TWM562316U - Air squeeze water intake device - Google Patents

Abstract

Generally, a submersible horsepower electric motor-driven submersible water pump can only extract groundwater within 40 meters below the ground. The submersible water pump with more than half horsepower is very expensive; however, the groundwater in many areas is deep. More than 50 meters, the pump below one-half horsepower is not available in these areas. The creation uses high-pressure compressed air to infuse the air into the pipe from the underground air pipe. The high-pressure compressed air will squeeze the water in the connecting pipe and the water outlet pipe, causing the water to rise along the water outlet pipe. Out of the ground, it can reach the groundwater of more than 500 meters, and the air compressor only needs one-eighth horsepower. This creation can also be added with solar power to provide remote areas.

Description

Air squeeze water intake device

This creation is a device that draws water from a groundwater or from a low place, especially a mechanism that uses high-pressure air to push water from a deep or low point in the ground, pushing the water down the pipe to a high place.

Generally, a submersible water pump driven by an electric motor with a horsepower of less than one horsepower can only extract groundwater within 40 meters of the ground. For example, if the groundwater is more than 50 meters deep, it is usually driven by a motor below one-half horsepower. Submersible pumps are not available. At present, an air inlet pipe is inserted into a large pipe deep into the ground (the diameter of the large pipe is about 2 吋), and then a large amount of air is driven into the bottom of the large pipe through the air inlet pipe to push the water to the ground, but a large amount is required. The high-pressure air is poured in, so much waste of energy, the above traditional institutional shortcomings should be improved.

Generally, a submersible horsepower electric motor-driven submersible water pump can only extract groundwater within 40 meters below the ground. The submersible water pump with more than half horsepower is very expensive; however, the groundwater in many areas is deep. More than 50 meters, the pump below one-half horsepower is not available in these areas. The creation uses high-pressure compressed air to infuse the air into the pipe from the underground air pipe. The high-pressure compressed air will squeeze the water in the connecting pipe and the water outlet pipe, causing the water to rise along the water outlet pipe. Out of the ground, it can reach the groundwater of more than 500 meters, and the air compressor only needs one-eighth horsepower. This creation can also be added with solar power. Provide use in remote areas.

9‧‧‧ Ground

10‧‧‧Old big pipe

11‧‧‧Old air tube

12‧‧‧Exhaust air

13‧‧‧ water

20‧‧‧ big tube

21‧‧‧Air inlet

21A‧‧‧ hole

21B‧‧‧Small hole

22‧‧‧Water outlet

23‧‧‧Connected pipe

24‧‧ ‧ separate tube

25‧‧1# check valve

Check valve of 26‧‧‧2

27‧‧‧ discharged water

28‧‧‧Water level sensor

29‧‧‧Wire

30‧‧‧Water Detector

31‧‧‧Wire

32‧‧‧Water storage bucket

33‧‧‧ water

34‧‧‧ water

39‧‧‧Wire

40‧‧‧3 check valve

41‧‧‧Air compressor

42‧‧‧Wire

43‧‧‧Control box

44‧‧‧ solar panels

45‧‧‧Wire

46‧‧‧Electromagnetic three-way valve

60‧‧‧4 check valve

Check valve of 61‧‧‧5

The first pattern is a structural diagram of a conventional traditional inefficient water intake system.

The second drawing is an overall structure and a partial cross-sectional view of the present embodiment.

The third figure is a structural diagram of the No. 1 check valve and the No. 2 check valve which are not installed in the present embodiment.

The fourth figure is a structural diagram of the check valve No. 1, No. 2, and No. 4 which are not installed in the present embodiment.

The fifth figure is an intermediate view of the lower end of the air inlet pipe directly connected to the water outlet pipe in the present embodiment.

The sixth figure is a check valve No. 4 of the lower end of the water outlet pipe of the present embodiment.

The seventh figure is a return structure diagram of the present embodiment.

For a more complete and clear disclosure of the technical content, the purpose of the creation and the effects achieved by the present application, an embodiment will be described in detail below, and please refer to the illustrated drawings and drawings: Referring to the first figure, the old high-pressure air is discharged from the air compressor (41) through the lower end of the old air pipe (11) to discharge air (12), and the exhaust air (12) is pushed in the old large pipe (12). The water (13) in the tube (10) causes the water (13) in the old large pipe (10) to rise upward, and the water (13) is discharged from the upper end opening of the old large pipe (10) to discharge the water (27). It can flow into the water storage tank (32), but this method requires a large amount of high-pressure air to be produced, which is a waste of energy.

This creation (please read the first, second, third and fourth figures) uses the air compressor (41) to generate high-pressure air, which passes through the No. 3 check valve (40) and then enters the upper end of the air inlet pipe (21). The lower end of the air inlet pipe (21) is connected to one or more communication pipes (23), and the other end of the communication pipe (23) is connected to the water outlet pipe (22), so that the high-pressure air entering the air inlet pipe (21) is pushed and connected. The water (34) in the pipe (23) and the outlet pipe (22) causes the water (34) in the outlet pipe (22) to rise upward, and the water (34) passes through the check valve (26) of the No. 2, and then Passing one or more water flu detectors (30), and then discharging them through the upper outlet opening of the outlet pipe (22), and the discharged water (27) falls into the water storage tank (22) to become the accumulated water (33), the water ( 33) It is convenient for people to use. The middle and lower sections of the air inlet pipe (21) and the outlet pipe (22) extend into the large pipe (20), and the large pipe (20) can be a general underground well extending into the ground (9), and the diameter can be 1 〞, 2 〞, 3〞 and 4〞, etc., or upright pipes, or wells or pools, the lower section of the large pipe (20) will be filled with water; next to the air inlet pipe (21) at the exit of the 3rd check valve (40) An electromagnetic three-way valve (46) is connected. The function of the electromagnetic three-way valve (46) is that the high-pressure air discharged from the air compressor (41) is filled with the air inlet pipe (21), the communication pipe (23) and the water outlet pipe ( 22), the electromagnetic three-way valve (46) is energized (ON), so that the high-pressure air discharged from the air compressor (41) is blocked, and no longer flows into the air inlet pipe (21), and the air is introduced into the pipe (21). Connecting the external space, the high-pressure air in the air inlet pipe (21) is discharged, and the pressure in the air inlet pipe (21), the communication pipe (23) and the water outlet pipe (22) becomes atmospheric pressure, and the check valve No. 1 (25) is used. Opening, the water in the large pipe (20) enters the check valve (25) of No. 1, and the water passes through the branch pipe (24) and enters the air inlet pipe (21), the communication pipe (23) and the water outlet pipe (22). After the time, the electromagnetic three-way valve (46) is powered off (off) again. The air inlet pipe (21) communicates with the external space, and the high-pressure air discharged from the air compressor (41) starts to flow again into the upper end of the air inlet pipe (21), and the water (34) is pushed again to make the water (34) flow out of the water outlet pipe ( 22) the upper end opening, The water flu detector (30) is connected to the control box (43) by wires (31); the water level sensor (28) is connected to the control box (43) by wires (29), and the solar panel (44) can also be installed, and Connect the control box (43) with wires (45). In this creation, the air inlet pipe (21) and the water outlet pipe (22) can be folded into a U shape using the same pipe, so that the communication pipe (23) can be omitted, but the diameter of the large pipe (30) needs to be large enough. This creation may also be equipped with a check valve No. 1 (25), and a small hole (21A) is provided in the air inlet pipe (21), or a small hole (21B) is provided in the water outlet pipe (22) (refer to the third figure). The water is directly injected into the air inlet pipe (21) with a relatively large amount of high-pressure air, and the water at the bottom of the water outlet pipe (22) is pushed to the top outlet of the water outlet pipe (22) to be discharged. In the second figure, the check valve No. 2 (26) may not be provided.

This creation also does not include the No. 1 check valve (25), the No. 2 check valve (26), the No. 3 check valve (40) and the solar panel (44) (see the fourth figure), which is directly compressed by air. The machine (41) injects high pressure air into the air inlet pipe (21).

This creation can also directly connect the lower end of the air inlet pipe (21) to the middle of the water outlet pipe (22) (please refer to the fifth figure); or install the 4th stop at the lower end of the water outlet pipe (22). Valve (see Figure 6).

The large pipe (20) of the present invention is a water-filled container, and any water well, lake or sea, etc., which can be immersed in the water into the pipe (21) and the water outlet pipe (22), can replace the large pipe ( 20).

This creation can also use a loop-type structure (see Figure 7) to make the water outlet pipe (22) into a plurality of loops, and at the top of the loop wound around each water outlet pipe (22). Set the No. 5 check valve (61), there are several loop types, and there are several No. 5 check valves (61).

This creation can increase the diameter of the water outlet pipe (22) and insert the air inlet pipe (21) into the water outlet pipe (22) without connecting the communication pipe (23). Air can also be piped into the tube (21) Increase and insert the water outlet pipe (22) into the air inlet pipe (21) without connecting the communication pipe (23).

Claims (14)

An air squeeze water pumping device comprises: an air compressor, which can generate high-pressure air, the high-pressure air can enter the upper end of the air inlet pipe; an air inlet pipe, the air inlet pipe portion extends into the water, the air inlet pipe The upper end nozzle is connected to the high-pressure air discharge port of the air compressor, and the lower end of the air inlet pipe is connected to one end of the communication pipe, and the other end of the communication pipe is connected to the lower end of the water outlet pipe; a water outlet pipe, and the lower end of the water outlet pipe is connected with the communication pipe One end. The air squeeze water intake device according to claim 1, wherein the upper end of the air inlet pipe is first connected to one end of the electromagnetic three-way valve, and the other end of the electromagnetic three-way valve is connected to the outlet of the high pressure air of the air compressor. The air squeeze water intake device according to the first aspect of the patent application, wherein a water flu detector can be connected in the middle of the water outlet pipe to sense whether there is water or water flowing in the pipe of the water outlet pipe. According to the air-extracting water-drawing device of the first aspect of the patent application, in the middle of the water outlet pipe, a check valve No. 2 can be installed. The air squeeze water intake device according to claim 1, wherein the system can be equipped with solar panels to generate electricity to provide system power energy. According to the air-extracting water-drawing device of the first aspect of the patent application, in which the No. 1 check valve and the No. 2 check valve are not provided, and one of the air inlet pipe and the water outlet pipe is provided with a small hole. According to the air-extracting water-drawing device of the first aspect of the patent application, the No. 1 check valve and the No. 2 check valve are not provided, and small holes are provided in the water outlet pipe and the air inlet pipe. According to the air-extracting water-drawing device of the first application of the patent scope, the No. 1 check valve, the No. 2 check valve, the No. 3 check valve and the electromagnetic three-way valve are not installed, and the air inlet pipe and the water are not included. One of the outlets is provided with a small hole. According to the air-extracting water-drawing device of the first application of the patent scope, the No. 1 check valve, the No. 2 check valve, the No. 3 check valve and the electromagnetic three-way valve are not installed, and the water outlet pipe and A small hole is provided in the air inlet pipe. According to the air squeeze water intake device of the first aspect of the patent application, wherein the air inlet pipe is directly connected to the lower end of the pipe, and is not connected to the communication pipe. According to the air-extracting water-drawing device of claim 10, wherein the lower end of the water outlet pipe can be equipped with a check valve No. 4. According to the air squeezing and assault device of claim 1, wherein the water outlet pipe can be made into a squatting type. The air squeeze water intake device according to claim 1, wherein the water outlet pipe diameter is increased, and the air inlet pipe is inserted into the water outlet pipe. The air squeeze water intake device according to claim 1, wherein the air inlet pipe diameter is increased, and the water outlet pipe is inserted into the air inlet pipe.