TWM509273U - Shore-side sea wave automatic water pumping device - Google Patents

Description

Automatic wave pumping device for shore

This creation is based on the principle of a wave energy conversion method, that is, the application of ocean waves can be directly converted into water energy. A shore automatic wave pumping device includes a plurality of hollow tubes, a base, and a high water level container. And a cavity combination, wherein a high water level container is placed on the shore, the shore is provided with a base, the base is fixed with a plurality of hollow tubes, and the plurality of hollow tubes are a collection of a plurality of hollow tubes. One end of each hollow tube is open, and the other port is connected with a thin tube. The thin tubes of each hollow tube are connected, and the other end of the thin tube is connected with a pore of a cavity, and the cavity is a suitable space, and the structure is composed of a casing, a vent, a two-way valve, an outlet, and an input port, wherein the casing of the cavity is connected to a connecting plate fixed to the edge of a hollow pipe, and the middle portion of the cavity is disposed There is a gas hole, and one outlet port and one input port are respectively arranged on the two sides of the port, and the cavity has two check valves built therein, wherein one check valve is connected to the input port and communicates with the seawater, and the other check valve is connected to the output port and then connected. a water pipe, Pipes extending into the high-water container shore.

The conversion method of the wave energy is to convert the wave energy into mechanical energy or other energy by the transmission mechanism of the floating body. This energy conversion method must have a majority of transmission mechanisms, so the energy consumption will be compared when transmitting energy. There are many, and the seawater corrosion resistance of its materials also affects its cost.

A shore automatic wave pumping device comprises a plurality of hollow tubes, a base, a high water level container and a cavity, wherein a high water level container is placed on the shore, and a base is arranged on the shore. The base is fixed to a plurality of hollow tubes by a frame, and the plurality of hollow tubes are a collection of a plurality of hollow tubes, wherein each hollow tube has an open end at one end and a thin tube at each port, each hollow The narrow tubes of the tubes are connected, and the other end of the tubes is connected to the pores of a cavity. The cavity is a suitable space, and the structure is composed of a casing, a gas hole, a two-way valve, an output port, and an input port. The combination, wherein the outer casing of the cavity is connected to a connecting plate, the connecting plate is fixed to the edge of a hollow tube, and the middle portion of the outer casing of the cavity is disposed with an air hole, and an outlet port and an input port are respectively disposed at the ports on both sides, one of the single After connecting the inlet to the valve, it is connected to the seawater, and the other check valve is connected to the outlet and is connected to a water pipe that extends to the high water level container on the shore.

As shown in Fig. 1, the open end of the hollow tube 2 and the cavity 4 are fixed under the sea surface. When the waves are fluctuating up and down, as shown by the low water level 6 and the high water level 7 in Fig. 1, the tube is inside. The volume change of the gas is as follows; total volume (V) = (V1 + V3)

V1 = volume in the hollow tube 2

V3 = volume of the thin tube 3

At low water level, the volume inside the hollow tube 2 (V1) = (A × length L1)

A = cross-sectional area of the hollow tube 2

At high water level, the volume inside the hollow tube 2 (V2) = A × length (L1-L2)

At low water levels, the pressure of the gas in the tube is P1. At high water level, the pressure of the gas in the tube is P2, then P2 = P1 × (V1 + V3) / (V2 + V3) = P1 × ((A × L1) )+V3)/((A×(L1-L2)+V3)

Obviously, the volume (V3) of the thin tube 3 is a fixed value, so the pressure of the gas in the tube will change following the change in the water level of the hollow tube 2, which causes the high pressure and the inside of the hollow tube 2, the thin tube 3, and the chamber 4 to generate high pressure and The characteristic of low pressure is that high pressure (P2>P1) occurs when the water level rises, and low pressure (P2<P1) when the water level drops. When the chamber 4 is low pressure, the check valve 45 of the output port 43 is closed, and the input port 42 is closed. When the one-way valve 44 is opened, the seawater will be sucked into the cavity 4. When the cavity 4 is at a high pressure, the check valve 44 of the input port 42 is closed, and the check valve 45 of the output port 43 is opened, the cavity is opened. The water in the body 4 will be sent to the high water level vessel 10 via a water pipe 5 due to the high pressure, which is a feature that the waves can be automatically pumped to a high water level.

According to the above features, a plurality of hollow tubes of a frame on a pedestal will have water in a cavity sent to a high water level container on the shore via a water pipe, and the high water level container on the bank can be based on the shore. The condition is to facility multiple pedestals, and the water pipes led by the majority of the hollow pipes fixed by each pedestal are connected to the high water level containers on the shore, so that a larger amount of high water level can be obtained.

1‧‧‧Support

10‧‧‧High water level container

11‧‧‧Connecting board

12‧‧‧ shore

2‧‧‧ hollow tube

20‧‧‧port

21‧‧‧ frame

22‧‧‧ pedestal

3‧‧‧Small tube

4‧‧‧ cavity

40‧‧‧ Shell

41‧‧‧ stomata

42‧‧‧ input port

43‧‧‧Outlet

44‧‧‧ check valve

45‧‧‧check valve

5‧‧‧ water pipes

50‧‧‧ water pipes

51‧‧‧High water level container

6‧‧‧Low water level

7‧‧‧High water level

L1‧‧‧ length

L2‧‧‧ length

Figure 1 is a schematic diagram of the principle of a wave energy conversion method.

Figure 2 is a schematic diagram of an application example of the present creation.

The implementation method of the automatic wave pumping device for the shore is shown in Figures 1 to 2, and an automatic water pumping device for the shore includes a plurality of hollow tubes 2, a base 22 and a high water level container. 51 and a cavity 4, wherein a high water level container 51 is placed on the shore 12, the shore 12 is provided with a base 22, and the base 22 is fixed with a frame 21 for a plurality of hollow tubes 2 , The plurality of hollow tubes 2 are a collection of a plurality of hollow tubes 2, wherein one end of each hollow tube 2 is open, and the other port 20 is connected to a thin tube 3, and the thin tubes 3 of each hollow tube 2 are connected to each other. The other end is connected to the air hole 41 of a cavity 4. As shown in Fig. 1, the cavity 4 is a suitable space, and the structure thereof is composed of a casing 40, an air hole 41, two check valves (44, 45), and a The output port 43 and the input port 42 are combined, wherein the outer casing 40 of the cavity 4 is connected to a connecting plate 11 fixed to the edge of a hollow tube 2, and the inner portion of the outer casing 40 of the cavity 4 is provided with an air hole 41. Each of the two ports is provided with an output port 43 and an input port 42. One of the check valves 44 is connected to the input port 42 and communicates with the seawater. The other check valve 43 is connected to the output port 45 and is connected to a water pipe 5, the water pipe. 5 extends to the high water level container 10.

As shown in Fig. 1, the open end of the hollow tube 2 and the cavity 4 are fixed under the sea surface. When the waves fluctuate up and down, the volume of the gas in the tube changes, and at a low water level 6, the pressure of the gas in the tube For P1, at a high water level of 7, the pressure of the gas in the tube is P2. Since the volume of the thin tube 3 is a fixed value, the pressure of the gas in the tube will change following the change of the water level of the hollow tube 2, and the pressure causes the hollow tube 2 to be The thin tube 3 and the interior of the chamber 4 are characterized by high pressure and low pressure, that is, a high pressure is generated when the water level rises (P2>P1), and a low pressure (P2<P1) is generated when the water level drops. When the chamber 4 is low pressure, the output is The check valve 45 of the port 43 is closed, the check valve 44 of the input port 42 is opened, and the seawater will be sucked into the cavity 4. When the chamber 4 is at a high pressure, the check valve 44 of the input port 42 is closed. When the one-way valve 45 of the outlet port 43 is opened, the water in the chamber 4 will be sent to the high water level container 10 via a water pipe 5 due to the high pressure, that is, the wave can be automatically pumped to a high water level.

As shown in Fig. 2, according to the above features, a plurality of hollow tubes 2 of the frame 21 on a base 22 will have a water in the chamber 4 sent to the shore 12 via a water pipe 5. The water level container 51, the high water level container 51 of the bank 12 can be equipped with a plurality of bases 22 according to the conditions of the shore 12, and the water pipes 5 led out by the plurality of hollow tubes 2 fixed by each of the bases 22 are connected. After the water pipe 50, The high water level tank 51 is sent to the shore 12 so that the high water level 51 can obtain a greater amount of water as its characteristic.

12‧‧‧ shore

2‧‧‧ hollow tube

21‧‧‧ frame

22‧‧‧ pedestal

3‧‧‧Small tube

4‧‧‧ cavity

5‧‧‧ water pipes

50‧‧‧ water pipes

51‧‧‧High water level container

Claims (2)

A shore automatic wave pumping device comprises: a plurality of hollow tubes, a base, a high water level container and a cavity combination, comprising: a plurality of hollow tubes, the plurality of hollow tubes being one The frame is fixed, and the frame is fixed on a pedestal of the bank. Most of the hollow tubes are a collection of a plurality of hollow tubes, wherein one end of each hollow tube is open and the other port is connected with a thin tube, and each hollow tube is The thin tubes are connected to each other, and the other end of the thin tube is connected to the air hole of a cavity; the cavity is a suitable space, and the structure is composed of a casing, a gas hole, a two-way valve, an output port, and an input. The combination of the mouth, wherein the outer casing of the cavity is connected to a connecting plate, the connecting plate is fixed to the edge of a hollow pipe, the middle portion of the outer casing of the cavity is disposed with an air hole, and an outlet port and an input port are respectively disposed at the ports on both sides thereof. The chamber has two check valves built therein. One of the check valves is connected to the input port and then communicates with the seawater. After the other check valve is connected to the output port, a water pipe is connected, and the water pipe extends to a high water level container; Water level container, the height The positional container is fixed on the shore, and the water quantity is sent by the water pipe connected by the cavity of the plurality of hollow tubes; when the waves are fluctuating up and down, the volume change of the gas in the tube will produce high pressure and low pressure characteristics. When the cavity is low pressure, the check valve of the output port is closed, and the check valve of the input port is opened, the seawater will be sucked into the cavity, and when the cavity is high pressure, the check valve of the input port is closed. When the check valve of the outlet is opened, the water in the chamber will be sent to the high water level container on the shore via a water pipe due to the high pressure. According to the invention of claim 1, the shore automatic wave pumping device, wherein a plurality of hollow pipes are fixed to the base, can be provided with a plurality of features according to the conditions of the shore.