hole, is primarily provided in the pair of long edges so that the plurality of additional vortices are less likely to be generated on the edge sides of the pair of short edges than on the edge sides of the pair of long edges. Air ejector according to Claim 14 wherein the plurality of vortex generating means is provided in the pair of long edges and is not provided in the pair of short edges. Air ejection device according to one of the Claims 12 to 15th wherein the plurality of vortex generating means are plate-shaped members having a thickness in an opening direction of the air discharge hole. Air ejector according to Claim 16 wherein the plurality of vortex generating means have plate surfaces on a downstream air side disposed on the same surface as a surface of a downstream end of the peripheral edge portion of the hole forming member surrounding the air discharge hole.

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