JPS60111065A - System for taking out hydraulic pressure energy as air pressure energy - Google Patents

Abstract

PURPOSE:To transduce a hydraulic potential energy directly into an air pressure energy by using a hydraulic pressure-air pressure transducer equipped with a water chamber and an air chamber. CONSTITUTION:The water in a reservoir 1 flows down, and air vent valves 5a- 5c are closed to fill a slope water pipe 2 with water. Vent valves 20a, 20b, which are set up in a vent pipe 13, are opened. An air vent valve 5d is opened, and water is fed through a water feed valve 17 to fill a water pipe 3 and a water chamber 10 of a hydraulic pressure-air pressure transducer 6 with water, and then the vent valve 5d and the water feed valve 17 are closed. When a water flow valve 4d in opened, a sliding valve 9 slides toward an air chamber 11 to compress the air in the chamber 11. Owing to the sliding of the sliding valve 9, the air pressures inside the air chamber 11, the vent pipe 13, and an air storage tank 15 rise. The vent valves 20a, 20b are closed and a joint flange 14 is removed. And, after the water flow valve 4c is closed, a drain valve 19 is opened. Another air storage tank 15 is connected to the vent pipe 13 and the vent valves 20a, 20b are opened.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a method for harvesting compressed air energy by directly converting the potential energy of water into compressed air and storing it so that it can be used freely.

Conventionally, the potential energy of water flows down a penstock and becomes pressure and velocity energy, which is absorbed by the blades of a water wheel and converted into power, or rotational energy, which turns a generator, producing hydroelectric power. used as. Generally, obtaining high-pressure air requires a complex process in which the electric power obtained in this way drives a motor and operates a compressor, which requires a large amount of capital investment and a lot of effort to operate this equipment. It was intended to be.

In view of this situation, the present invention proposes a method for directly converting and collecting the potential energy of water into high-pressure air without using any means such as power generation. A plurality of water pressure/air pressure converters are installed in a cylindrical outer shell at a location lower than the reservoir, each having an ice chamber and an air chamber separated by a slide valve slidably supported via a guide shaft. The water pressure/air pressure converter and the reservoir are connected to each other via water pipes so that they can be opened and closed, and an air storage tank is removably connected to the water pressure/air pressure converter via a ventilation pipe.・By passing water into the ice chamber of the air pressure converter and using the potential energy of the water to press and slide the t11f operating valve, the air in the air chamber is compressed into pressurized air, and the pressurized air is passed through the ventilation pipe. The air is stored in an air storage tank.

Embodiments of the present invention will be described below with reference to the drawings.

In Fig. 1, 1 is a reservoir installed at a height A''2, and 2 is an inclined water pipe laid along a slope B reaching the height Δ, with its upper end communicating with the reservoir 1 and its lower end. is the height difference I
4 and connect it to the horizontal water pipe 3. The inclined water pipe 2 is provided with water flow valves 4a, 4b and air vent valves 5a, 51) near the reservoir 1 and at an arbitrary intermediate height position, respectively.

6 is a water pressure/atmospheric pressure converter connected to the horizontal water pipe 3 and installed at a low place C, and is a sliding type having a cylindrical shape and slidably supported by a guide shaft 8 inside the outer shell 7. By providing a valve 9, it is divided into an ice chamber 10 and an air chamber 1. In addition, Himuro 1
The volume of the air chamber 11 increases or decreases depending on the position of the slide valve 9. As shown in FIG. 2, both ends of the guide shaft 8 are formed to allow free passage of water and ventilation, and are supported by supporting members 12 fixed to the outer shell 7, as well as to support the sliding stroke of the slide valve 9 (FIG. 4). It is designed to function as a regulating stopper.

Reference numeral 13 denotes a ventilation pipe communicating with the air chamber 11 of the water pressure/air pressure converter 6, and an air storage tank 15 made of a closed container is removably connected to the ventilation pipe 13 via a joining flange 14.

At the low point C, a drainage channel is provided at the bottom of the slope B.

The horizontal water pipe 3 is equipped with a water pressure gauge 1689, water flow valve 4c, air vent valve 5c + water flow valve 4d, in order from the inclined water pipe 2 side.
, a water supply valve 17 and a water pressure gauge 16b are provided, and a water supply valve 4 is provided.
A drain pipe 18 is connected to the drain pipe 18 facing the drain channel between the air release valve 5c and the air vent valve 5c. The drain pipe 18 is provided with a drain valve 19 . The water supply valve 17 is connected to another water source (not shown). Further, the ventilation pipe 13 is provided with ventilation valves 20a and 20b on both sides of the joint flange 14, and is located close to the water pressure/air pressure converter 6 and the air storage tank 15, and has a barometer 21a,
Install 21b. Furthermore, an air vent valve 5d communicating with the ice chamber 10 of the water pressure/air pressure converter 6 is provided.

Next, the operating procedures and effects of using the apparatus constructed as described above will be explained. First, close the water valve 4d provided on the horizontal water pipe 3 and the drain valve 19 of the drain pipe 18, then open the air vent valves 5a, 5b, and 5c, and then open the water valve 4c,
4b, and then open the water flow valve 4a near the reservoir 1 to allow the water in the reservoir 1 to flow1.The air forced out to the lower end of the inclined water flow pipe 2 by this water flow is extracted from the air vent valve 5c. Then, the air vent valve 5c is closed so that the water immediately overflows above the air vent valve 5c, and similarly, the air vent valves t5b and 5a are sequentially closed to fill the inclined water pipe 2 with water. As a result of this), the water pressure at the lower end of the inclined water pipe 2 is p,
bawl. (However, il++ -p'o + Hkg/
c+K; P'o is the external pressure at altitude Δ (kg/c+6)
, ■1 is the water head of the reservoir water surface (mouth 1), and 1) 8 becomes larger as H becomes larger, but it is not related to the inclination degree and pipe diameter of the inclined water pipe 2. ) In this way, after the inclined water pipe 2 is filled with water, the vent valves 20a and 20b provided in the vent pipe 13 connecting the air storage tank 15 are opened. At this time, the slide valve 9 of the water pressure/air pressure converter 6 is moved to the slide start position (the right end of the slide stroke) as shown in FIG.
The air in the air chamber 1J2 ventilation pipe 13 and air tank 15 is made equal to the outside pressure p0. Next, the air vent valve 5d connected to the ice chamber 10 of the water pressure/air pressure converter 6 is opened, and water is supplied from the water supply valve 17 connected to the horizontal water pipe 3.
Then, the water chamber 10 of the water pressure/air pressure converter 6 is filled with water, and the air vent valve 5d and water supply valve 17 are closed. The preparation for operating the water pressure/atmospheric pressure converter 6 is now complete.

Next, the water flow valve 4d is opened. By opening the water flow valve 4d, the water pressure in the water chamber 1o of the water pressure/air pressure converter 6 becomes ρ8, and this water pressure causes the slide valve 9 to compress the air in the shaft of the guy F. As shown in FIG. 4, the slide valve 9 slides all the way through its sliding stroke and is stopped by the support +A12 at the left end of the guide shaft 8. By sliding this sliding valve 9, the amount of water in the water pressure/air pressure converter 6 is filled from the water pond 113' through the inclined water pipe 2.
Since the amount of water in reservoir 1 is human, water head 1-1 and water pressure p
, is maintained with almost no decrease. Due to such sliding of the sliding valve 9, the air pressure in the air chamber 11, the ventilation pipe 13, and the air storage tank 15 reaches p. r) (however, P
<1), l). Next, the vent valves 20a and 20b are closed and the joint flange 14 is removed, so that the air 11j reservoir tank 15 storing pressurized air at the air pressure p can be freely handled and replaced.

Next, the operation of repeatedly collecting pressurized air into the air storage tank 15 will be described. First, the water flow valve 4c of the horizontal water flow pipe 3 is closed, and then the drain valve 19 is opened. At this time, the air pressure in the air chamber 11 of the ventilation pipe 13 and the water pressure/air pressure converter 6 remains at p, so by maintaining this pressure f), the water pressure/air pressure is converted by opening the drain valve 19. The water in the machine 6 is pushed by the slide valve 9 and discharged from the horizontal water pipe 3 through the drain pipe 18 to the drain channel 1 ]/\
automatically returns to the starting position of sliding stroke 1, and closes the JJI water valve 19.

At this time, if air enters the ice chamber lO of the horizontally running water pipe 3 and the water pressure/air pressure converter 6 from the drain pipe 8, air vent valve 5c.
, 5d, and adjust the water level with the water supply valve 17. Next, the air inside the tank is brought to the outside pressure P. Connect another air storage tank 15, which was left as it is, to the vent pipe 13 via the joint flange 4 and open the vent valves 20a and 20b, the water pressure/air pressure converter 6 will be in the pre-operation state, and the following steps will be performed as described above. The operation after opening the water flow valve 4d may be performed.

Although the above-mentioned embodiment is shown using only one water pressure/air pressure converter to simplify the explanation, the method of the present invention is not limited to this, and the method of the present invention is not limited to this. It is possible to increase the compression ratio and collect high-pressure air, and an embodiment using a plurality of water pressure/air pressure converters will be described below. FIG. 5 shows a structure in which horizontally running water pipes 3°, water pressure/air pressure converters 6, and ventilation pipes 13 are arranged in series as shown in FIG. 1, and a plurality of water pressure/air pressure converters 6' are installed in parallel. Each of these water pressure/atmospheric pressure converters 6' is connected by a branch water pipe 3' extending from the horizontal water pipe 3, and is individually controlled by a water valve 4Q provided in the branch water pipe 3'. Furthermore, each of these water pressure/air pressure converters 6' is connected by a branched vent pipe 13' extending to the vent pipe I3, and a vent valve provided in the branched vent pipe 1;)'. 20
The required number of these water pressure/air pressure converters 6' are operated simultaneously with the water pressure/air pressure converters 6 so that they can be opened and closed individually by the air pressure converters 6'. It is possible to collect air at a pressure p' (where p'<pH). In the case shown in FIG. 5, a plurality of water pressure/atmospheric pressure converters 6, 6' are installed in a plane, but they may be installed in a multi-stage manner.

As described below, the pressure air energy harvesting system of the present invention allows water from a reservoir installed at a high location to flow down to a lower location through a water pipe, and uses the potential energy of the water to generate water pressure and This system directly obtains pressurized air by compressing the air in the air chamber provided in the air pressure converter, and collects and stores it in a removably connected air tank. It is simple i11 and can be repeatedly collected many times. Moreover, after installation, the potential energy of water can be efficiently harvested without requiring any labor or energy other than opening/closing each valve and replacing the air storage tank.
It can be used in various ways as pressurized air energy. Furthermore, since safe water and air are used as the medium for the collection process, it is clean and non-polluting.

[Brief explanation of the drawing]

The figures relate to an embodiment of the present invention, and Fig. 1 is an overall schematic diagram shown in cross section, Fig. 2 is an enlarged sectional view taken along the line X-X of Fig. 1,
Figure 3 is an enlarged sectional view taken along Y-Y line in Figure 1, and Figure 4 is a water pressure/
FIG. 5 is a sectional view showing the operation inside the air pressure converter, and a plan view of an embodiment in which a plurality of water pressure/air pressure converters are installed. l... Reservoir, 2... Inclined water pipe, 3...
Horizontal water pipe, 6... Water pressure/air pressure converter, 7...
・Outer shell, 8...Guide shaft, 9...Slide valve, 10
...Ice chamber, 11...Air chamber, 13...Vent pipe, 15...Air storage tank. A: High place, C: Low place. 2rA Figure 3 Figure 4 Figure 5

Claims (1)

[Claims] A water pressure system that includes a reservoir located at a high location and an ice chamber and an air chamber that are partitioned by a slide valve that is slidably supported via a guide shaft in a cylindrical outer shell located at a location lower than the reservoir.
A plurality of air pressure converters are installed, and the water pressure/air pressure converters and the reservoir are connected so as to be openable and closable through respective water pipes, and an air storage tank is removably connected to the water pressure/air pressure converters via ventilation pipes. 11'i°Water from the water pond is passed through the water pipe into the water chamber of the water pressure/air pressure converter, and the water's potential energy pushes and slides the slide valve to compress the air in the air chamber. 1. A system for collecting hydraulic energy as pressure air energy, characterized in that the pressure air is converted into pressure air, and the pressure air is stored in an air storage tank via a ventilation pipe.