JPS59190482A - Device for generating motive power by twin windmill - Google Patents

Abstract

PURPOSE:To make a whole device compact and obtain a high output, by mounting two vertical windmills with spaces around windmill shafts and interlaying the vanes of the windmills between each other not to interfere with each other. CONSTITUTION:Two windmills 1, 1a, each of which has three vanes 3 or 3a at regular intervals, are mounted with spaces 4, 4a around windmill shafts 2, 2a. The vanes of one windmill are interposed between those of the other. As a result, a whole device is made compact and a high output is obtained. Driving bevel gears 6, 6a are mounted near the lower ends of the windmill shafts 2, 2a. Driven bevel gears 9, 9a, which are engaged with the driving gears 6, 6a are mounted on a single horizontal shaft 7 so that the windmills 1, 1a are smoothly rotated together at the same speed in the opposite directions as their vanes 3, 3a do not interfere with each other.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a dual wind turbine power generation device in which two wind turbines are synchronized and rotated in opposite directions.

Power generation devices that utilize wind power have recently attracted attention as an energy source.

Regarding small devices that use wind power to generate power, we are trying to efficiently utilize the ever-changing wind power to generate large amounts of power with small devices. be.

In other words, in a wind turbine power generation device equipped with a directional stabilizing plate that automatically rotates in the direction of the wind, two wind turbines are installed with three blades arranged at equal intervals and a space provided around the wind turbine shaft. vertically vM, the blades are arranged in a tangled manner so as not to interfere with each other, driving bevel gears are attached near the lower ends of the wind turbine shafts of the two wind turbines, and passive bevel gears meshing with the driving bevel gears are installed. By attaching them to one horizontal shaft, the two windmills are made to operate in opposite directions at the same rotational speed.

A detailed explanation will be given below based on the attached drawings illustrating embodiments.

(1) (la) is a windmill, and the distance between the windmill shafts (2) (2a) increases toward the top. It is installed at an angle, and the blades (3) (3a) are expanded upward to make the area where the wind is received as wide as possible.

Three of these blades (3) (3a) are attached to one windmill shaft at equal intervals, and there are spaces (4) (4) around the windmill shaft.
a) is provided to reduce the back pressure of the blades, and furthermore, the tips of the blades (3) (3a) are slightly bent portions (3) (to 3) where the two windmills are in opposite directions to each other, Try not to let the wind escape as much as possible.

The two windmills (1) (la) configured in this way are arranged so that the blades (3) (3a) are entwined with the bladeless part of the other windmill so as not to interfere with the rotation, and the windmill shaft (2) is (2a
) as close as possible.

(5) is a gear room that supports the lower part of the wind turbine shaft (2) (2a), and a driving bevel gear (6) (6a) is attached near the lower end of the wind turbine shaft.

(7) is the horizontal axis, and the bearing (8) (8&
), and a driving bevel gear (6) (
A passive bevel gear (9) (9&) is attached which meshes with 6a).

QO (11) are transmission bevel gears that mesh with each other, one transmission bevel gear Q0 is attached to the horizontal shaft (7), and the other transmission bevel gear aη is attached to the upper end of the vertical axis θ.
The rotation of the horizontal axis (7) is transmitted to the vertical axis (a).

θ→ is a driving pulley, which is attached to the lower end of the vertical axis a.

θΦ is a passive V pulley, which is fitted to the shaft end of the generator αQ attached to the machine frame O, and rotates the generator (IQ) by the V belt (17) from the driving V pulley 03.

θ~ is a direction stabilizing plate, which is integrally formed with the gear chamber by an arm θ0 extending from the gear chamber (5), and this gear chamber (5) is rotatably supported by the machine frame aG, and has two Windmill (1) (
1a) acts so that the plane containing the center of the wind turbine shaft (2) (2a) is always perpendicular to the direction of the wind, as shown in FIG.

The wire is the storage battery, and Qυ is the generator controller.

This idea consists of the above configuration, and as shown in Figure 3,
When the wind blows in the direction of the many arrows shown parallel to the left,
Due to the direction stabilizing plate 0 barrel, the windmill (1) (la) is positioned so that the two windmills (1) (la) are parallel to each other in the direction of the wind, and the windmill (1) (la) is positioned at the tip of the blade (3) (3a). They rotate in opposite directions as shown by the arrows.

This windmill (1) (1a) has blades (3) (3a) that are intertwined with each other, so if they are not synchronized at the same rotation speed,
Since the blades will interfere with each other, by rotating them in synch, the rotational force of the two windmills (1) and (la) will be concentrated on one horizontal axis (7), and the rotational force will be rotated along the vertical axis α. The transmission device is a gear chamber (5), and driving bevel gears (6) (6a) with the same number of teeth are attached to the wind turbine shaft (2) (2a), and are attached to both ends of the horizontal shaft (7). This is also a passive bevel gear with the same number of teeth (9)
(9a), the windmills (1) and (la) rotate in opposite directions, so the horizontal shaft (7) rotates in a fixed direction, and the driven bevel gear (6) and passive bevel gear (
9) and the tooth ratio of the driving bevel gear (6a) and the passive bevel gear (9a) are the same, so the windmills (1) (la) have no choice but to rotate synchronously no matter how they receive the wind. Therefore, smooth rotation can be obtained without interference between the blades (3) and (3a).

In this way, the rotational force that causes the wind turbine (1,) (la) to rotate in response to wind energy is concentrated on the horizontal axis (7), transmitted to the vertical axis Q by the transmission bevel gear OOθ1), and is transmitted to the vertical axis Q (6).
) to the driving V-pulley Q3. The V-belt α force passes through the passive V-pulley Q → to the generator (turn 10 to generate electricity, and the storage battery -
It can be used for floating charging and used for various loads.

The basis of this idea is two windmills (1) consisting of three blades (
The blades (3) (3a) are intertwined with each other to prevent interference while rotating in synchrony and in reverse, and the wind pressure applied to each of the three blades is always unbalanced, causing rotational force. The reason lies in the adoption of a new type of reaction-type windmill.

The two windmills (1) (la) have their blades (2) (2a) tilted so that their upper ends expand outward.
3) The purpose is to expand (3a) upward to increase the wind pressure area.

Furthermore, by creating a space (4) (4a) around the wind turbine shaft (2) (2a), the blades (3) (3a) reduce the back pressure generated by the rotation of the blade by escaping this space, thereby reducing rotational resistance. Since this space is provided close to the center of rotation, the blade (3) (
Even if the area of 3a) decreases, the decrease in rotational force is small, and the effect of reducing the resistance of the back pressure received by the blades (3) (3a) is greater than the negative effect on the output range, so if you subtract it, This is a plus.

Since the windmills (1) and (la) are configured such that the blades (3) and (3a) are interwoven between the blades of the other windmills, the entire device can be miniaturized and a large output can be obtained.

In addition, the tips of the upper blades (3) (3a) are attached to two windmills (1
) (1 &) are bent at an appropriate angle so that they are in opposite directions to effectively catch the wind and increase the rotational force.

This dual wind turbine power generator starts easily even in low speed winds, and does not rapidly increase rotation even in high speed winds.
A windmill is a type of windmill that can provide almost constant and stable rotation.
The rotation ratio between la) and the generator θQ is preferably 1:10 or more. Also, when the generated voltage becomes unstable, the generator controller ■υ works to automatically control and maintain a constant voltage.

To inspect the inside of the gear room (5), choose a windless day, and then remove the windmill (1).
(1a) is stopped and the top inspection window (A) and side inspection window (C) are opened for inspection and maintenance.

This dual wind turbine power generator is mainly used for power generation in small businesses, such as power supply for remote islands, power supply for mountaintop radio stations, power supply for lighting on the roof of buildings, power supply for heating in cold regions with severe seasonal winds, power supply for agricultural use, It can be used for home heating, lighting power, and other purposes, but it can also be used for pumping water by directly utilizing the rotation of the vertical axis.

Although the top view shows the wind turbine shaft (2) (2a) inclined, it is of course possible to make it vertical.

As described above, the present invention provides a dual wind turbine power generation device that is compact, can provide a relatively large output, has a simple structure, can be manufactured at low cost, can be used for many purposes, and is highly efficient. It's something you get.

[Brief explanation of drawings]

The attached drawings show one embodiment of the present invention, and FIG. 1 is a partially cutaway front view, FIG. 2 is a side view of FIG. 1 as seen in the direction of arrow A, and FIG. 3 is a plan view. be. 1.1a...Windmill 2,2a...Windmill shaft 3.3a
...Blades 4, 4a...Space 5...Gear room
6, 6a... Drive bevel gear 7... Horizontal shaft 8, 8a
... Bearing 9.9 & ... Passive bevel gear

Claims (1)

[Claims] In a wind turbine power generation device equipped with a directional stabilizing plate that automatically rotates in the direction of the wind, two wind turbines with three blades arranged at equal intervals and mounted with a space around the wind turbine axis are installed vertically. The blades are arranged so that they do not interfere with each other, and the driving bevel gears are installed near the lower ends of the wind turbine shafts of the two windmills, and one passive bevel gear is meshed with the driving bevel gear. 1. A dual wind turbine power generation device, characterized in that the two wind turbines are connected to the horizontal axis of the wind turbine so that the two wind turbines operate in opposite directions at the same rotational speed.