CN212151595U - Two-way hand variable speed booster-type bottled water pumping device - Google Patents

Abstract

A two-way hand-operated variable-speed supercharged barreled water pumping device comprises a water pumping pipe, an air suction pipe, a water outlet pipe, an air outlet pipe, a water path valve set module, an air path valve set module, a two-way water pump, a two-way air pump, a crank, a driving shaft, a transmission shaft, a driving large gear, a driving small gear, a driven one-way large gear, a driven one-way small gear, a shell and a water barrel water intake plugging sleeve. The crank is rotated, the driven unidirectional small/large gear is driven to rotate by the driving large/small gear, and then the bidirectional water/pump is driven to operate by the transmission shaft; the rotation directions of the crank handles are different, and the two pumps run at high speed or low speed; in the operation process of the two pumps, water in the water bucket firstly enters the water path valve group module through the water pumping pipe, then enters the water pump through the water path valve group module, and finally returns to the water path valve group module and is discharged out of the bucket through the water outlet pipe; in the air path, air firstly enters the air path valve group module through the air suction pipe, then enters the air pump through the air path valve group module, and finally returns to the air path valve group module and is injected into the water bucket through the air outlet pipe for pressurization.

Description

Two-way hand variable speed booster-type bottled water pumping device

Technical Field

The utility model belongs to the technical field of the lifting installation, especially, relate to a two-way hand variable-speed booster-type bottled water pumping device.

Background

The water taking mode of the barreled water is mainly divided into two modes, the first water taking mode needs the water barrel to be assembled with the water dispenser, a water taking port of the water barrel is inversely inserted into a water inlet at the top end of the water dispenser, and water can be discharged only by pressing a water outlet valve on the water dispenser when water is taken; the second water taking mode needs to use the bag type water pump, when water is taken through the bag type water pump, the water taking port of the bucket is upward, the water pumping pipe of the bag type water pump is inserted into the bucket through the water taking port, the air bag needs to be compressed downwards during water taking, air in the air bag is pressed into the bucket, the pressure in the bucket is increased, and under the positive pressure effect, water in the bucket can be pressed into the water pumping pipe of the bag type water pump and then enters the water outlet pipe of the bag type water pump, and finally flows out of the outer pipe opening of the water outlet pipe.

However, the service life of traditional bag-type water pump is short, the gasbag is after the multiple compression, the gasbag will get into the fatigue damage stage very fast, tiny crackle will appear gradually on the utricule of gasbag afterwards, can demonstrate to become the breach afterwards, lead to gasbag gas leakage, the gasbag compression at this moment is more and more low to the produced malleation effect of water in the cask, and then cause the continuous reduction of pressurized-water efficiency, directly show that also do not have many water to flow from the outlet pipe through the multiple compression gasbag, can only do scrapping treatment with this bag-type water pump this moment, then change brand-new bag-type water pump.

Furthermore, the traditional bag type water pump adopts a compressed air bag to take water, so that the water outlet flow is single and difficult to accurately control, and the phenomenon that the water quantity flowing out of the water outlet pipe often exceeds the expectation and the exceeding water quantity is wasted only in vain is directly shown.

SUMMERY OF THE UTILITY MODEL

Problem to prior art existence, the utility model provides a two-way hand variable speed booster-type bottled water pumping device, life is longer, can satisfy the play water flow of two kinds of differences and change control.

In order to achieve the above purpose, the utility model adopts the following technical scheme: a two-way hand-operated variable-speed supercharged barreled water pumping device comprises a water pumping pipe, an air suction pipe, a water outlet pipe, an air outlet pipe, a waterway valve set module, an air passage valve set module, a two-way water pump, a two-way air pump, a crank, a driving shaft, a transmission shaft, a driving large gear, a driving small gear, a driven one-way large gear, a driven one-way small gear, a shell and a water barrel water intake plug-in sleeve; the driving shaft is arranged in the shell, the driving gearwheel and the driving pinion are coaxially and fixedly sleeved on the driving shaft, the driving shaft has a rotation degree of freedom, one end of the driving shaft extends to the outside of the shell, and the crank is arranged at the end part of the driving shaft positioned outside the shell; the transmission shaft is arranged in the shell, the transmission shaft is parallel to the driving shaft, the transmission shaft has a rotation degree of freedom, the driven unidirectional large gear and the driven unidirectional small gear are coaxially sleeved on the transmission shaft, and the unidirectional rotation directions of the driven unidirectional large gear and the driven unidirectional small gear on the transmission shaft are opposite; the driving large gear is meshed with the driven one-way small gear; the driving pinion is meshed with the driven unidirectional bull gear; the bidirectional water pump and the bidirectional air pump are arranged in the shell, and a central rotating shaft of the bidirectional water pump, a central rotating shaft of the bidirectional air pump and the transmission shaft are coaxial and fixedly connected in series; the waterway valve group module is arranged in the shell, and four waterway valve ports, namely a first waterway valve port, a second waterway valve port, a third waterway valve port and a fourth waterway valve port, are arranged on the waterway valve group module; the first waterway valve port is communicated with one end of a water pumping pipe, and the other end of the water pumping pipe is inserted into the bucket; the second waterway valve port is communicated with a first water pumping and draining port of the bidirectional water pump through a first adapter water pipe, and the third waterway valve port is communicated with a second water pumping and draining port of the bidirectional water pump through a second adapter water pipe; the fourth waterway valve port is communicated with one end of the water outlet pipe, and the other end of the water outlet pipe extends to the outside of the shell and is communicated with the atmosphere; the gas circuit valve group module is arranged in the shell, and four gas circuit valve ports, namely a first gas circuit valve port, a second gas circuit valve port, a third gas circuit valve port and a fourth gas circuit valve port, are arranged on the gas circuit valve group module; the first gas circuit valve port is communicated with one end of the gas suction pipe, and the other end of the gas suction pipe extends to the outside of the shell and is communicated with the atmosphere; the second air path valve port is communicated with a first pumping exhaust port of the bidirectional air pump through a first switching air pipe, and the third air path valve port is communicated with a second pumping exhaust port of the bidirectional air pump through a second switching air pipe; the fourth gas circuit valve port is communicated with one end of a gas outlet pipe, and the other end of the gas outlet pipe is inserted into the water barrel; the bucket water intake plug sleeve is fixedly connected to the bottom of the shell, and the bucket water intake plug sleeve is sleeved outside the water pumping pipe and the air outlet pipe.

The waterway valve group module comprises a waterway valve group module shell, a first waterway one-way valve, a second waterway one-way valve, a third waterway one-way valve and a fourth waterway one-way valve; the first waterway one-way valve, the second waterway one-way valve, the third waterway one-way valve and the fourth waterway one-way valve are all arranged inside the waterway valve group module shell; the water inlet end of the first waterway one-way valve is communicated with the water pumping pipe through a first waterway valve port, and the water outlet end of the first waterway one-way valve is communicated with the first water transfer pipe through a second waterway valve port; the water inlet end of the second waterway one-way valve is communicated with the water pumping pipe through a first waterway valve port, and the water outlet end of the second waterway one-way valve is communicated with the second adapter water pipe through a third waterway valve port; the water inlet end of the third waterway one-way valve is communicated with the second adapter water pipe through a third waterway valve port, and the water outlet end of the third waterway one-way valve is communicated with the water outlet pipe through a fourth waterway valve port; the water inlet end of the fourth waterway one-way valve is communicated with the first water-receiving pipe through the second waterway valve port, and the water outlet end of the fourth waterway one-way valve is communicated with the water outlet pipe through the fourth waterway valve port.

The air circuit valve group module comprises an air circuit valve group module shell, a first air circuit one-way valve, a second air circuit one-way valve, a third air circuit one-way valve and a fourth air circuit one-way valve; the first air path one-way valve, the second air path one-way valve, the third air path one-way valve and the fourth air path one-way valve are all arranged inside the air path valve group module shell; the air inlet end of the first air path one-way valve is communicated with the air suction pipe through a first air path valve port, and the air outlet end of the first air path one-way valve is communicated with the first adapter air pipe through a second air path valve port; the air inlet end of the second air path one-way valve is communicated with the air suction pipe through a first air path valve port, and the air outlet end of the second air path one-way valve is communicated with the second switching air pipe through a third air path valve port; the air inlet end of the third air path one-way valve is communicated with the second switching air pipe through a third air path valve port, and the air outlet end of the third air path one-way valve is communicated with the air outlet pipe through a fourth air path valve port; and the air inlet end of the fourth air path one-way valve is communicated with the first adapter air pipe through a second air path valve port, and the air outlet end of the fourth air path one-way valve is communicated with the air outlet pipe through a fourth air path valve port.

The utility model has the advantages that:

the utility model discloses a two-way hand variable-speed booster-type bottled water pumping device, life is longer, can satisfy two kinds of different water flow and change control.

Drawings

Fig. 1 is an appearance diagram of a bidirectional hand-operated variable-speed booster-type barreled water pumping device of the utility model;

fig. 2 is a perspective view (partially cut away) of a bidirectional hand-operated variable-speed booster-type barreled water pumping device of the present invention;

fig. 3 is a front view of the two-way hand-operated variable-speed supercharged barreled water pumping device (in overall section) of the present invention;

fig. 4 is an overall assembly view of the waterway valve block module, the air passage valve block module, the bidirectional water pump and the bidirectional air pump of the present invention;

fig. 5 is a schematic structural diagram of the waterway valve set module of the present invention;

fig. 6 is a working schematic diagram of the waterway valve set module (high flow operation state) of the present invention;

fig. 7 is a working schematic diagram of the waterway valve set module (low flow operation state) of the present invention;

fig. 8 is a schematic structural diagram of the gas circuit valve group module of the present invention;

fig. 9 is a working schematic diagram of the gas circuit valve set module (high flow operation state) of the present invention;

fig. 10 is a working schematic diagram of the gas circuit valve set module (low-high flow operation state) according to the present invention;

in the figure, 1-water pumping pipe, 2-air suction pipe, 3-water outlet pipe, 4-air outlet pipe, 5-waterway valve group module, 6-waterway valve group module, 7-bidirectional water pump, 8-bidirectional air pump, 9-crank, 10-driving shaft, 11-driving shaft, 12-driving big gear, 13-driving small gear, 14-driven one-way big gear, 15-driven one-way small gear, 16-shell, 17-bucket water intake plug-in sleeve, 18-first transfer water pipe, 19-second transfer water pipe, 20-first transfer air pipe, 21-second transfer air pipe, 22-waterway valve group module shell, 23-first waterway one-way valve, 24-second waterway one-way valve, 25-third waterway one-way valve, 26-fourth waterway one-way valve, 27-waterway valve group module shell, 28-first air passage one-way valve, 29-second air passage one-way valve, 30-third air passage one-way valve, 31-fourth air passage one-way valve.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

As shown in fig. 1 to 10, a two-way hand-operated variable-speed booster-type barreled water pumping device comprises a pumping pipe 1, an air suction pipe 2, an water outlet pipe 3, an air outlet pipe 4, a waterway valve group module 5, an air passage valve group module 6, a two-way water pump 7, a two-way air pump 8, a crank 9, a driving shaft 10, a transmission shaft 11, a driving large gear 12, a driving small gear 13, a driven one-way large gear 14, a driven one-way small gear 15, a shell 16 and a water barrel water intake plug-in sleeve 17; the driving shaft 10 is arranged in a shell 16, the driving gearwheel 12 and the driving pinion 13 are coaxially and fixedly sleeved on the driving shaft 10, the driving shaft 10 has a rotation degree of freedom, one end of the driving shaft 10 extends to the outside of the shell 16, and the crank 9 is arranged at the end part of the driving shaft 10 positioned outside the shell 16; the transmission shaft 11 is arranged in the shell 16, the transmission shaft 11 is parallel to the driving shaft 10, the transmission shaft 11 has a rotation degree of freedom, the driven unidirectional large gear 14 and the driven unidirectional small gear 15 are coaxially sleeved on the transmission shaft 11, and the unidirectional rotation directions of the driven unidirectional large gear 14 and the driven unidirectional small gear 15 on the transmission shaft 11 are opposite; the driving gearwheel 12 is meshed with the driven unidirectional pinion 15; the driving pinion 13 is meshed with the driven unidirectional bull gear 14; the bidirectional water pump 7 and the bidirectional air pump 8 are arranged in the shell 16, and a central rotating shaft of the bidirectional water pump 7, a central rotating shaft of the bidirectional air pump 8 and the transmission shaft 11 are coaxial and fixedly connected in series; the waterway valve group module 5 is arranged in the shell 16, and four waterway valve ports, namely a first waterway valve port, a second waterway valve port, a third waterway valve port and a fourth waterway valve port, are arranged on the waterway valve group module 5; the first waterway valve port is communicated with one end of a water pumping pipe 1, and the other end of the water pumping pipe 1 is inserted into a bucket; the second waterway valve port is communicated with a first water pumping and draining port of the bidirectional water pump 7 through a first adapter water pipe 18, and the third waterway valve port is communicated with a second water pumping and draining port of the bidirectional water pump 7 through a second adapter water pipe 19; the fourth waterway valve port is communicated with one end of the water outlet pipe 3, and the other end of the water outlet pipe 3 extends to the outside of the shell 16 and is communicated with the atmosphere; the gas circuit valve group module 6 is arranged in the shell 16, and four gas circuit valve ports, namely a first gas circuit valve port, a second gas circuit valve port, a third gas circuit valve port and a fourth gas circuit valve port, are arranged on the gas circuit valve group module 6; the first gas circuit valve port is communicated with one end of the gas suction pipe 2, and the other end of the gas suction pipe 2 extends to the outside of the shell 16 and is communicated with the atmosphere; the second air path valve port is communicated with a first pumping exhaust port of the bidirectional air pump 8 through a first switching air pipe 20, and the third air path valve port is communicated with a second pumping exhaust port of the bidirectional air pump 8 through a second switching air pipe 21; the fourth gas path valve port is communicated with one end of a gas outlet pipe 4, and the other end of the gas outlet pipe 4 is inserted into the water barrel; the bucket water intake plug bush 17 is fixedly connected to the bottom of the shell 16, and the bucket water intake plug bush 17 is sleeved outside the water pumping pipe 1 and the air outlet pipe 4.

The waterway valve block module 5 comprises a waterway valve block module shell 22, a first waterway one-way valve 23, a second waterway one-way valve 24, a third waterway one-way valve 25 and a fourth waterway one-way valve 26; the first waterway one-way valve 23, the second waterway one-way valve 24, the third waterway one-way valve 25 and the fourth waterway one-way valve 26 are all installed inside the waterway valve block module shell 22; the water inlet end of the first waterway one-way valve 23 is communicated with the water pumping pipe 1 through a first waterway valve port, and the water outlet end of the first waterway one-way valve 23 is communicated with the first water transfer pipe 18 through a second waterway valve port; the water inlet end of the second waterway one-way valve 24 is communicated with the water pumping pipe 1 through a first waterway valve port, and the water outlet end of the second waterway one-way valve 24 is communicated with the second adapter water pipe 19 through a third waterway valve port; the water inlet end of the third waterway one-way valve 25 is communicated with the second adapter water pipe 19 through a third waterway valve port, and the water outlet end of the third waterway one-way valve 25 is communicated with the water outlet pipe 3 through a fourth waterway valve port; the water inlet end of the fourth waterway one-way valve 26 is communicated with the first diverting water pipe 18 through the second waterway valve port, and the water outlet end of the fourth waterway one-way valve 26 is communicated with the water outlet pipe 3 through the fourth waterway valve port.

The air circuit valve group module 6 comprises an air circuit valve group module shell 27, a first air circuit one-way valve 28, a second air circuit one-way valve 29, a third air circuit one-way valve 30 and a fourth air circuit one-way valve 31; the first air path one-way valve 28, the second air path one-way valve 29, the third air path one-way valve 30 and the fourth air path one-way valve 31 are all arranged inside the air path valve group module shell 27; the air inlet end of the first air path one-way valve 28 is communicated with the air suction pipe 2 through a first air path valve port, and the air outlet end of the first air path one-way valve 28 is communicated with the first adapter air pipe 20 through a second air path valve port; the air inlet end of the second air path one-way valve 29 is communicated with the air suction pipe 2 through a first air path valve port, and the air outlet end of the second air path one-way valve 29 is communicated with the second switching air pipe 21 through a third air path valve port; the air inlet end of the third air path check valve 30 is communicated with the second switching air pipe 21 through a third air path valve port, and the air outlet end of the third air path check valve 30 is communicated with the air outlet pipe 4 through a fourth air path valve port; the air inlet end of the fourth air path one-way valve 31 is communicated with the first adapter 20 through a second air path valve port, and the air outlet end of the fourth air path one-way valve 31 is communicated with the air outlet pipe 4 through a fourth air path valve port.

The utility model is described with the following drawings in the process of one-time use:

before the water suction pipe is used, the water suction pipe 1 is aligned and inserted into a water intake of a bucket until the water suction pipe 1 completely extends into the bucket, and meanwhile, the water intake insertion sleeve 17 of the bucket is sleeved on the water intake of the bucket in an interference mode.

Taking the clockwise rotation crank 9 as an example, firstly, the driving shaft 10 is driven to rotate clockwise, and then the driving gearwheel 12 and the driving pinion 13 are driven to rotate synchronously, through the rotation of the driving gearwheel 12, the driven unidirectional pinion 15 engaged with the driving gearwheel can be driven to rotate anticlockwise, the driving shaft 11 can be driven to rotate synchronously through the driven unidirectional pinion 15, at the moment, the speed-up transmission is performed, and at the same moment, through the rotation of the driving pinion 13, the driven unidirectional gearwheel 14 engaged with the driving gearwheel can be driven to rotate, but the driven unidirectional gearwheel 14 idles relative to the driving shaft 11, the transmission of driving force is not performed, and along with the anticlockwise rotation of the driving shaft 11, the central rotating shaft which synchronously drives the bidirectional water pump 7 and the bidirectional air pump 8 rotates anticlockwise.

When the central rotating shaft of the bidirectional water pump 7 rotates counterclockwise, as shown in fig. 6, negative pressure is generated in the first water transfer pipe 18, and positive pressure is generated in the second water transfer pipe 19, at this time, the first water path check valve 23 and the third water path check valve 25 are conducted under the action of positive pressure difference, and the second water path check valve 24 and the fourth water path check valve 26 are still in a closed state under the action of negative pressure difference, during the process, water in the bucket enters the water outlet pipe 3 through the water pumping pipe 1, the first water path check valve 23, the first water transfer pipe 18, the bidirectional water pump 7, the second water transfer pipe 19 and the third water path check valve 25 in sequence, and finally the water in the bucket flows out from the water outlet pipe 3 in a high flow state.

When the central rotating shaft of the bidirectional air pump 8 rotates counterclockwise, as shown in fig. 9, negative pressure is generated in the first switching air pipe 20, and positive pressure is generated in the second switching air pipe 21, at this time, the first air path check valve 28 and the third air path check valve 30 are conducted under the action of positive pressure difference, and the second air path check valve 29 and the fourth air path check valve 31 are still in a closed state under the action of negative pressure difference, during this process, air outside the housing 16 sequentially passes through the air suction pipe 2, the first air path check valve 28, the first switching air pipe 20, the bidirectional air pump 8, the second switching air pipe 21, and the third air path check valve 30 to enter the air outlet pipe 4, and finally the air is filled into the water tank, so that high-speed pressurization of the interior of the water tank is realized.

Taking the counterclockwise rotation crank 9 as an example, firstly, the driving shaft 10 is driven to rotate counterclockwise, and then the driving gearwheel 12 and the driving pinion 13 are driven to rotate synchronously, through the rotation of the driving pinion 13, the driven unidirectional gearwheel 14 engaged with the driving gearwheel can be driven to rotate clockwise, the driving shaft 11 can be driven to rotate synchronously through the driven unidirectional gearwheel 14, at this moment, the speed reduction transmission is performed, and at the same moment, through the rotation of the driving gearwheel 12, the driven unidirectional pinion 15 engaged with the driving gearwheel can be driven to rotate, but the driven unidirectional pinion 15 idles relative to the driving shaft 11, the transmission of the driving force is not performed, and along with the clockwise rotation of the driving shaft 11, the central rotating shaft which synchronously drives the bidirectional water pump 7 and the bidirectional air pump 8 rotates clockwise.

When the central rotating shaft of the bidirectional water pump 7 rotates clockwise, as shown in fig. 7, positive pressure is generated in the first transfer water pipe 18, and negative pressure is generated in the second transfer water pipe 19, at this time, the second waterway one-way valve 24 and the fourth waterway one-way valve 26 are conducted under the action of positive pressure difference, and the first waterway one-way valve 23 and the third waterway one-way valve 25 are still in a closed state under the action of negative pressure difference, in this process, water in the bucket enters the water outlet pipe 3 through the water pumping pipe 1, the second waterway one-way valve 24, the second transfer water pipe 19, the bidirectional water pump 7, the first transfer water pipe 18 and the fourth waterway one-way valve 26 in sequence, and finally water in the bucket flows out from the water outlet pipe 3 in a low flow state.

When the central rotating shaft of the bidirectional air pump 8 rotates clockwise, as shown in fig. 10, positive pressure is generated in the first switching air pipe 20, and negative pressure is generated in the second switching air pipe 21, at this time, the second air path check valve 29 and the fourth air path check valve 31 are conducted under the action of positive pressure difference, and the first air path check valve 28 and the third air path check valve 30 are still in a closed state under the action of negative pressure difference, in this process, air outside the shell 16 sequentially passes through the air suction pipe 2, the second air path check valve 29, the second switching air pipe 21, the bidirectional air pump 8, the first switching air pipe 20 and the fourth air path check valve 31 to enter the air outlet pipe 4, and finally the air is filled into the water tank, so that low-speed pressurization of the interior of the water tank is realized.

The embodiments are not intended to limit the scope of the present invention, and all equivalent implementations or modifications that do not depart from the scope of the present invention are intended to be included within the scope of the present invention.

Claims (3)

1. The utility model provides a two-way hand variable speed booster-type bottled water pumping device which characterized in that: the water intake device comprises a water pumping pipe, an air suction pipe, a water outlet pipe, an air outlet pipe, a waterway valve group module, an air passage valve group module, a two-way water pump, a two-way air pump, a crank, a driving shaft, a transmission shaft, a driving large gear, a driving small gear, a driven one-way large gear, a driven one-way small gear, a shell and a water intake plugging sleeve of a bucket; the driving shaft is arranged in the shell, the driving gearwheel and the driving pinion are coaxially and fixedly sleeved on the driving shaft, the driving shaft has a rotation degree of freedom, one end of the driving shaft extends to the outside of the shell, and the crank is arranged at the end part of the driving shaft positioned outside the shell; the transmission shaft is arranged in the shell, the transmission shaft is parallel to the driving shaft, the transmission shaft has a rotation degree of freedom, the driven unidirectional large gear and the driven unidirectional small gear are coaxially sleeved on the transmission shaft, and the unidirectional rotation directions of the driven unidirectional large gear and the driven unidirectional small gear on the transmission shaft are opposite; the driving large gear is meshed with the driven one-way small gear; the driving pinion is meshed with the driven unidirectional bull gear; the bidirectional water pump and the bidirectional air pump are arranged in the shell, and a central rotating shaft of the bidirectional water pump, a central rotating shaft of the bidirectional air pump and the transmission shaft are coaxial and fixedly connected in series; the waterway valve group module is arranged in the shell, and four waterway valve ports, namely a first waterway valve port, a second waterway valve port, a third waterway valve port and a fourth waterway valve port, are arranged on the waterway valve group module; the first waterway valve port is communicated with one end of a water pumping pipe, and the other end of the water pumping pipe is inserted into the bucket; the second waterway valve port is communicated with a first water pumping and draining port of the bidirectional water pump through a first adapter water pipe, and the third waterway valve port is communicated with a second water pumping and draining port of the bidirectional water pump through a second adapter water pipe; the fourth waterway valve port is communicated with one end of the water outlet pipe, and the other end of the water outlet pipe extends to the outside of the shell and is communicated with the atmosphere; the gas circuit valve group module is arranged in the shell, and four gas circuit valve ports, namely a first gas circuit valve port, a second gas circuit valve port, a third gas circuit valve port and a fourth gas circuit valve port, are arranged on the gas circuit valve group module; the first gas circuit valve port is communicated with one end of the gas suction pipe, and the other end of the gas suction pipe extends to the outside of the shell and is communicated with the atmosphere; the second air path valve port is communicated with a first pumping exhaust port of the bidirectional air pump through a first switching air pipe, and the third air path valve port is communicated with a second pumping exhaust port of the bidirectional air pump through a second switching air pipe; the fourth gas circuit valve port is communicated with one end of a gas outlet pipe, and the other end of the gas outlet pipe is inserted into the water barrel; the bucket water intake plug sleeve is fixedly connected to the bottom of the shell, and the bucket water intake plug sleeve is sleeved outside the water pumping pipe and the air outlet pipe.

2. The two-way hand-cranking variable-speed booster-type barreled water pumping device as claimed in claim 1, wherein: the waterway valve group module comprises a waterway valve group module shell, a first waterway one-way valve, a second waterway one-way valve, a third waterway one-way valve and a fourth waterway one-way valve; the first waterway one-way valve, the second waterway one-way valve, the third waterway one-way valve and the fourth waterway one-way valve are all arranged inside the waterway valve group module shell; the water inlet end of the first waterway one-way valve is communicated with the water pumping pipe through a first waterway valve port, and the water outlet end of the first waterway one-way valve is communicated with the first water transfer pipe through a second waterway valve port; the water inlet end of the second waterway one-way valve is communicated with the water pumping pipe through a first waterway valve port, and the water outlet end of the second waterway one-way valve is communicated with the second adapter water pipe through a third waterway valve port; the water inlet end of the third waterway one-way valve is communicated with the second adapter water pipe through a third waterway valve port, and the water outlet end of the third waterway one-way valve is communicated with the water outlet pipe through a fourth waterway valve port; the water inlet end of the fourth waterway one-way valve is communicated with the first water-receiving pipe through the second waterway valve port, and the water outlet end of the fourth waterway one-way valve is communicated with the water outlet pipe through the fourth waterway valve port.

3. The two-way hand-cranking variable-speed booster-type barreled water pumping device as claimed in claim 1, wherein: the air circuit valve group module comprises an air circuit valve group module shell, a first air circuit one-way valve, a second air circuit one-way valve, a third air circuit one-way valve and a fourth air circuit one-way valve; the first air path one-way valve, the second air path one-way valve, the third air path one-way valve and the fourth air path one-way valve are all arranged inside the air path valve group module shell; the air inlet end of the first air path one-way valve is communicated with the air suction pipe through a first air path valve port, and the air outlet end of the first air path one-way valve is communicated with the first adapter air pipe through a second air path valve port; the air inlet end of the second air path one-way valve is communicated with the air suction pipe through a first air path valve port, and the air outlet end of the second air path one-way valve is communicated with the second switching air pipe through a third air path valve port; the air inlet end of the third air path one-way valve is communicated with the second switching air pipe through a third air path valve port, and the air outlet end of the third air path one-way valve is communicated with the air outlet pipe through a fourth air path valve port; and the air inlet end of the fourth air path one-way valve is communicated with the first adapter air pipe through a second air path valve port, and the air outlet end of the fourth air path one-way valve is communicated with the air outlet pipe through a fourth air path valve port.

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