JPS63198782A - Air output aggregation type wave activated power generator - Google Patents

Abstract

PURPOSE:To improve the energy conversion efficiency by rectifying air streams generated in multiple air chambers with positive pressure and negative pressure check valves and performing power generation with turbines provided between positive pressure and negative pressure side air passages. CONSTITUTION:Air chambers 30-32 are communicated to a positive pressure side air passage 36 via positive pressure check valves 33-35 and communicated to a negative pressure side air passage 40 via negative side check valves 37-39. Turbines 44, 45 are provided which are rotated by the air stream discharged to the outside through the air discharge port 41 of the positive pressure side air passage 36 and the air stream sucked from the outside air into the air intake port 42 of the negative pressure side air passage 40. Accordingly, the wave energy can be efficiently converted into the electric power energy.

Description

[Detailed Description of the Invention] [Industrial Application Field] This invention rectifies and aggregates the reciprocating motion of airflow obtained from a plurality of air chambers whose internal air pressure fluctuates due to wave force in a fixed direction. The present invention relates to an air output concentration type wave power generation device that generates power using concentrated airflow.

[Prior art] As is well known, it has been considered to generate electricity using wave energy, but since wave energy has a low energy density, it is extremely difficult to always obtain a certain amount of electricity. It has become a regular feature. For this reason, the only wave power generation devices currently in practical use that utilize wave energy are small-scale air turbine type wave power generators used for buoys.

Therefore, a wave power generation device as shown in FIG. 3 has been proposed in order to constantly obtain a certain amount of electric power using wave energy. That is, in the figure, reference numerals 11 and 12 are air chambers, the bottom of which is communicated with water. Among these, the turbine 1 is located at the upper part of the air chamber 11 in the figure.
Two air channels 15, 16 are formed which communicate with the outside air via air channels 3, 14, respectively. Also formed in the upper part of the air chamber 12 in the figure are two air passages 19.20 that communicate with the outside air via turbines 17.18, respectively.

As each of the turbines 13, 14, 17, and 18, a rotary transducer type Wells turbine as shown in, for example, Japanese Unexamined Patent Publication No. 53-92060, etc., is used.

Here, the turbine 13.14 has a bearing 21.22.
The rotating shaft 23 is rotatably supported by the rotating shaft 23. The turbines 17 and 18 also have bearings 24
．． 25 by a rotary shaft 26 rotatably supported. Further, the turbines 14 and 17 are connected by a connecting shaft 27. Further, the turbine 18 is connected to a generator 29 via a connecting shaft 28.

In such a configuration, the wavefront W1 inside the air chamber 11 is now
When the temperature rises, an air flow is generated from inside the air chamber 11 toward the outside air through the air passages 15 and 16, and the turbine f3.14 is rotated by this air flow. Conversely, when the wave surface W1 in the air chamber 11 descends, the air passages 15, 16 from the outside air side
An air flow is generated which flows into the air chamber 11 through the air chamber 11, and this air flow rotates the turbine 13,14.

On the other hand, when the wave surface W2 in the air v12 rises, the air chamber 1
An air flow is generated from inside the turbine 2 in the direction of the outside air through the air passages 19, 20, and the turbine 17.18 is rotated by this air flow. Conversely, when the wave surface W2 inside the air chamber 12 falls, an air flow is generated from the outside air side toward the inside of the air chamber 12 via the air passage 19.20, and the turbine 17.18 is rotated by this air flow. And each of the above turbines 13
．． The rotational force of 14.17.18 is applied to the connecting shaft 27.28'r
By consolidating the power and transmitting it to the generator 29, it is possible to always obtain more power than the - room.

[Problems to be solved by the invention] However, in the conventional wave power generation device as described above,
If four turbines 13, 14, 17, 18 are required and they are actually installed in a sea area, the lengths of the rotating shafts 23, 26 and connecting shafts 27, 28 will be considerably long, and the bearings (p. 21. Since a large number of 22, 24, 25 are required, the configuration becomes complicated, the efficiency of converting the air flow generated in each air chamber 11, 12 into rotational motion deteriorates, and maintenance and inspection work becomes difficult. However, it has the problem of lack of reliability.

In addition, particularly in the case of a Wells turbine, problems arise in that the starting force is weak and the torque is small, and the rotation noise is extremely loud.

Therefore, this invention has been made in consideration of the above circumstances, and provides a highly efficient air power intensive type wave power generation device that has high conversion efficiency from wave energy to electric energy and can stabilize output power. The purpose is to provide.

[Means for Solving the Problems] That is, the air output concentrating wave power generation device according to the present invention includes a plurality of independent air chambers whose internal air pressure fluctuates due to wave force generated on the water surface, and a plurality of A plurality of check valves for positive pressure and negative pressure are installed corresponding to each air chamber and are opened when the air pressure inside the air chamber is increased or decreased, and air flow flows out from the check valve for positive pressure. and positive pressure side and negative pressure side air passages respectively guiding air flows flowing into the check valve for negative pressure, an air outlet to the outside air of the positive pressure side air passage, and an air intake port from the outside air of the negative pressure side air passage. a rotating shaft that is installed astride and is rotatably supported around the axis;
The rotary shaft is provided at both ends of the rotating shaft, and receives the air flow discharged to the outside air from the air outlet of the positive pressure side air path, and the air flow sucked from the outside air into the air intake port of the negative pressure side air path, respectively. a pair of turbines that rotate rotating wheels in the same direction;
The generator is provided approximately at the center of the rotating shaft and is driven by the rotational force of the rotating shaft.

[Function] According to the above configuration, the air flows generated inside the plurality of air chambers are rectified by the positive pressure and negative pressure check valves, respectively, and concentrated in the positive pressure side and negative pressure side air paths. At the same time, from the air outlet of the positive pressure side air path, a A pair of turbines were installed to receive the airflow discharged to the outside air and the airflow taken from the outside air into the air intake port of the negative pressure side air path, respectively, and the generator was driven by the rotational force of the rotating shaft. Therefore, the configuration is simpler than the conventional one, the loss of wave energy can be reduced, the conversion efficiency into electric energy can be increased, and the output power can be stabilized.

[Embodiment J] Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings. In FIG. 1, 30.31° 32 are air chambers whose bottoms communicate with water. These air i30, 31, 32 are connected to the positive pressure check valve 33.
34, 35 to the positive pressure side air passage 36, and also communicated to the negative pressure side air passage 40 via negative pressure check valves 37, 38, 39.

Here, the air outlet 4 of the positive pressure side air passage 36 is connected to the outside air.
1 and the air intake port 42 from the outside air of the negative pressure side air path 40 are installed facing each other, and the air exhaust port 41
A rotating shaft 43 is installed so as to straddle the air intake port 42 and the air intake port 42 . At both ends of this rotating shaft 43, an air flow discharged to the outside air from the air outlet 41 of the positive pressure side air path 36 and an air flow sucked from the outside air into the air intake port 42 of the negative pressure side air path 40 are connected. A pair of turbines 44, 45 are provided respectively to rotate the rotary shaft 43 in the same direction. Further, approximately at the center of the rotating wheel 43, the rotating shaft 4 is provided.
Power generation I driven by the rotational force of 3! 146 are provided.

In the above configuration, for example, assume that the water surface W11 near the air chamber 30 has risen above the steady state (the position indicated by the dotted line in the figure), and the water surface W13 near the air chamber 32 has fallen below the steady state. Then, the air pressure in the air chamber 30 increases and the positive pressure check valve 33 is opened, while the air pressure in the air chamber 32 decreases and the negative pressure check valve 39 is opened. Therefore, a unidirectionally rectified air flow is generated in the positive pressure side and negative pressure side air passages 36, 40, as shown by the arrows in the figure.

In this case, the air flowing through the positive pressure side air passage 36 is used to rotate the turbine 44 when being discharged to the outside air from the air outlet 41, and the air flowing through the negative pressure side air passage 40 is used to rotate the turbine 44 when being discharged to the outside air from the air outlet 41. It serves to rotate the turbine 45 when taken in through the inlet 42 . For this reason,
The rotating shaft 43 is rotated by the rotational force of the two turbines 44 and 45, and generates electricity l! 146 is used to generate electricity.

Therefore, according to the configuration of the above embodiment, the air flow flowing out from each positive pressure check valve 33, 34, 35 is collected by the positive pressure side air passage 36 and supplied to the turbine 44, and each The airflow flowing in through the negative pressure check valves 37, 38° 39 is concentrated by the negative pressure air passage 40 and supplied to the turbine 45, so that each air chamber 30
．． The airflow generated by 31.32 can be converted into rotational movement without losses.

Further, since there is no need to increase the length of the rotating shaft 43 and only two turbines 44 and 45 are required, the configuration is simple and the efficiency of conversion into electric energy can be increased accordingly. Further, as the turbines 44, 45, ordinary axial flow impulse type turbines can be used without using Wells turbines, which is also advantageous in terms of construction and economy.

Here, FIG. 2 shows another embodiment of the present invention. That is, 47, 48, and 49 in the figure are air chambers whose bottoms communicate with the water. These air chambers 47
．． At the top of the figure 48.49 are pipes 50.5 and 50.5, respectively.
1.52 are connected at one end. The other ends of these pipes 50, 51, and 52 are connected to water 55 contained in a container 54 constituting a check valve 53, which is a positive pressure check valve.
is immersed in Here, the upper part of the container 54 in the figure is
It is connected to the positive pressure side air passage 56. A turbine 57 is installed within this positive pressure side air passage 56.

On the other hand, in the vicinity of the air v47, 48, 49, there is provided a container 61, 62, 63 that constitutes a check valve 58, 59, 60 that is a check valve for negative pressure. These containers 61, 62, 63 contain water 64, 65, 66,
One end of a vibrator 67, 68, 69 is immersed in the water 64, 65, 66. Further, the other ends of the vibrators 67, 68, and 69 are integrally formed to form a negative pressure side air passage 70. In this negative pressure side air passage 70, a turbine 71 is provided.
is installed, and this turbine 71 and the turbine 5
A power generator @ 73 is provided at the center of a rotating shaft 72 that connects the power generator 7 with the rotating shaft 72 .

According to such a configuration, it is assumed that, for example, the water surface W21 near the air chamber 47 is higher than the steady state (the position indicated by the dotted line in the figure), and the water surface W23 near the air chamber 49 is lower than the steady state. Then, the air pressure in the air chamber 47 increases, and since the ratio of the opening area of the vibrator 50 and the area of the container 54 excluding the opening area of the vibrator 50 is different, air flows out to the positive pressure side air path 56. Become. In addition, since the air pressure in the air chamber 49 decreases and the ratio of the opening area of the vibro 9 and the area of the container 63 excluding the opening area of the vibro 9 is different, air flows into the negative pressure side air path 70. Become. Therefore, a unidirectionally rectified air flow is generated in the positive pressure side and negative pressure side air passages 56, 70, as shown by the arrows in the figure.

In this case, the air flowing through the positive pressure side air passage 56 is used to rotate the turbine 51 when being discharged from the air discharge lower 4 to the outside air, and the air flowing through the negative pressure side air passage 70 is used to rotate the turbine 51 when being discharged from the air discharge lower 4 to the outside air. It is used to rotate the turbine 71 when taken in through the suction lower 5. For this reason,
The rotating shaft 72 is rotated by the rotational force of the two turbines 57 and 71, and power generation is performed by a generator 73.

Therefore, even with the above configuration, efficient power generation can be performed as shown in the first embodiment, and mechanical Compared to the case of using a valve mechanism, it is possible to reduce energy loss due to valve failure, and
This can extend the life of the valve. Furthermore, the check valve 53, which is a check valve for positive pressure, can be configured in the same container 54, and this also contributes to simplifying the configuration.

It should be noted that the present invention is not limited to the above-described embodiments, and can be implemented with various modifications without departing from the gist thereof.

[Effects of the Invention] Therefore, as detailed above, according to the present invention, the conversion efficiency from wave energy to electric energy is high;
It is possible to provide an extremely good air power concentrating type wave power generation device that can stabilize output power.

[Brief explanation of the drawing]

Fig. 1 is a block diagram showing one embodiment of the air power concentrating type wave power generation device according to the present invention, Fig. 2 is a block diagram showing another embodiment of the present invention, and Fig. 3 is a block diagram showing a conventional wave power generation device. FIG. 2 is a configuration diagram showing the device. 11, 12...Air chamber, 13.14...Turbine,
15.16...Air passage, 17.18...Turbine,
19.20... Air path, 21, 22... Bearing, 2
3...Rotating shaft, 24.25...Bearing, 26...
Rotating shaft, 27.28...Connection shaft, 29...Starting 14@
, 30-32...Air chamber, 33-35...Check valve for positive pressure, 36...Positive pressure side air path, 37-39...Check valve for negative pressure, 40...Negative pressure side air path, 41... air outlet, 42... air intake port, 43... rotating shaft, 44
．． 45... Turbine, 46... Engine 14 @ 147~4
9...Air chamber, 50-52...Vibe, 53...
Non-return valve, 54... Container, 55... Water, 56...
Positive pressure side air passage, 57...turbine, 58-60...
Non-return valve, 61-63... Container, 64-66... Water, 67-69... Vibrator, 70... Negative pressure side air path,
71... Turbine, 72... Rotating shaft, 73... Generator, 74... Air exhaust port, 75... Air intake port.

Claims (2)

[Claims] (1) A plurality of independent air chambers whose internal air pressure fluctuates due to wave force generated on the water surface, and a plurality of independent air chambers that are installed corresponding to each of the plurality of air chambers and are opened when the air pressure inside the air chamber is increased. a plurality of negative pressure check valves installed corresponding to the plurality of air chambers and opened when the air pressure inside the air chamber is reduced; and a plurality of positive pressure check valves. a positive pressure side air path that guides the air flow to be discharged;
It straddles a negative pressure side air path that guides the air flow flowing into the plurality of negative pressure check valves, an air outlet to the outside air of the positive pressure side air path, and an air intake port from the outside air of the negative pressure side air path. a rotating shaft that is installed at the center and supported rotatably around an axis; an air flow that is provided at both ends of the rotating shaft and is discharged to the outside air from an air outlet of the positive pressure side air passage; and the negative pressure side air passage. a pair of turbines that rotate the rotating shaft in the same direction by receiving air flows taken in from the outside air into the air intake ports of the turbine, and a turbine that is provided approximately in the center of the rotating shaft and is driven by the rotational force of the rotating shaft What is claimed is: 1. An air output intensive type wave power generation device characterized by comprising: a power generator; (2) The above-mentioned positive pressure check valve and negative pressure check valve are water valves that perform a valve action by fluctuating the water level due to a difference in air pressure. Air output concentrated type wave power generation device.