JPH07111169B2 - Hydroelectric generator - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a hydroelectric power generation device that can be put in a water stream and has a small and simple structure.

(Prior Art) In a small-sized and simply-configured hydroelectric power generator that is arranged in a water stream and transmits the rotational force of a hydroelectric blade that rotates by receiving hydraulic power to a rotor of a generator, the hydroelectric blade has conventionally been fixed. It is generally known that the shaft is directly connected to the rotor of the generator.

However, in such a structure, when the flow velocity is low, the rotation speed of the water turbine blade, that is, the rotation speed of the rotor of the generator is inevitably small, and it is difficult to obtain sufficient electric power with the normally used generator. become.

Therefore, in order to increase the electric power that can be acquired, it is necessary to appropriately increase the speed of the rotation of the water turbine blade using the speed increasing transmission mechanism and transmit the rotation to the rollers of the generator. here,
For the widest possible flow rate, from low to high
In order to efficiently generate electric power using the same generator, it is necessary to appropriately select a turbine blade having a diameter and an area corresponding to the flow velocity thereof, and the speed increasing transmission mechanism corresponding to the turbine blade It is necessary to replace with an appropriate speed increasing ratio.

Further, the speed increasing transmission mechanism will be provided between the respective shafts of the turbine blade and the generator rotor, but when the speed increasing transmission mechanism is changed to a different speed increasing ratio,
If the structure in which the mounting position of the generator has to be moved according to it is inconvenient in handling, it is necessary to take measures to avoid such trouble.

Under such circumstances, it is desired to use the same generator without changing the generator or moving the mounting position, and by which the speed increasing transmission mechanism other than the turbine blade can be easily selectively replaced. It was

(Object of the invention) The present invention meets the above-mentioned demand, and by appropriately selecting a transmission mechanism having an appropriate speed increasing ratio and using the same generator for a wide range of flow velocities, it is possible to increase the efficiency as efficiently as possible. An object of the present invention is to provide a hydroelectric power generation device that can obtain electric power and can easily replace the mechanism without changing or moving the generator when replacing the speed increasing transmission mechanism. .

(Structure of the Invention) According to the present invention, a shaft equipped with water turbine blades at both ends is rotatably supported by the housing in a state of penetrating the housing, and an axial rotational force of the shaft causes a speed increasing transmission mechanism in the housing. In a hydroelectric power generation device configured to be transmitted to a rotor of a generator via a drive-side pulley connected to the shaft, a driven pulley connected to the rotor, and the like as the speed-up transmission mechanism. A belt connecting the driving pulley and the driven pulley is arranged side by side in a direction orthogonal to the shirt, while the housing is composed of a first case member and a second case member which are mutually separable in the shaft penetrating direction. The stator of the generator is fixed to the inside of the first case member to dispose the entire generator from the center of the driving pulley and the driven pulley. The first case member is offset, and at least one of the turbine blades is detachably attached to the shaft.

According to such a configuration, by exchanging the water turbine blade and the speed increasing transmission mechanism according to the flow velocity, it is possible to efficiently generate power using the same generator, and moreover, the operation of the speed increasing transmission mechanism is performed. The exchange can be easily performed by moving in the following order without moving the generator.

Remove either the left or right turbine blade from the shaft.

The case member on the side where the water turbine blade is removed is separated from the other case member in the longitudinal direction of the shaft.

Only the speed increasing transmission mechanism is replaced with the generator left on the first case member side.

Reconnect the case members to each other and reattach the turbine blade to the shaft.

(Embodiment) First to first configurations of a hydraulic power plant W according to an embodiment of the present invention are given.
This will be described with reference to FIG.

A shaft 5 is provided so as to project through both sides of a bearing portion of a housing 1 equipped with a generator G, and a turbine blade 9 is attached to a pipe shaft 6 connected to the shaft 5. When the water turbine blade 9 is arranged in the water flow, it receives a hydraulic force and converts it into an axial rotational force of the shafts 5 and 6, and a transmission mechanism, which will be described later, provided in the housing 1 to convert the axial rotational force. The electric power is transmitted to the rotor 20 of the generator G via the generator G to generate electric power.

The details of each part of the above basic configuration will be described. The housing 1
Comprises a first case member 1a and a second case member 1b,
The flange members 2, 2 are fixed to the bearing portion. The flange member 2 has a through hole 2a formed therein, and at the same time, a bearing 3 and an oil seal 4 are internally provided to support the shaft 5. A seal member such as an O-ring is provided between the first case member 1a and the second case member 1b to prevent water from entering the housing 1.

Pipe shafts 6, 6 are fitted in the portions where the shaft 5 projects from both sides of the housing 1, and are fixed by hose bands 7, 7. The pipe shaft 6 is provided with a slit so as not to rotate with respect to the shaft 5. Around this pipe shaft 6, a water turbine blade 9 composed of a plurality of blades 8 (in the embodiment, 8 blades) is provided, and it is detachably attached by cones 10 and 10 as follows. That is, the cone 10 on the housing 1 side is
The cap portion 10a is fixed to the pipe shaft 6 by a hose band 11, while the cone 10 on the outer end side of the pipe shaft 6 has a housing 10 with a washer 13 by tightening the cap portion 10a with a bolt 12. I try to push it to the 1 side. When the blade 9 is sandwiched by the cones 10 and 10 from both sides in this way, friction acts between the inclined surface 9a of the blade 9 and the inclined surface 1b of the cone, and the blade 9 can be fixed to the pipe shaft 6. it can. Also, the blade 8 when fixed
In order to prevent rattling, the inner diameter of the base of the blade 8 is formed in an arcuate shape in the axial direction so that a gap a is formed between the blade 8 and the pipe shaft 6.

Further, in the housing 1, the central portion 5a of the shaft 5
A toothed pulley (drive pulley) 15 is attached to the housing 1 using a key 14, and the housing 1 is separated from the shaft 5.
The rotor shaft 16 is supported therein by bearings 17, 17. The rotor shaft 16 is provided with a toothed pulley (driven pulley) 18 by using a key 19 so as to coincide with a center (Y-Y line in FIG. 1) orthogonal to the axial direction of the pulley 15. In addition to being fixed, the rotor 20 of the generator G is fixed to the side surface of the toothed pulley 18. Further, a toothed belt 21 is stretched between the pulley 18 and the pulley 15, and the two are connected by the belt 21.
The rotational force of 15 is transmitted to the pulley 18.
Then, the toothed pulleys 15 and 18 and the belt 21 constitute a speed-up transmission mechanism.

Further, a ferrite magnet 22 is fixed to the outer circumference of the rotor 20 to form a multi-pole rotor. Further, a stator 23 in which a coil is wound around an iron core of ferrite is fixed in the first case member 1a so as to be located around the ferrite magnet 22. Are configured. Therefore, in this hydraulic power generation device W, the generator G is mounted offset from the center of the pulleys 15 and 18 (line YY in FIG. 1) in the axial direction.

Next, as a structure for arranging the rotor W of the generator having the above structure in the water flow, one end of the tubular main shaft 24 is fixed to the end of the housing 1 and the retaining pin 30 is penetrated. ing. A hydrofoil mounting ring 27, to which a hydrofoil 26 is connected via an arm 24, penetrates through the main shaft 24, and both are fixed in this state. This hydrofoil 26
Is composed of two blades 26a and 26b and has a V-shaped cross section. One wing 26a is horizontal and the other wing 26b is substantially parallel to the vertical, and is positioned below the water surface (U-U line in FIG. 2) when in use.

As shown in FIG. 1 (b), a connector 28 is connected to the stator 23, and a cord 29 is extended from this connector 28 to send the output from the stator 23 to the outside.

Next, the operation state of this embodiment will be described with reference to FIG. In FIG. 7, the river R is flowing in the direction of arrow A, and the hydroelectric generator W configured as described above is floated on this river R, and at the same time, it is connected to the shore S by the wire 29 'accompanied by the code 29. I'm out. At this time, since the hydrofoil 26 floats in the flow of the river R, lift Lu that tries to float the hydroelectric generator W upward and Ls that tries to pull it toward the offshore where the flow velocity is high work, and the hydroelectric generator W is always It is kept so that it floats in the center of the river, that is, at a position where the flow velocity is high.

In this state, the blade 9 rotates under the water flow of the river R,
At this time, the inclined surface 9a of the blade 9 and the inclined surface of the cone 10
This rotational force is transmitted by the friction between 10b, and rotates together with the pipe shaft 6 and the shaft 5 blade 9. Then, this shaft rotational force is transferred from the pulley 15 to the belt 21.
It is transmitted to the pulley 18 and the shaft 16 via, and the rotor 20 rotated by this pulley 18 is rotated. This causes the generator G to generate power.

By the way, the case where the blade 9 is replaced according to the flow velocity of water will be described. In order to efficiently obtain electric power using the same generator G for a wide range of flow velocities, it is necessary to appropriately select a blade having a diameter and an area corresponding thereto. For example, when the flow velocity is high, the blade is replaced with a blade having a smaller diameter and smaller area than the blade 9 (shown by a double-dotted chain line in FIGS. 2 and 3). At the same time as this replacement, it is necessary to replace the pulleys 15 and 18 of the speed increasing transmission mechanism so that the speed increasing ratio corresponding to the selected blade is given in order to give a suitable rotation speed to the generator G. There is. At this time, since the generator G is attached offset from the center of the pulleys 15 and 18 and the belt 21 in one axial direction as described above, the generator G can be easily moved without moving. It can be replaced. Specifically, the speed increasing transmission mechanism can be replaced in the following order.

Either the left or right turbine blade 9 is removed from the shaft 5.

The case member on the side where the water turbine blade is removed (for example, when the water turbine blade 9 on the right side is removed, the second case member 1
b) is separated from the other case member (the first case member 1a when the right turbine blade 9 is removed) in the longitudinal direction of the shaft 5.

Only the speed increasing transmission mechanism is replaced with the generator G left on the first case member 1a side.

After the replacement, the case members 1a and 1b are connected to each other again, and the turbine blade 9 is attached to the shaft 5 again.

(Effects of the Invention) As described above, the present invention accelerates the rotation of the turbine blade and transmits it to the rotor of the generator, and replaces the blade according to the flow velocity, and at the same time, increases the speedup ratio suitable for it. By selecting and replacing the speed-increasing transmission mechanism, it is possible to efficiently obtain electric power using the same generator for the widest possible flow velocity. Moreover, the above housing is the first
A case member and a second case member are separable, the stator of the generator is fixed to the side of the first case member, and the disposition position of the entire generator is set from the center of the drive pulley and the specific drive pulley to the first case member. Offset, and at least the water turbine blade on the side closer to the second case member of the water turbine blades is configured to be attachable to and detachable from the shaft, so that it takes time and effort to change or move the generator. It is possible to easily and appropriately replace the speed-increasing electric body mechanism without having to do so, and the exchanging operability is excellent.

[Brief description of drawings]

FIG. 1 (a) is a sectional view taken along the line I-I of FIG. 4 showing the essential structure of a hydroelectric power generator according to an embodiment of the present invention, and FIG. 1 (b).
Is a cross-sectional view showing the vicinity of the connector of the device, FIG. 2 is a side view of the device, FIG. 3 is a plan view of the device, FIG. 4 is a front view of the device, and FIG. 5 is a turbine blade of the device. 6 is a cross-sectional view corresponding to the line VV in FIG. 6, and FIG.
VI-VI sectional view, FIG. 7 is a perspective view showing a usage state of the same apparatus. G ... Generator, W ... Hydroelectric generator, 1 ... Housing, 1a ... First case member, 1b ... Second case member, 5
...... Shafts with fixed blades, 6 ...... pipe shafts, 9 …… turbine blades, 15 …… toothed pulleys (driving pulleys), 18 …… toothed pulleys (driven pulleys), 16 …… rotor shafts, 20 ...... Rotor, 21 …… Belt, 23 …… Stator.

Claims (1)

[Claims] 1. A rotor of a generator, wherein a shaft having water turbine blades at both ends is rotatably supported by the housing in a state of penetrating the housing, and an axial rotation of the shaft is transmitted through a speed increasing transmission mechanism in the housing. In the hydroelectric power generation device configured to be transmitted to a drive-side pulley, the drive-side pulley connected to the shaft, the driven pulley connected to the rotor, and the drive pulley and the driven pulley. And a belt for connecting to the shaft are arranged side by side in a direction orthogonal to the shaft, and the housing is composed of a first case member and a second case member which are mutually separable in a penetrating direction of the shaft. The stator of the generator is fixed to the inside of the generator so that the entire generator is arranged from the center of the driving pulley and driven pulley to the first case member side. Is offset, hydraulic power unit, characterized in that at least one of the water wheel blades detachably configured with respect to the shaft.