JPH0235165B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention provides a means for changing the flow state, and the means for changing the flow state also exerts a regulating force in the flow direction on the downstream side of the nozzle. The purpose is to improve the adhesion to the enlarged shape guide wall.

Another object of the present invention is to continuously control the deflection angle of the deflection device.

Further, the purpose is to configure the configuration in a form that is easier to create.

Furthermore, the purpose is to perform wide-angle deflection in the flow direction with a length shorter than the nozzle width.

Conventionally, this type of fluid flow deflection device does not exist.

The present invention includes a nozzle that emits a fluid flow;
Opposing guide walls are provided in a gradually expanding shape downstream of the nozzle, and rotatable about an axis are provided between the opposing guide walls to divide the fluid flow into each of the guide walls. It has a feather,
The upstream end of the guide wall is formed continuously with the nozzle without a step, and at least the downstream end of the blade is located downstream of the nozzle, and the flow emitted from the nozzle due to rotation is directed to the guide wall. The structure is such that it is placed at a position where it can adhere to the wall.

In the above configuration, by rotating the blades, the adhesion effect of one of the divided flows to each guide wall side is controlled, and the other flow is induced to merge with this, thereby wide-angle deflection control of the entire flow is performed. It is done.

Figures 2a, b, and c show a fluid flow deflection device in an embodiment of the present invention;
In b and c, 13 is a flow deflection device. 1
4 and 15 are walls. 16 and 17 are walls 14 and 15
It is a nozzle forming part that protrudes further inside the flow,
A nozzle portion 18 is formed that is narrowed with respect to the upstream flow path 23.

19 is a blade, which has an axis 20 perpendicular to the plane of the paper on the vertical center line passing through the center of the nozzle width;
0 is fixed to the blade 19, and the entire shaft 20 is configured to be rotatable. The vanes 19 are arranged from upstream to downstream of the nozzle portion 18 at the position shown in FIG. 2a.

Reference numerals 21 and 22 are guide walls having substantially arc shapes.

The deflection device is symmetrical with respect to the centerline of the nozzle section 18.

Next, the effect will be explained.

FIG. 1a shows the case where the blade 9 is aligned with the axis of symmetry. The flow velocity vectors at the nozzle exit are as indicated by arrows a ₁ and a ₂ , but since the entire flow is symmetrical, the direction of the entire outflow flow is in the direction of arrow A.

FIG. 1b shows the case where the blade 9 is rotated counterclockwise. In the flow between the nozzle forming part 8 and the blade 9, the outermost flow velocity is a ₃ , as shown by the arrow.
a ₄ , and the overall direction is in the direction of arrow B.
Further, in the flow between the nozzle forming part 7 and the blade 9, the outermost flow velocity is indicated by arrows _a5 and _a6 , and the flow as a whole heads in the C direction. The overall flow at the nozzle outlet is the direction in which the flows in the direction of arrow B and the flow in the direction of arrow C collide with each other. This direction is to the right of the direction indicated by arrow A, and the nozzle exit flow is directed to the right as a whole.

This flow produces a Coanda effect in the guide wall 11, and is deflected downstream of the nozzle.

However, in this example, since the entire blade 9 is located on the upstream side of the nozzle, the direction regulating force for the nozzle exit flow is weak and cannot greatly contribute to the deflection operation on the downstream side of the nozzle.

FIG. 2a shows a case where the blades 19 are aligned with the central axis of the nozzle 18.

At this time, the flow D passing between the blade 19 and the nozzle forming part 17 and the flow passing between the blade 19 and the nozzle forming part 16 are symmetrical with respect to the central axis of the nozzle 18. Therefore, a flow contraction effect occurs at the outlet ends of the nozzles 17 and 16, and although the flow velocities b ₁ and b ₂ are directed inward, they cancel each other out on the left and right sides, and the combined flow becomes a straight flow F.

In FIG. 2, FIG. 2b shows the case where the blade 19 is rotated a little more counterclockwise than in FIG. 2a.

At this time, since the blades 19 protrude downstream from the nozzle 18 , the flow D passing between the blades 19 and the nozzle forming part 17 is controlled by the blades 19 on the downstream side of the nozzle 18 . received greatly. In other words, the flow velocity at the outlet of the nozzle forming part 17
b ₄ is facing inward due to contraction, but the blade 19
The directional restriction of the flow velocity b ₃ along the direction acts strongly all the way to the downstream side of the nozzle. As a result, mainly the blade 19
The flow D directed by is attached to the guide wall by the Coanda effect. Thereafter, separation occurs at the position X in the figure, and thereafter it flows away approximately in the tangential direction of the guide wall at the position X.

On the other hand, the flow E passing between the blade 19 and the nozzle forming part 16 has a flow velocity b _{6 in a substantially straight direction on the side of the blade 19, but on the side of the nozzle forming part 16, the flow E has a flow velocity b 6} in the straight direction. Inward flow velocity for flow
b ₅ . In addition to the rightward deflection tendency due to the flow velocity _b5 , the mutual attraction effect that occurs between flows D and E causes flow E to be formed along flow D, and the combined flow becomes flow F heading to the right. .

FIG. 2c shows the case where the blade 19 is rotated further counterclockwise than in FIG. 2b.

At this time, the flow velocity b ₈ at the outlet of the nozzle forming portion 17 is directed inward due to contraction, but the direction regulation of the flow velocity b ₇ along the blades 19 is strongly exerted until it reaches the downstream side of the nozzle. Moreover, the direction is further increasing to the right than in FIG. 2b. Therefore, the flow D mainly directed by the vanes 19 is shown in FIG.
It heads toward the guide wall with a rightward deflection than at. Therefore, the Coanda effect works more effectively than in the case of FIG. 2b, and the separation point Y of the flow D is located downstream of the position X of FIG. 2b.

On the other hand, the flow E passing between the blade 19 and the nozzle forming part 16 is formed along the flow D due to the rightward deflection tendency due to the flow velocity b ₉ and the mutual attraction effect that occurs between the flows D and E. , the merged flow becomes a flow F further to the right than in FIG. 2b.

Experiments have revealed that when obtaining a deflection angle θ of about 60°, the total length L can be achieved with a dimension that is three times or less the nozzle width Ws.

Further, in the rotation of the blade 19 to the positions a, b, and c in FIG. 2, the position of the separation point changes continuously because the shape of the guide wall is formed in an arc shape. That is, the direction of the flow away from the tangential direction of the separation point can be continuously controlled.

In this example, the deflection operation has been explained using an example of a nozzle with an aperture, but when the regulating force by the blades is large or the adhesion effect to the guide wall is strong, that is, when the blades are placed further downstream. When the guide wall has a larger radius of curvature, the nozzle does not necessarily need to be constricted.

In the above embodiments, the deflection on one side has been described, but the same effect can be achieved on the deflection on the opposite side.

Furthermore, the shape of the deflection device does not necessarily have to be symmetrical about the nozzle center line.

This deflection device can operate even if the fluid is air, water, etc., if the surrounding fluid and the fluid passing through the deflection device are of the same quality.

As is clear from the description of the embodiments above, according to the fluid flow deflection device of the present invention, the blades for controlling flow deflection are arranged such that at least their downstream ends are located downstream of the nozzle. The regulating force for the flow coming out of the nozzle is further downstream and the flow deflection angle can be expanded by the attraction effect of the attached flow, and the deflection angle can be continuously controlled.

Furthermore, since the upstream end of the guide wall is formed continuously with the nozzle, it is easy to manufacture.

Furthermore, since the device is formed with a length that is three times or less the nozzle width in the flow direction, it can also be used in a small depth range.

As a result, a deflection device with further increased industrial utility value can be obtained.

[Brief explanation of drawings]

Figures 1a and b are cross-sectional views of the fluid flow deflection device before improvement in different states, and Figures 2a, b, and c are sectional views of the fluid flow deflection device in different states according to an embodiment of the present invention. The sectional view and FIG. 3 are perspective views. 13...Flow deflection device (fluid flow deflection device), 1
8... Nozzle part (nozzle), 19... Vane, 21,
22...Guidance wall.

Claims (1)

[Scope of Claims] 1. One nozzle that emits a fluid flow, opposing guide walls provided in a gradually expanding shape downstream of this nozzle, and rotation about an axis between the opposing guide walls. a blade that is freely provided and divides the flow of fluid into each of the guide walls, the upstream end of the guide wall is formed continuously with the nozzle without a step, and the blade is at least connected to the downstream end of the guide wall. is located on the downstream side of the nozzle, and is arranged at a position such that the flow emitted from the nozzle due to rotation can cause an adhesion action to the guide wall. 2. The fluid flow deflecting device according to claim 1, wherein the total length of the fluid flow changing device in the flow direction is three times or less the nozzle width.