WO2018105429A1 - Acceleration duct - Google Patents

Abstract

The present invention provides an acceleration duct to be disposed on the front of a rotor blade and having a shape in which the front portion of a bottom plate of a cylindrical section located in the rear is extended and formed into a gutter-like shape having a wide tip width to collect and accelerate a small amount of water. A front portion of a bottom plate (3) of a cylindrical section (2) located in the rear of a duct (1) is extended into a flat shape the width of which gradually increases toward the front, and sidewalls (4), (5) are disposed upright on the sides while the top is left open, thereby displacing and raising water coming in from the front before allowing the water to pass into the cylindrical section (2).

Description

Acceleration duct

The present invention relates to an acceleration duct that is disposed at a front portion of a rotor in a hydroelectric generator so that a water flow in a water channel can be accelerated and applied to a rotor blade.

For example, Patent Document 1 discloses that a duct is disposed at a front portion of a water turbine rotor.

JP 2010-112194 A

In the invention described in Patent Document 1, a turbine rotor is disposed inside a long duct, and the front end of the duct has a trumpet tubular shape with a large diameter. However, even if the front end has a large diameter, the amount of water passing therethrough Will never become large, nor will it be accelerated.
The present invention provides an acceleration duct in which the width of the front portion of the duct is increased, the water flow is made closer to the side wall, and the water flow is accelerated and sent at the rear portion of the duct.

The present invention has taken the following technical means in order to solve the above-mentioned problems.

(1) An accelerating duct in which the front part of the bottom plate of the cylindrical part at the rear part is stretched to have a flattened shape that gradually becomes wider, the side wall is erected on the side part, and the upper part is opened.

(2) The acceleration duct according to (1), wherein the width of the front end portion of the bottom plate is larger than the width of the cylindrical portion.

(3) The acceleration duct according to (1) or (2), wherein one side of the side end portion of the bottom plate is parallel to the cylindrical portion, and the other side is projected outward toward the tip.

(4) The acceleration duct according to (1) or (2), wherein the side end portions of the bottom plate are formed symmetrically.

(5) In the case where the tip end portion of the side wall protrudes outward from the outer surface of the cylindrical portion, the middle portion of the inner side surface is curved inwardly bulging, and the height of the tip end portion is increased. The acceleration duct according to any one of (1) to (4), wherein the height is set higher than the height of the cylindrical portion.

(6) When the upper end portion of the side wall is higher than the height of the cylindrical portion, the lid portion is formed in a bowl shape from the front end portion of the side wall to the central portion of the front end of the cylindrical portion. The acceleration duct according to any one of (1) to (5).

(7) The acceleration duct according to any one of (1) to (6), wherein an elastic water guide plate that is inclined forward and downward is disposed at a front end portion of the bottom plate.

(8) The acceleration duct according to any one of (1) to (7), wherein an outward flange for connecting to another tubular body is formed on a peripheral surface of a rear end portion of the cylindrical portion. .

(9) The acceleration duct according to any one of (1) to (8), wherein the cylindrical portion and a bottom plate portion continuous therewith are divided into left and right parts so as to be connectable.

(10) The acceleration duct according to any one of (1) to (9), wherein the side plate is formed of an elastic material.

According to the present invention, the following effects can be obtained.

In the invention described in the above (1), the bottom plate front portion of the cylindrical portion is gradually widened forward, and a side wall is erected on the side end portion thereof. The water flow entering from the front of the wide bottom plate is gradually brought closer by the side wall to reach the cylindrical portion.
Even if the water depth is shallow at half the height of the cylindrical part, if the width of the front part of the bottom plate is, for example, twice the width of the cylindrical part, the water flow entering the cylindrical part becomes full, and Since it is pressurized, it is accelerated more than the flow velocity of the water channel.
When the cylindrical part is long, the frictional resistance with the inner peripheral surface of the cylindrical part becomes large, but the length of the cylindrical part is short, so that it passes in a short time and is arranged at the rear part of the duct. An equal water pressure can be applied to the rotor blade.

In the invention described in (2) above, the width of the front end portion of the bottom plate is larger than the width of the cylindrical portion, for example, more than 1.5 times, and thus, for example, 1.5 times the flow rate in the water channel. An amount of water flow can be directed to the tube.

In the invention described in (3) above, one side end of the bottom plate is parallel to the cylindrical part, and the other side projects outwardly toward the tip, so the side part parallel to the cylindrical part is For example, if the water flow is disposed close to the side wall of the water channel, the water flow can be gathered from the front end on the other side to collect the water flow in the tubular portion.

In the invention described in (4), since the side end portions of the bottom plate are formed symmetrically, water can be gathered to the central portion of the rear portion of the duct along the left and right side walls.

In the invention described in (5) above, when the tip portion of the side wall protrudes outward from the outer surface of the cylindrical portion, the intermediate portion of the inner side surface is curved inwardly bulging, And since the height of the front-end | tip part is set higher than the height of a cylindrical part, speeding up by the Coanda effect can be made to pass through a cylindrical part, raising the water flow along the inner surface of a side wall.

In the invention described in (6) above, when the upper end of the side wall is higher than the height of the tubular part, the roof wall extends from the end part of the side wall to the central part of the end of the tubular part. Since the cover portion is formed in a shape, the water flow passing along the inner surface of the side wall descends inward and downstream along the cover portion and passes to the cylindrical portion.

In the invention described in (7) above, since the soft water guide plate that inclines forward and downward is disposed at the tip of the bottom plate, the tip of the water guide plate is brought into close contact with the bottom surface of the water channel by water pressure. In addition, the bottom layer flow can be guided into the duct.

In the invention described in (8), since the outward flange is formed on the peripheral surface of the rear end portion of the cylindrical portion, it is possible to connect a hydroelectric power generation unit or the like to the rear portion by flange coupling. it can.

In the invention described in (9), since the cylindrical portion and the bottom plate portion continuous with the cylindrical portion are divided into left and right parts so as to be connectable, even a large size is easy to manufacture, and on site Since it can be assembled, it is excellent in transportation and workability.

In the invention described in (10), since the side plate is made of an elastic material, when installed in a water channel, it is not easily damaged even if it collides with a side wall or a large falling material collides. .
Moreover, since it has elasticity, it adheres to a side wall surface, water leakage does not arise, and the fall of the water pressure concerning a duct can be suppressed.

It is a top view which shows one Embodiment of the acceleration duct of this invention. It is the II-II line vertical side view in FIG. It is a front view in FIG. FIG. 2 is a rear view in FIG. 1. It is a side view which shows the use condition of the acceleration duct of this invention. It is a top view which shows other embodiment of the acceleration duct of this invention. FIG. 7 is a longitudinal sectional side view taken along line VII-VII in FIG. 6. It is a front view in FIG. FIG. 7 is a rear view in FIG. 6.

An embodiment of the present invention will be described with reference to the drawings.
In FIG. 1, an acceleration duct 1 has a front portion of a bottom plate 3 of a cylindrical portion 2 that extends forward in plan view, and projects rightward in a right view in FIG. Yes.

In FIG. 1, the left side surface when viewed from the right side is linear with the cylindrical portion 2. Side walls 4 and 5 are erected on left and right ends of the bottom plate 3, respectively.
The right side wall 4 rises gradually from the front end of the cylindrical portion 2 to the front end of the side wall 4, and its upper surface is a curved surface.
The left side wall 5 is substantially the same height as the cylindrical portion 2 and has a straight shape. Thus, the left side wall 5 is brought into contact with the side wall of the water channel and is fixed by a rope or the like.

From the upper surface of each side wall 4, 5, the inwardly hooked lid parts 6, 7 have a constant width and extend from the front end to the front end of the cylindrical part 2, and the side walls 4, 5 and the lid part The boundary with 6 and 7 is an arc curved surface.

Therefore, the water flow that competes along the side walls 4 and 5 smoothly passes downstream along the lower surfaces of the covered portions 6 and 7. By making the material of the side plates 4 and 5 elastic, there is no possibility of damage even if the duct 1 collides with the side wall or the falling material collides when the duct 1 is disposed in the water channel R.

The left and right support legs 8, 8 are arranged on the front surface of the bottom surface of the bottom plate 3 so that the height can be adjusted. A water guide plate 9 that is inclined downward is disposed at the front end of the bottom plate 3 so that the front portion is in contact with the bottom of the water channel R. The water guide plate 9 is made of an elastic material such as synthetic rubber so that the lower surface of the front end can be in close contact with the bottom of the water channel.

FIG. 5 is a side view showing a state where the acceleration duct 1 is used in a water channel.
As shown in FIG. 5, an outward flange 10 is formed on the rear end peripheral surface of the cylindrical portion 2 of the acceleration duct 1. As shown in FIG. 5, the outward flange 10 is connected to the outward flange 13 of the support ring 12 of the hydroelectric power generation unit 11.

In the hydroelectric power generation unit 11, a suspension pipe 14 that protrudes from the upper portion of the support ring 12 is suspended from a suspension frame 15 that is installed between both banks of the water channel R. The upper end of the suspension pipe 14 is connected to the generator 16. It is connected to. A bearing housing 17 is fixed to the lower end portion of the suspension tube 14.
A rotor 18 is fixed to the tip of the rotor shaft that is horizontally supported by the bearing housing 17. The rotor shaft is connected to the generator 16 via a transmission shaft (not shown) in the suspension pipe 14.

In FIG. 5, the rearward outward flange 13 </ b> A of the support ring 12 is connected to the frontward outward flange 20 of the drainage duct 19 connected to the rear part.
The drainage duct 19 has a larger diameter at the rear port 19A than at the front port 19B. Thereby, the portion of the rotor 18 becomes a bottleneck, and the rotational efficiency of the rotor 18 is enhanced.

In FIG. 5, even when the water level W of the water channel R is low, the water flow guided from the water guide plate 9 to the front portion of the bottom plate 3 of the acceleration duct 1 is shifted toward the center by the side wall 4 as shown in FIG. Be made.
Since the middle part of the inner side surface of the side wall 4 bulges inward, the flow rate of water passing along the inner side surface of the side wall 4 is increased by the Coanda effect.

The water flow brought to the center of the bottom plate 3 advances to the cylindrical part 2 while raising the water level, passes through the cylinder part 2 in full, and applies a uniform water pressure to the rotor 18 immediately after it to rotate it. Let Just before the tubular portion 2, excess water overflows and passes over the upper surface of the tubular portion 2.

In the drainage duct 19, the rear opening 19 </ b> A is formed larger than the front opening 19 </ b> B, so that the inside of the support ring 12 in which the rotor 18 is accommodated becomes a bottleneck, and the passage speed of the water flow becomes high.

Further, since the drain duct 19 has a large rear opening 19A, the rear portion of the drain duct 19 has a negative pressure rather than the water pressure applied to the inside of the support ring 12, and the front water flow becomes a high-speed flow due to the difference in water pressure. And the rotational efficiency of the rotor 18 can be increased.

Further, the bottom surface of the irrigation channel R has a slope, and the acceleration duct 1 has the front portion lifted higher by the support column 8, so that the water flow passing through the inside is subjected to gravity and the flow velocity is faster than the water flow in the water channel R. Become.

FIG. 6 is a plan view showing another embodiment of the acceleration duct. The same members as those of the previous example are denoted by the same reference numerals and description thereof is omitted.
In FIG. 6, the acceleration duct 1 is divided into two parts from the center of the width in plan view, and the right and left coupling parts 1 </ b> C and 1 </ b> C are joined together by bolts 1 </ b> D.

The left and right side walls 4 and 5 of the acceleration duct 1 are formed symmetrically. Thereby, a large-sized duct can also be easily manufactured with a metal mold. Moreover, since it can be transported to the site and assembled on site, it is excellent in transportation and workability.
In addition, lifting is suppressed by fixing a weight to the lower surface of the front part of a baseplate so that attachment or detachment is possible.

Since a large amount of water flow can be collected, it can be effectively used for a hydroelectric power generation device in a waterway with a low water level.

1. Acceleration duct 2. 2. Cylindrical part Bottom plate 4,5. Side walls 6,7. Covered portion 8. Support legs 9. Water guide plate 10. Outward flange 11. Hydroelectric power generation unit 12. Support ring 13, 13A. Outward flange 14. Hanging tube 15. Hanging frame 16. Generator 17. Shaft support housing 18. Rotor 19. Exhaust duct 19B. Front entrance 19A. Rear mouth 20. Outward flange Waterway W ... water surface

Claims (10)

Accelerating duct characterized in that the bottom plate front part of the cylindrical part at the rear part is extended in a flat shape that gradually becomes wider forward, a side wall is erected on the side end part, and the upper part is opened. 2. The acceleration duct according to claim 1, wherein the width of the front end portion of the bottom plate is larger than the width of the cylindrical portion. The acceleration duct according to claim 1 or 2, wherein one side end portion of the bottom plate is parallel to the cylindrical portion, and the other side protrudes outward from the tip end. The acceleration duct according to claim 1 or 2, wherein the side edges of the bottom plate are formed symmetrically. In the case where the tip of the side wall protrudes outward from the outer surface of the cylindrical part, the middle part of the inner side is curved so as to bulge inward, and the height of the tip part is the height of the cylindrical part. The acceleration duct according to any one of claims 1 to 4, wherein the acceleration duct is set higher than a height. Where the top end of the side wall is higher than the height of the cylindrical part, a bowl-shaped lid is formed from the front end part of the side wall to the center part of the front end of the cylindrical part. The acceleration duct according to any one of claims 1 to 5. The acceleration duct according to any one of claims 1 to 6, wherein a resilient water guide plate that is inclined forward and downward is disposed at a tip portion of the bottom plate. The acceleration duct according to any one of claims 1 to 7, wherein an outward flange for coupling with another tubular body is formed on a peripheral surface of a rear end portion of the cylindrical portion. The acceleration duct according to any one of claims 1 to 8, wherein the cylindrical portion and the bottom plate portion continuing to the cylindrical portion are divided into left and right parts so as to be connectable. The acceleration duct according to any one of claims 1 to 9, wherein the side plate is made of an elastic material.

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