CN112412770A - Bidirectional adsorption water pump equipment capable of accelerating output - Google Patents

Abstract

The invention relates to sampling equipment, in particular to accelerated output water pump equipment for bidirectional adsorption, which comprises a bidirectional adsorption mechanism, a linkage filtering mechanism and an accelerated output mechanism, wherein the equipment can adsorb water and other liquid in two directions, can automatically output the liquid through a water pipe on the other side in the process of adsorbing the liquid, can filter the liquid entering from a water inlet, can output the liquid in an accelerated manner, is connected with the linkage filtering mechanism, and is connected with the bidirectional adsorption mechanism.

Description

Bidirectional adsorption water pump equipment capable of accelerating output

Technical Field

The invention relates to an accelerated output water pump device, in particular to an accelerated output water pump device for bidirectional adsorption.

Background

In hydraulic engineering, the water pump is often required to be capable of bidirectionally adsorbing, but no good bidirectionally-adsorbing accelerated output water pump equipment exists in the market, so that the bidirectionally-adsorbing accelerated output water pump equipment is designed.

Disclosure of Invention

The invention mainly solves the technical problem of providing the accelerated output water pump equipment for bidirectional adsorption, the equipment can adsorb water and other liquid in two directions, the equipment can automatically output the liquid through the water pipe on the other side in the process of adsorbing the liquid, the equipment can filter the liquid entering from the water inlet, and the equipment can accelerate the output of the liquid.

In order to solve the technical problems, the invention relates to a sampling device, in particular to a bidirectional adsorption pump device capable of outputting water in an accelerated mode.

The bidirectional adsorption mechanism is connected with the linkage filtering mechanism, and the acceleration output mechanism is connected with the bidirectional adsorption mechanism.

As a further optimization of the technical scheme, the invention relates to an accelerated output water pump device for bidirectional adsorption, which comprises a motor, a motor shaft, a friction wheel a, a belt a, a connecting shaft a, a friction wheel b, a connecting plate a, a connecting plate b, a connecting plate c, a connecting plate d, a connecting plate e, a connecting plate f, a sliding groove, a connecting plate g, a belt b, a connecting shaft b, a friction wheel c, a rotating ring a, a propeller a, a connecting shaft c, a bearing ring, a water pipe, a rotating ring b, a propeller b, a connecting shaft d, a connecting pipe, a sealing plate, a water tank sealing plate and a sealing circular plate, wherein the motor is connected with the motor shaft, the motor shaft is connected with the friction wheel a, the friction wheel a is connected with the connecting plate b, the belt a is connected with the motor shaft in a friction manner, the connecting shaft a is connected with the belt a, the connecting plate b is connected with the connecting plate a, the connecting plate c is connected with the friction wheel b, the connecting plate d is connected with the connecting plate c, the connecting plate e is connected with the connecting plate b in a sliding mode, the connecting plate f is connected with the water tank, the sliding groove is connected with the connecting plate d in a sliding mode, the connecting plate g is connected with the connecting plate c in a sliding mode, the belt b is connected with the motor shaft in a friction mode, the connecting shaft b is connected with the belt b in a friction mode, the friction wheel c is connected with the connecting shaft b, the rotating ring a is connected with the friction wheel c, the propeller a is connected with the rotating ring a, the connecting shaft c is connected with the propeller a, the bearing ring is connected with the rotating ring a bearing, the water pipe is connected with and communicated with the sealing plate, the rotating ring b is connected with the friction wheel c, the propeller b is connected with the rotating ring, the water tank is connected with the water tank sealing plate, the sealing circular plate is connected with the rotating ring b, the motor is connected with the water tank, the motor shaft is connected with the water tank bearing, the connecting shaft a is connected with the water tank bearing, the connecting plate b is connected with the water tank in a sliding mode, the connecting plate d is connected with the water tank in a sliding mode, the connecting plate g is connected with the water tank, the connecting shaft b is connected with the water tank bearing, the rotating ring a is connected with the water tank bearing, the water pipe is connected with the water tank and communicated with the water tank, the rotating ring b.

As a further optimization of the technical scheme, the invention relates to a bidirectional adsorption accelerated output water pump device, which comprises a first belt, a linkage shaft, a linkage bearing plate, a second belt, a linkage friction wheel a, a linkage shaft a, a linkage friction wheel b, a sliding limiting plate, a sliding plate, a compression shaft, a compression spring, a compression plate, a reset connecting plate, a reset shaft, a reset connecting plate a, a reset spring and a reset connecting plate b, wherein the first belt is in friction connection with the connecting shaft a, the linkage shaft is in friction connection with the first belt, the linkage bearing plate is in friction connection with the linkage shaft, the second belt is in friction connection with the linkage shaft, the linkage friction wheel a is in friction connection with the second belt, the linkage shaft a is connected with the friction wheel a, the linkage friction wheel b is connected with the linkage shaft a, the sliding limiting plate is connected with a water tank, the sliding plate is in sliding connection with the sliding limiting plate, and, the pressing spring is sleeved on the pressing shaft and limited on the sliding plate and the pressing plate, the pressing plate is connected with the pressing shaft, the reset connecting plate is connected with the water tank, the reset shaft is connected with the reset connecting plate in a sliding mode, the reset connecting plate a is connected with the reset shaft, the reset spring is sleeved on the reset shaft and limited on the reset shaft, the reset connecting plate b is connected with the reset connecting plate b, the linkage bearing plate is connected with the water tank, the linkage shaft a is connected with the water tank bearing, the linkage friction wheel b is connected with the sliding plate in a friction mode, and the sliding plate is connected with the.

As a further optimization of the technical scheme, the invention relates to an accelerated output water pump device for bidirectional adsorption, which comprises a mounting plate, a mounting plate a, an output motor shaft, an output belt, an output transmission shaft, an output propeller, an output ring, a mounting plate b, an output pipe a, an output pipe b, an output pipe c and a mounting plate c, wherein the mounting plate is connected with a water tank, the mounting plate a is connected with the mounting plate, the output motor is connected with the mounting plate a, the output motor shaft is connected with the output motor, the output belt is in friction connection with the output motor shaft, the output transmission shaft is in friction connection with the output belt, the output propeller is connected with the output transmission shaft, the output ring is in sliding connection with the output propeller, the mounting plate b is connected with an output transmission shaft bearing, the output pipe a is connected and communicated with the, the output pipe c is connected and communicated with the water tank, the mounting plate c is connected with the output ring, the output pipe b on one side is connected with the connecting plate b in a sliding mode, the output pipe b on the other side is connected with the connecting plate d in a sliding mode, and the mounting plate c is connected with the water tank.

As a further optimization of the technical scheme, the accelerated output water pump equipment for bidirectional adsorption is characterized in that the propellers a, b and the output propellers are made of carbon fiber reaction force propellers.

As a further optimization of the technical scheme, the invention relates to an accelerated output water pump device for bidirectional adsorption, wherein two propellers a are a forward propeller and a reverse propeller, two propellers b are a forward propeller and a reverse propeller, and the propeller a and the propeller b on the same side are a forward propeller and a reverse propeller.

As a further optimization of the technical scheme, the accelerated output water pump equipment for bidirectional adsorption is provided, and the surface of the compression plate is provided with a large number of micropores capable of filtering out impurities in water.

The accelerated output water pump equipment for bidirectional adsorption has the beneficial effects that:

according to the accelerated output water pump equipment for bidirectional adsorption, disclosed by the invention, water and other liquid can be bidirectionally adsorbed, the equipment can automatically output the liquid through the water pipe on the other side in the process of adsorbing the liquid, the equipment can filter the liquid entering from the water inlet, and the equipment can accelerate the output of the liquid.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a schematic structural diagram of a bidirectional adsorption pump device capable of accelerating output.

Fig. 2 is a schematic structural diagram of a two-way adsorption accelerated output water pump device according to the present invention.

Fig. 3 is a schematic structural diagram of a bidirectional adsorption mechanism 1 of an accelerated output water pump apparatus for bidirectional adsorption according to the present invention.

Fig. 4 is a schematic structural diagram of a two-way adsorption mechanism 1 of an accelerated output water pump device for two-way adsorption according to the present invention.

Fig. 5 is a third schematic structural diagram of a bidirectional adsorption mechanism 1 of an accelerated output water pump device for bidirectional adsorption according to the present invention.

Fig. 6 is a fourth schematic structural diagram of a bidirectional adsorption mechanism 1 of an accelerated output water pump device for bidirectional adsorption according to the present invention.

Fig. 7 is a schematic structural diagram of water tanks 1-28 of an accelerated delivery water pump device for bidirectional adsorption according to the present invention.

Fig. 8 is a schematic structural diagram of a linkage filtering mechanism 2 of an accelerated output water pump device for bidirectional adsorption according to the first embodiment of the present invention.

Fig. 9 is a second schematic structural diagram of the linkage filtering mechanism 2 of the accelerated delivery water pump device for bidirectional adsorption according to the present invention.

Fig. 10 is a third schematic structural diagram of the linkage filtering mechanism 2 of the bidirectional adsorption accelerated output water pump device of the invention.

Fig. 11 is a fourth schematic structural diagram of the linkage filtering mechanism 2 of the accelerated delivery water pump device for bidirectional adsorption according to the present invention.

Fig. 12 is a first structural schematic diagram of an accelerated output mechanism 3 of an accelerated output water pump device for bidirectional adsorption according to the present invention.

Fig. 13 is a second schematic structural diagram of an accelerated output mechanism 3 of an accelerated output water pump device for bidirectional adsorption according to the present invention.

Fig. 14 is a third schematic structural diagram of an accelerated output mechanism 3 of an accelerated output water pump device for bidirectional adsorption according to the present invention.

In the figure: a bidirectional adsorption mechanism 1; a motor 1-1; a motor shaft 1-2; friction wheel a 1-3; belt a 1-4; connecting shaft a 1-5; friction wheel b 1-6; connection board a 1-7; connecting plate b 1-8; connecting plate c 1-9; connecting plate d 1-10; connecting plate e 1-11; connecting plate f 1-12; 1-13 of a sliding groove; connecting plates g 1-14; belts b 1-15; connecting shaft b 1-16; friction wheel c 1-17; a rotating ring a 1-18; propeller a 1-19; connecting shafts c 1-20; 1-21 parts of bearing ring; 1-22 parts of a water pipe; a rotating ring b 1-23; propeller b 1-24; connecting shafts d 1-25; connecting pipes 1-26; sealing plates 1-27; 1-28 of a water tank; a water tank sealing plate 1-29; sealing circular plates 1-30; a linkage filtering mechanism 2; 2-1 of a first belt; 2-2 of a linkage shaft; 2-3 of a linkage bearing plate; 2-4 parts of a second belt; a linkage friction wheel a 2-5; linkage shaft a 2-6; a linkage friction wheel b 2-7; 2-8 sliding limit plates; a sliding plate 2-9; 2-10 of a compression shaft; pressing the springs 2-11; 2-12 of a compression plate; resetting the connecting plates 2-13; reset shafts 2-14; reset connecting plate a 2-15; 2-16 of a return spring; reset connecting plate b 2-17; an acceleration output mechanism 3; mounting plate 3-1; mounting plate a 3-2; an output motor 3-3; an output motor shaft 3-4; 3-5 parts of an output belt; 3-6 parts of an output transmission shaft; 3-7 parts of an output propeller; 3-8 parts of output ring; mounting plate b 3-9; an output pipe a 3-10; output pipe b 3-11; an output pipe c 3-12; mounting plate c 3-13.

Detailed Description

The first embodiment is as follows:

the present embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, and fig. 14, the present invention relates to a sampling device, and more specifically, to an accelerated delivery water pump device for bidirectional adsorption, which includes a bidirectional adsorption mechanism 1, a linkage filter mechanism 2, and an accelerated delivery mechanism 3, and is capable of adsorbing water and other liquids in both directions, automatically delivering the liquid through a water pipe on the other side during the process of adsorbing the liquid, filtering the liquid entering from a water inlet, and accelerating the delivery of the liquid.

The bidirectional adsorption mechanism 1 is connected with the linkage filtering mechanism 2, and the acceleration output mechanism 3 is connected with the bidirectional adsorption mechanism 1.

The second embodiment is as follows:

the following describes the present embodiment with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, and the present embodiment further describes the present embodiment, where the bidirectional adsorption mechanism 1 includes a motor 1-1, a motor shaft 1-2, a friction wheel a1-3, a belt a1-4, a connecting shaft a1-5, a friction wheel b1-6, a connecting plate a1-7, a connecting plate b1-8, a connecting plate c1-9, a connecting plate d1-10, a connecting plate e1-11, a connecting plate f1-12, a sliding groove 1-13, a connecting plate 45-14, a belt b1-15, a connecting shaft b1-16, a friction wheel c1-17, a rotating ring a1-18, a propeller a1-19, a connecting shaft c1-20, 1-21 parts of bearing ring, 1-22 parts of water pipe, 1-23 parts of rotating ring b1-23 parts of propeller b1-24 parts of connecting shaft d1-25 parts of connecting pipe, 1-26 parts of sealing plate, 1-27 parts of water tank, 1-28 parts of water tank sealing plate and 1-30 parts of sealing circular plate, wherein motor 1-1 is connected with 1-2 parts of motor shaft, 1-2 parts of motor shaft are connected with a friction wheel a1-3 part of friction wheel a1-3 part of friction wheel b1-8 part of connecting plate, a belt a1-4 part of friction wheel is connected with 1-2 parts of motor shaft, a connecting shaft a1-5 part is connected with a belt a1-4 part of friction wheel, b1-6 part of friction wheel is connected with a1-5 part of connecting shaft, a connecting plate a1-7 part of friction wheel a1-3 part of connecting plate b1-8 part of connecting plate a1-7 part of, a connecting plate d1-10 is connected with a connecting plate c1-9, a connecting plate e1-11 is connected with a connecting plate b1-8 in a sliding manner, a connecting plate f1-12 is connected with water tanks 1-28, sliding grooves 1-13 are connected with a connecting plate d1-10 in a sliding manner, a connecting plate g1-14 is connected with a connecting plate c1-9 in a sliding manner, a belt b1-15 is connected with a motor shaft 1-2 in a friction manner, a connecting shaft b1-16 is connected with a belt b1-15 in a friction manner, friction wheels c1-17 are connected with connecting shafts b1-16, rotating rings a1-18 are connected with friction wheels c1-17 in a friction manner, propellers a screw propellers a1-19 is connected with rotating rings a1-18, connecting shafts c1-20 are connected with screw propellers a1-19, bearing rings 1-21 are connected with rotating rings a1-18 bearing, water pipes 1-22, the rotating ring b1-23 is in friction connection with a friction wheel c1-17, the propeller b1-24 is connected with a rotating ring b1-23, the connecting shaft d1-25 is connected with the propeller b1-24, one end of the connecting pipe 1-26 is connected and communicated with the bearing ring 1-21, the other end is connected and communicated with the sealing circular plate 1-30, the sealing plate 1-27 is connected with the bearing ring 1-21, the water tank 1-28 is connected with the water tank sealing plate 1-29, the sealing circular plate 1-30 is connected with the rotating ring b1-23, the motor 1-1 is connected with the water tank 1-28, the motor shaft 1-2 is connected with the water tank 1-28 by a bearing, the connecting shaft a1-5 is connected with the water tank 1-28 by a bearing, the connecting plate b1-8 is in sliding connection with the water tank 1-28, the connecting plate d 36, connecting plates g1-14 are connected with water tanks 1-28, connecting shafts b1-16 are connected with water tanks 1-28 through bearings, rotating rings a1-18 are connected with water tanks 1-28 through bearings, water pipes 1-22 are connected and communicated with water tanks 1-28, rotating rings b1-23 are connected with water tanks 1-28 through bearings, connecting shafts d1-25 are connected with sealing circular plates 1-30 through bearings, the equipment can adsorb water and other liquid in two directions, the equipment can automatically output liquid through the water pipe on the other side in the process of adsorbing liquid, the motor 1-1 works to drive a motor shaft 1-2 to rotate, the motor shaft 1-2 rotates to drive a friction wheel a1-3 to rotate, the motor shaft 1-2 rotates to drive a connecting shaft a1-5 to rotate through a1-4, connecting shaft a1-5 rotates to drive friction wheel b1-6 to rotate, friction wheel a1-3 rotates to drive connecting plate b1-8 to slide to one side of the equipment under the limitation of connecting plate e1-11 through connecting plate a1-7, friction wheel b1-6 rotates to drive connecting plate d1-10 to slide to the other side of the equipment under the limitation of sliding groove 1-13 through connecting plate c1-9, in the process, one of connecting plate b1-8 and connecting plate d1-10 shields the other side of the circular hole on water tank 1-28 and gradually does not shield, connecting plate b1-8 and connecting plate d1-10 contact connecting plate f1-12 at two sides, connecting plate b1-8 and connecting plate d1-10 slide to limit, and friction connection between friction wheel a1-3 and connecting plate a1-7 fails, the friction wheel a1-3 continues to rotate, the friction connection between the friction wheel b1-6 and the connecting plate c1-9 is failed, the friction wheel b1-6 continues to rotate, the motor shaft 1-2 rotates to drive the connecting shaft b1-16 to rotate through the belt b1-15, the connecting shaft b1-16 rotates to drive the friction wheel c1-17 to rotate, the friction wheel c1-17 rotates to drive the rotating ring a1-18 to rotate, the rotating ring a1-18 rotates to drive the propeller a1-19 to rotate, the propeller a1-19 rotates to drive the connecting shaft c1-20 to rotate, the propeller a1-19 on one side rotates to absorb water into the water tank 1-28 through the water pipe 1-22, and the propeller a1-19 on the other side rotates to discharge air in the rotating ring a1-18 towards the direction of the water pipe 1-22, one of the connecting plates b1-8 and the connecting plate d1-10 is adsorbed to be tightly attached to the water tank 1-28, the friction wheel c1-17 drives the propeller b1-24 to rotate through the rotating ring b1-23 when rotating, the propeller b1-24 drives the connecting shaft d1-25 to rotate, when the screw propeller b1-24 on one side of the water pipe 1-22 for sucking water rotates, the water in the water tank 1-28 is blown to the water tank 1-28, when the screw propeller b1-24 on the other side rotates, the water is discharged to the rotating ring a1-18 through the connecting pipe 1-26, and water is discharged out of the equipment through the water pipes 1-22 at the same side under the action of the propellers a1-19 at the same side, and when the motor 1-1 drives the motor shaft 1-2 to rotate reversely, the water inlet pipes and the water outlet pipes of the water pipes 1-22 at the two sides act reversely.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, and fig. 14, and the embodiment further describes the embodiment, where the linkage filter mechanism 2 includes a belt i 2-1, a linkage shaft 2-2, a linkage bearing plate 2-3, a belt ii 2-4, a linkage friction wheel a2-5, a linkage shaft a2-6, a linkage friction wheel b2-7, a sliding position limiting plate 2-8, a sliding plate 2-9, a pressing shaft 2-10, a pressing spring 2-11, a pressing plate 2-12, a return connecting plate 2-13, a return shaft 2-14, a return connecting plate a2-15, a return spring 2-16, a return connecting plate b2-17, the belt i 2-1 is frictionally connected to the connecting shaft a1-5, a linkage shaft 2-2 is in frictional connection with a belt I2-1, a linkage bearing plate 2-3 is in frictional connection with the linkage shaft 2-2, a belt II 2-4 is in frictional connection with the linkage shaft 2-2, a linkage friction wheel a2-5 is in frictional connection with a belt II 2-4, a linkage shaft a2-6 is in connection with a friction wheel a2-5, a linkage friction wheel b2-7 is in connection with a linkage shaft a2-6, a sliding limit plate 2-8 is in connection with a water tank 1-28, a sliding plate 2-9 is in sliding connection with a sliding limit plate 2-8, a pressing shaft 2-10 is in sliding connection with a sliding plate 2-9, a pressing spring 2-11 is sleeved on the pressing shaft 2-10 and limited on the sliding plate 2-9 and the pressing plate 2-12, the pressing plate 2-12 is connected with the pressing shaft 2-10, the reset connecting plate 2-13 is connected with the water tank 1-28, the reset shaft 2-14 is connected with the reset connecting plate 2-13 in a sliding way, the reset connecting plate a2-15 is connected with the reset shaft 2-14, the reset spring 2-16 is sleeved on the reset shaft 2-14, the limit position is limited, the reset connecting plate 2-13 is connected with the reset connecting plate b2-17, the reset connecting plate b2-17 is connected with the reset shaft 2-14, the linkage bearing plate 2-3 is connected with the water tank 1-28, the linkage shaft a2-6 is connected with the water tank 1-28 bearing, the linkage friction wheel b2-7 is connected with the sliding plate 2-9 in a friction way, the sliding plate 2-9 is connected with the water tank 1-28 in a sliding way, the device can filter the liquid entering from the water inlet, the motor 1-1 works, the motor 1-1, the motor shaft 1-2 rotates to drive the connecting shaft a1-5 to rotate through the belt a1-4, the connecting shaft a1-5 rotates to drive the linkage shaft 2-2 to rotate through the belt one 2-1, the linkage shaft 2-2 rotates to drive the other linkage shaft 2-2 to rotate through the belt two 2-4, the two linkage friction wheels a2-5 are driven to rotate when the two belts two 2-4 rotate, the two linkage friction wheels a2-5 rotate to drive the two linkage friction wheels b2-7 to rotate through the linkage shaft a2-6, the linkage friction wheels b2-7 rotate to drive the two sliding plates 2-9 to slide under the limitation of the sliding limit plates 2-8, at the moment, one sliding plate 2-9 slides towards the belt one 2-1 direction, the other sliding plate slides towards the reverse direction, the sliding plates 2-9 are driven by the pressing shaft 2-10 to press the plates 2-12 to move in the sliding process of the sliding plates 2-9, the pressing plate 2-12 can be closely contacted with the water tank 1-28 under the action of the pressing spring 2-11, the pressing plate 2-12 is moved to completely shield the water inlet hole at one side of the water inlet pipe 1-22 in the process, the water outlet hole at the other side is not shielded gradually, the sliding plate 2-9 has a limit position in the moving process under the action of the return spring 2-16, the return connecting plate b2-17 is pressed when the sliding plate 2-9 reaches the limit position, the return connecting plate b2-17 gives reverse thrust to the sliding plate 2-9 under the action of the return spring 2-16, the pressing plate 2-12 at one side of the water inlet pipe filters water in the process, and the pressing plate 2-12 at one side of the water outlet pipe is not shielded by the water outlet hole.

The fourth concrete implementation mode:

referring to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, the present embodiment further illustrates the present embodiment, in which the acceleration output mechanism 3 includes a mounting plate 3-1, a mounting plate a3-2, an output motor 3-3, an output motor shaft 3-4, an output belt 3-5, an output transmission shaft 3-6, an output propeller 3-7, an output ring 3-8, a mounting plate b3-9, an output pipe a3-10, an output pipe b3-11, an output pipe c3-12, and a mounting plate c3-13, the mounting plate 3-1 is connected to the water tank 1-28, the mounting plate a3-2 is connected to the mounting plate 3-1, the output motor 3-3 is connected to the mounting plate a3-2, an output motor shaft 3-4 is connected with an output motor 3-3, an output belt 3-5 is in friction connection with the output motor shaft 3-4, an output transmission shaft 3-6 is in friction connection with the output belt 3-5, an output propeller 3-7 is connected with the output transmission shaft 3-6, an output ring 3-8 is in sliding connection with the output propeller 3-7, a mounting plate b3-9 is in bearing connection with the output transmission shaft 3-6, an output pipe a3-10 is connected and communicated with a mounting plate b3-9, an output pipe b3-11 is connected and communicated with an output pipe a3-10, an output pipe c3-12 is connected and communicated with a water tank 1-28, a mounting plate c3-13 is connected with the output ring 3-8, an output pipe b3-11 on one side is in sliding connection with a connecting plate b1, the output pipe b3-11 on the other side is connected with the connecting plate d1-10 in a sliding mode, the mounting plate c3-13 is connected with the water tank 1-28, the device can output liquid at an accelerated speed, the output motor 3-3 works to drive the output motor shaft 3-4 to rotate, the output motor shaft 3-4 rotates to drive the output transmission shaft 3-6 to rotate through the output belt 3-5, the output transmission shaft 3-6 rotates to drive the output propeller 3-7 to rotate, when the output propeller 3-7 rotates, water accumulated at the bottom of the water tank 1-28 is discharged to the output pipe b3-11 through the output pipe a3-10, at the moment, the device is in a water adsorption state, one side of the direction of the water outlet hole in the connecting plate b1-8 and the connecting plate d1-10 does not shield the, the output pipe c3-12 is shielded by one side of the water inlet hole without shielding the water inlet hole, namely, the water in the connecting plate e1-11 is discharged into the bearing rings 1-21 through the output pipe c3-12 at one side of the water outlet hole and is discharged out of the equipment through the water pipes 1-22.

The fifth concrete implementation mode:

the present embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, and fig. 14, and the present embodiment further describes the first embodiment in which the propellers a1-19, b1-24, and the output propeller 3-7 are made of carbon fiber reaction force propellers.

The sixth specific implementation mode:

in the following, the present embodiment is described with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, and fig. 14, and the present embodiment further describes the first embodiment, in which the two propellers a1-19 are a forward propeller and a reverse propeller, the two propellers b1-24 are a forward propeller and a reverse propeller, and the propellers a1-19 and b1-24 on the same side are a forward propeller and a reverse propeller.

The seventh embodiment:

the following describes the present embodiment with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, and fig. 14, and the present embodiment further describes the present embodiment, in which a large number of micropores are arranged on the surface of the compression plate 2-12 to filter out impurities in water.

The working principle of the device is as follows: the equipment can adsorb water and other liquid in two directions, the equipment can automatically output liquid through a water pipe on the other side in the process of adsorbing the liquid, the motor 1-1 works to drive the motor shaft 1-2 to rotate, the motor shaft 1-2 rotates to drive the friction wheel a1-3 to rotate, the motor shaft 1-2 rotates to drive the connecting shaft a1-5 to rotate through the belt a1-4, the connecting shaft a1-5 rotates to drive the friction wheel b1-6 to rotate, the friction wheel a1-3 rotates to drive the connecting plate b1-8 to slide to one side of the equipment under the limitation of the connecting plate e1-11 through the connecting plate a1-7, the friction wheel b1-6 rotates to drive the connecting plate d1-10 to slide to the other side of the equipment under the limitation of the sliding grooves 1-13 through the connecting plate c1-, in the process, one of the connecting plate b1-8 and the connecting plate d1-10 shields the other side of the round hole on the water tank 1-28 gradually, the other side of the round hole is not shielded any more, when the connecting plate b1-8 and the connecting plate d1-10 contact the connecting plate f1-12 at two sides, the connecting plate b1-8 and the connecting plate d1-10 slide to limit, at the moment, the friction connection between the friction wheel a1-3 and the connecting plate a1-7 fails, the friction wheel a1-3 continues to rotate, the friction connection between the friction wheel b1-6 and the connecting plate c1-9 fails, the friction wheel b1-6 continues to rotate, the motor shaft 1-2 rotates to drive the connecting shaft b1-16 to rotate through the belt b1-15, the connecting shaft b1-16 rotates to drive the friction wheel c1-17 to rotate, the friction wheel c1, the rotating ring a1-18 rotates to drive the propeller a1-19 to rotate, the propeller a1-19 rotates to drive the connecting shaft c1-20 to rotate, the propeller a1-19 on one side rotates to absorb water into the water tank 1-28 through the water pipe 1-22, the propeller a1-19 on the other side rotates to discharge air in the rotating ring a1-18 towards the water pipe 1-22, one of the connecting plate b1-8 and the connecting plate d1-10 is absorbed to be tightly attached to the water tank 1-28, the friction wheel c1-17 also drives the propeller b1-24 to rotate through the rotating ring b1-23 when rotating, the propeller b1-24 rotates to drive the connecting shaft d1-25 to rotate, the water in the water tank 1-28 is blown to the water tank 1-28 when the propeller b1-24 on one side of the water pipe 1-22 absorbing rotates, when the propeller b1-24 on the other side rotates, water is discharged into the rotating ring a1-18 through the connecting pipe 1-26, and is discharged out of the equipment through the water pipe 1-22 on the same side under the action of the propeller a1-19 on the same side, when the motor 1-1 drives the motor shaft 1-2 to rotate reversely, the water inlet pipe 1-22 on the two sides and the water outlet pipe act reversely, the equipment can filter the liquid entering from the water inlet, the motor 1-1 works to drive the motor shaft 1-2 to rotate, the motor shaft 1-2 rotates to drive the connecting shaft a1-5 to rotate through the belt a1-4, the a1-5 rotates to drive the connecting shaft 2-2 to rotate through the belt I2-1, the connecting shaft 2-2 rotates to drive the other connecting shaft 2-2 to rotate through the belt II 2-4, when the two belts II 2-4 rotate, the two linkage friction wheels a2-5 are driven to rotate, the two linkage friction wheels a2-5 rotate, the two linkage friction wheels b2-7 are driven to rotate through the linkage shafts a2-6, the linkage friction wheels b2-7 rotate to drive the two sliding plates 2-9 to slide under the limitation of the sliding limit plates 2-8, at the moment, one sliding plate 2-9 slides towards the direction of the belt I2-1, the other sliding plate slides towards the reverse direction, the pressing plates 2-12 are driven to move through the pressing shafts 2-10 in the sliding process of the sliding plates 2-9, the pressing plates 2-12 can be in close contact with the water tanks 1-28 under the action of the pressing springs 2-11, the pressing plates 2-12 are moved to completely shield the water inlet holes on one sides of the water inlet pipes 1-22 in the process, the water outlet hole on the other side is gradually not blocked, the sliding plate 2-9 has a limit position in the movement process under the action of the return spring 2-16, the return connecting plate b2-17 is pressed when the sliding plate 2-9 reaches the limit position, the return connecting plate b2-17 gives a reverse thrust to the sliding plate 2-9 under the action of the return spring 2-16, the compression plate 2-12 on one side of the water inlet pipe filters water in the process, the compression plate 2-12 on one side of the water outlet pipe does not block the water outlet hole, the equipment can accelerate the output of liquid, the output motor 3-3 works to drive the output motor shaft 3-4 to rotate, the output motor shaft 3-4 rotates to drive the output transmission shaft 3-6 to rotate through the output belt 3-5, the output transmission shaft 3-6 rotates to drive the output propeller 3-, when the output propeller 3-7 rotates, water accumulated at the bottom of the water tank 1-28 is discharged to the output pipe b3-11 through the output pipe a3-10, at the moment, the equipment is in a water adsorption state, one side of the direction of the water outlet hole shields the water outlet hole from shielding the output pipe c3-12, one side of the water inlet hole shields the water inlet hole from shielding the output pipe c3-12, namely, at the moment, the water in the connecting plate e1-11 is discharged into the bearing ring 1-21 through the output pipe c3-12 at the side of the water outlet hole and is discharged out of the equipment through the water pipe 1-22.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (7)

1. The utility model provides a two-way absorption is with output water pump equipment with higher speed, includes two-way adsorption device structure (1), linkage filter mechanism (2), output mechanism (3) with higher speed, its characterized in that: the bidirectional adsorption mechanism (1) is connected with the linkage filtering mechanism (2), and the acceleration output mechanism (3) is connected with the bidirectional adsorption mechanism (1).

2. The accelerated release pump apparatus for bi-directional adsorption of claim 1, further comprising: the bidirectional adsorption mechanism (1) comprises a motor (1-1), a motor shaft (1-2), a friction wheel a (1-3), a belt a (1-4), a connecting shaft a (1-5), a friction wheel b (1-6), a connecting plate a (1-7), a connecting plate b (1-8), a connecting plate c (1-9), a connecting plate d (1-10), a connecting plate e (1-11), a connecting plate f (1-12), a sliding groove (1-13), a connecting plate g (1-14), a belt b (1-15), a connecting shaft b (1-16), a friction wheel c (1-17), a rotating ring a (1-18), a propeller a (1-19), a connecting shaft c (1-20), a bearing ring (1-21), Water pipes (1-22), rotating rings b (1-23), propellers b (1-24), connecting shafts d (1-25), connecting pipes (1-26), sealing plates (1-27), water tanks (1-28), water tank sealing plates (1-29) and sealing circular plates (1-30), wherein a motor (1-1) is connected with a motor shaft (1-2), the motor shaft (1-2) is connected with friction wheels a (1-3), the friction wheels a (1-3) are connected with connecting plates b (1-8) in a friction mode, a belt a (1-4) is connected with the motor shaft (1-2) in a friction mode, a connecting shaft a (1-5) is connected with the belt a (1-4) in a friction mode, the friction wheels b (1-6) are connected with the connecting shafts a (1-5), the connecting plate a (1-7) is connected with the friction wheel a (1-3), the connecting plate b (1-8) is connected with the connecting plate a (1-7), the connecting plate c (1-9) is connected with the friction wheel b (1-6), the connecting plate d (1-10) is connected with the connecting plate c (1-9), the connecting plate e (1-11) is connected with the connecting plate b (1-8) in a sliding way, the connecting plate f (1-12) is connected with the water tank (1-28), the sliding groove (1-13) is connected with the connecting plate d (1-10) in a sliding way, the connecting plate g (1-14) is connected with the connecting plate c (1-9) in a sliding way, the belt b (1-15) is connected with the motor shaft (1-2) in a friction way, the connecting shaft b (1-16) is connected with the belt b (1-15) in, the friction wheel c (1-17) is connected with the connecting shaft b (1-16), the rotating ring a (1-18) is connected with the friction wheel c (1-17) in a friction mode, the propeller a (1-19) is connected with the rotating ring a (1-18), the connecting shaft c (1-20) is connected with the propeller a (1-19), the bearing ring (1-21) is connected with the rotating ring a (1-18) in a bearing mode, the water pipe (1-22) is connected and communicated with the sealing plate (1-27), the rotating ring b (1-23) is connected with the friction wheel c (1-17) in a friction mode, the propeller b (1-24) is connected with the rotating ring b (1-23), the connecting shaft d (1-25) is connected with the propeller b (1-24), one end of the connecting pipe (1-26) is connected and communicated with the bearing ring (1-21), the other end is connected and communicated with a sealing circular plate (1-30), a sealing plate (1-27) is connected with a bearing ring (1-21), a water tank (1-28) is connected with a water tank sealing plate (1-29), the sealing circular plate (1-30) is connected with a rotating ring b (1-23), a motor (1-1) is connected with the water tank (1-28), a motor shaft (1-2) is connected with the water tank (1-28) through a bearing, a connecting shaft a (1-5) is connected with the water tank (1-28) through a bearing, a connecting plate b (1-8) is connected with the water tank (1-28) through a sliding way, a connecting plate d (1-10) is connected with the water tank (1-28) through a sliding way, a connecting plate g (1-14) is connected with the water tank (1-28), a connecting shaft b (1-16) is connected with the water tank (, the rotating ring a (1-18) is in bearing connection with the water tank (1-28), the water pipe (1-22) is connected and communicated with the water tank (1-28), the rotating ring b (1-23) is in bearing connection with the water tank (1-28), and the connecting shaft d (1-25) is in bearing connection with the sealing circular plate (1-30).

3. The accelerated release pump apparatus for bi-directional adsorption of claim 1, further comprising: the linkage filtering mechanism (2) comprises a first belt (2-1), a linkage shaft (2-2), a linkage bearing plate (2-3), a second belt (2-4), a linkage friction wheel a (2-5), a linkage shaft a (2-6), a linkage friction wheel b (2-7), a sliding limiting plate (2-8), a sliding plate (2-9), a pressing shaft (2-10), a pressing spring (2-11), a pressing plate (2-12), a reset connecting plate (2-13), a reset shaft (2-14), a reset connecting plate a (2-15), a reset spring (2-16) and a reset connecting plate b (2-17), wherein the first belt (2-1) is in friction connection with the connecting shaft a (1-5), the linkage shaft (2-2) is in friction connection with the first belt (2-1), a linkage bearing plate (2-3) is in friction connection with a linkage shaft (2-2), a belt II (2-4) is in friction connection with the linkage shaft (2-2), a linkage friction wheel a (2-5) is in friction connection with the belt II (2-4), a linkage shaft a (2-6) is connected with a friction wheel a (2-5), a linkage friction wheel b (2-7) is connected with the linkage shaft a (2-6), a sliding limiting plate (2-8) is connected with a water tank (1-28), a sliding plate (2-9) is in sliding connection with a sliding limiting plate (2-8), a pressing shaft (2-10) is in sliding connection with the sliding plate (2-9), a pressing spring (2-11) is sleeved on the pressing shaft (2-10) and limited on the sliding plate (2-9) and the pressing plate (2-12), the pressing plate (2-12) is connected with the pressing shaft (2-10), the reset connecting plate (2-13) is connected with the water tank (1-28), the reset shaft (2-14) is connected with the reset connecting plate (2-13) in a sliding way, the reset connecting plate a (2-15) is connected with the reset shaft (2-14), the reset spring (2-16) is sleeved on the reset shaft (2-14) and is limited, the reset connecting plate (2-13) is connected with the reset connecting plate b (2-17), the reset connecting plate b (2-17) is connected with the reset shaft (2-14), the linkage bearing plate (2-3) is connected with the water tank (1-28), the linkage shaft a (2-6) is connected with the water tank (1-28) through a bearing, the linkage friction wheel b (2-7) is connected with the sliding plate (2-9) through a friction way, the sliding plates (2-9) are connected with the water tanks (1-28) in a sliding way.

4. The accelerated release pump apparatus for bi-directional adsorption of claim 1, further comprising: the acceleration output mechanism (3) comprises a mounting plate (3-1), a mounting plate a (3-2), an output motor (3-3), an output motor shaft (3-4), an output belt (3-5), an output transmission shaft (3-6), an output propeller (3-7), an output ring (3-8), a mounting plate b (3-9), an output pipe a (3-10), an output pipe b (3-11), an output pipe c (3-12) and a mounting plate c (3-13), wherein the mounting plate (3-1) is connected with a water tank (1-28), the mounting plate a (3-2) is connected with the mounting plate (3-1), the output motor (3-3) is connected with the mounting plate a (3-2), the output motor shaft (3-4) is connected with the output motor (3-3), an output belt (3-5) is in friction connection with an output motor shaft (3-4), an output transmission shaft (3-6) is in friction connection with the output belt (3-5), an output propeller (3-7) is connected with the output transmission shaft (3-6), an output ring (3-8) is in sliding connection with the output propeller (3-7), a mounting plate b (3-9) is in bearing connection with the output transmission shaft (3-6), an output pipe a (3-10) is connected and communicated with the mounting plate b (3-9), an output pipe b (3-11) is connected and communicated with the output pipe a (3-10), an output pipe c (3-12) is connected and communicated with a water tank (1-28), a mounting plate c (3-13) is connected with the output ring (3-8), the output pipe b (3-11) on one side is in sliding connection with a connecting plate b (1-8), the output pipe b (3-11) at the other side is connected with the connecting plate d (1-10) in a sliding way, and the mounting plate c (3-13) is connected with the water tank (1-28).

5. The accelerated release pump apparatus for bi-directional adsorption of claim 1, further comprising: the propellers a (1-19) and b (1-24) and the output propellers (3-7) are made of carbon fiber reaction force propellers.

6. The accelerated release pump apparatus for bi-directional adsorption of claim 1, further comprising: the two propellers a (1-19) are a forward propeller and a reverse propeller, the two propellers b (1-24) are a forward propeller and a reverse propeller, and the propellers a (1-19) and b (1-24) on the same side are a forward propeller and a reverse propeller.

7. The accelerated release pump apparatus for bi-directional adsorption of claim 1, further comprising: the surfaces of the compression plates (2-12) are provided with a large number of micropores which can filter out impurities in water.

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