CN212615198U

CN212615198U - Advection metering pump

Info

Publication number: CN212615198U
Application number: CN202020930030.3U
Authority: CN
Inventors: 周良; 王珉; 周财华
Original assignee: DEPAMU (HANGZHOU) PUMP TECHNOLOGY CO LTD
Current assignee: DEPAMU (HANGZHOU) PUMP TECHNOLOGY CO LTD
Priority date: 2020-05-27
Filing date: 2020-05-27
Publication date: 2021-02-26
Anticipated expiration: 2030-05-27

Abstract

The application discloses a advection metering pump, which comprises a pump body, a crankshaft, a half-stroke plunger and a full-stroke plunger; the pump body is provided with a half-stroke pump cavity and a full-stroke pump cavity, the half-stroke plunger and the full-stroke plunger are both slidably mounted on the pump body, one end of the half-stroke plunger is positioned in the half-stroke pump cavity, and the full-stroke plunger is positioned in the full-stroke pump cavity; the utility model discloses following beneficial effect has: the flow peak phases of the full-stroke pump cavity and the half-stroke pump cavity are 180 degrees, so that the pulsation is greatly reduced after superposition, and the flow is stable; and the half-stroke plunger can generate a reverse thrust to act on the crankshaft in the liquid suction process of the half-stroke pump cavity, so that the power is assisted in the liquid discharge process of the pump head of the full-stroke plunger, and the energy consumption is reduced.

Description

Advection metering pump

Technical Field

The utility model relates to a pump field especially relates to a advection measuring pump.

Background

The metering pump has the characteristics of accurate and adjustable flow, basically no influence of operating pressure on the flow, capability of conveying media at high precision under a high-pressure working condition and the like, and is widely applied to the industries of energy, petrifaction, thermal power and the like.

The metering pump is a positive displacement pump, so that a pulsation phenomenon inevitably exists when a medium is conveyed, vibration of a pipeline system can be caused, even resonance can be caused, and pipeline accessories can be damaged. In order to reduce pulsation, buffers are mainly arranged on the inlet and outlet pipelines of the metering pump.

Currently used buffers are mainly composed of four structures: air formula, bag formula, diaphragm type and mechanical type, four kinds of structures all have the drawback: the gas in the air buffer can be dissolved into the liquid quickly and lost, and the compressed gas is required to be filled frequently; the leather bag of the bag type buffer is a rubber product and cannot be used in a plurality of chemical solvents; the diaphragm type buffer is only suitable for low-pressure working conditions; the mechanical buffer is flushed by high-pressure and high-speed materials, parts are quickly abraded, and the buffering effect is reduced.

SUMMERY OF THE UTILITY MODEL

The utility model provides a to above-mentioned problem, a advection measuring pump is proposed.

The utility model adopts the following technical scheme:

a advection metering pump comprises a pump body, a crankshaft, a half-stroke plunger and a full-stroke plunger;

the pump body is provided with a half-stroke pump cavity and a full-stroke pump cavity, the half-stroke plunger and the full-stroke plunger are both slidably mounted on the pump body, one end of the half-stroke plunger is positioned in the half-stroke pump cavity, and the full-stroke plunger is positioned in the full-stroke pump cavity;

the half-stroke pump cavity is provided with a first one-way valve, a second one-way valve is arranged between the full-stroke pump cavity and the half-stroke pump cavity, the full-stroke pump cavity is provided with a third one-way valve and a liquid inlet valve, the first one-way valve is used for controlling liquid to flow out of the full-stroke pump cavity in a one-way mode, the second one-way valve is used for controlling liquid to flow into the half-stroke pump cavity in a one-way mode from the full-stroke pump cavity, the third one-way valve is used for controlling liquid to flow out of the full-stroke pump cavity in a one-way mode, and the liquid inlet;

the crankshaft is rotatably installed on the pump body, a first crank throw and a second crank throw are arranged on the crankshaft, the eccentric amount of the first crank throw is half of that of the second crank throw, the phase angle between the first crank throw and the second crank throw is 180 degrees, the first crank throw is used for driving the half-stroke plunger to move, and the second crank throw is used for driving the full-stroke plunger to move.

The phase angle of the first crank throw and the phase angle of the second crank throw are separated by 180 degrees, so the liquid inlet and outlet states of the half-stroke pump cavity and the full-stroke pump cavity are completely opposite, namely the half-stroke pump cavity is in a liquid discharging state when the full-stroke pump cavity is in a liquid inlet state, and the half-stroke pump cavity is in a liquid inlet state when the full-stroke pump cavity is in a liquid discharging state. Therefore, the flow peak phases of the full-stroke pump cavity and the half-stroke pump cavity are 180 degrees, the pulsation is greatly reduced after superposition, and the flow is stable; meanwhile, liquid suction of the half-stroke plunger pump head is high-pressure fluid supplied by liquid discharge of the full-stroke plunger pump head, so that the half-stroke plunger generates a reverse thrust to act on the crankshaft when liquid is fed into the half-stroke pump chamber, the power is assisted in the liquid discharge process of the full-stroke plunger pump head, and the energy consumption can be greatly reduced in the process.

In conclusion, in the scheme, the flow peak phases of the full-stroke pump cavity and the half-stroke pump cavity are 180 degrees, so that the pulsation is greatly reduced after superposition, and the flow is stable; and the half-stroke plunger can generate a reverse thrust to act on the crankshaft in the liquid suction process of the half-stroke pump cavity, so that the power is assisted in the liquid discharge process of the pump head of the full-stroke plunger, and the energy consumption is reduced.

Optionally, the hydraulic control system further comprises a connecting rod, the first crank throw drives the half-stroke plunger to move through the connecting rod, and the second crank throw drives the full-stroke plunger to move through the connecting rod.

Because the rotation of the crankshaft is rotary motion, and the motion of the full-stroke plunger and the motion of the half-stroke plunger are linear motion, the connecting rod is arranged, the linkage of the crankshaft, the full-stroke plunger and the half-stroke plunger is realized through the action of the connecting rod, and two ends of the connecting rod are hinged and matched with the crankshaft and the full-stroke plunger together.

Optionally, the pump further comprises a liquid guide tube and a connector, the liquid guide tube and the connector are communicated with the full-stroke pump cavity and the half-stroke pump cavity, and the second one-way valve is connected with the connector or the liquid guide tube.

Optionally, the liquid discharging device further comprises a liquid discharging pipe, the first one-way valve is communicated with the third one-way valve through the liquid discharging pipe, and a liquid discharging interface is arranged on the liquid discharging pipe.

Optionally, the plunger pump further comprises a plunger stuffing box, the full-stroke pump cavity and the half-stroke pump cavity are both provided with the plunger stuffing box, and the full-stroke plunger and the half-stroke plunger are both in sliding fit with the plunger stuffing box.

Optionally, the variable frequency motor is further included, and the variable frequency motor drives the crankshaft to rotate through a worm gear.

The variable frequency motor and the worm gear are used for stably driving the crankshaft to rotate and reducing energy consumption to the maximum extent.

Optionally, be provided with full stroke pump head and half stroke pump head on the pump body, half stroke pump chamber sets up in the half stroke pump head, full stroke pump chamber sets up in the full stroke pump head.

Optionally, a liquid inlet interface is arranged on the liquid inlet valve.

Optionally, the full-stroke pump chamber includes a first through hole and a second through hole, and the first through hole is communicated with the second through hole; the half-stroke pump cavity comprises a first through hole and a second through hole, and the first through hole is communicated with the second through hole.

The first design that the full-stroke pump cavity and the half-stroke pump cavity adopt the first through hole and the second through hole is to facilitate the quick installation of a first drain valve, a second drain valve, a third drain valve, a full-stroke plunger and a half-stroke plunger; and secondly, the liquid can stably flow.

The utility model has the advantages that: the flow peak phases of the full-stroke pump cavity and the half-stroke pump cavity are 180 degrees, so that the pulsation is greatly reduced after superposition, and the flow is stable; and the half-stroke plunger can generate a reverse thrust to act on the crankshaft in the liquid suction process of the half-stroke pump cavity, so that the power is assisted in the liquid discharge process of the pump head of the full-stroke plunger, and the energy consumption is reduced.

Description of the drawings:

figure 1 is a schematic diagram of a structure of a advection metering pump,

figure 2 is a schematic cross-sectional view taken along line a-a of figure 1,

figure 3 is a schematic cross-sectional view of the cross-section B-B in figure 1,

fig. 4 is a schematic diagram of the working principle of the advection metering pump.

The figures are numbered: 1. the device comprises a crankshaft, 2, a connecting rod, 3, a half-stroke plunger, 4, a half-stroke pump head, 501, a first check valve, 502, a second check valve, 503, a third check valve, 6, a liquid discharging port, 7, a full-stroke pump head, 8, a liquid inlet valve, 9, a liquid inlet port, 10, a plunger stuffing box, 11, a full-stroke plunger, 1201 first crank, 1202 second crank, 13, a first through hole, 14, a second through hole, 15, a joint, 1601, a liquid guide pipe, 1602, a liquid discharging pipe, 17, a worm wheel, 18, a worm, 19, a variable frequency motor, 20, a half-stroke pump cavity, 21 and a full-stroke pump cavity.

The specific implementation mode is as follows:

the present invention will be described in detail with reference to the accompanying drawings.

As shown in the attached

drawings

1, 2 and 3, the advection metering pump comprises a pump body, a crankshaft 1, a half-stroke plunger 3 and a full-stroke plunger 11;

the pump body is provided with a half-stroke pump cavity and a full-stroke pump cavity, the half-stroke plunger 3 and the full-stroke plunger 11 are both arranged on the pump body in a sliding manner, one end of the half-stroke plunger 3 is positioned in the half-stroke pump cavity, and the full-stroke plunger 11 is positioned in the full-stroke pump cavity;

a first one-way valve 501 is arranged on the half-stroke pump cavity 20, a second one-way valve 502 is arranged between the full-stroke pump cavity 21 and the half-stroke pump cavity 20, a third one-way valve 503 and a liquid inlet valve 8 are arranged on the full-stroke pump cavity 21, the first one-way valve 501 is used for controlling liquid to flow out of the half-stroke pump cavity 20 in a one-way mode, the second one-way valve 502 is used for controlling liquid to flow into the half-stroke pump cavity 20 in a one-way mode from the full-stroke pump cavity 21, the third one-way valve 503 is used for controlling liquid to flow out of the full-stroke pump cavity 21 in a one-way mode;

the crankshaft 1 is rotatably installed on the pump body, a first crank throw 1201 and a second crank throw 1202 are arranged on the crankshaft 1, the eccentric amount of the first crank throw 1201 is half of that of the second crank throw 1202, the phase angle between the first crank throw 1201 and the second crank throw 1202 is 180 degrees, the first crank throw 1201 is used for driving the half-stroke plunger 3 to move, and the second crank throw 1202 is used for driving the full-stroke plunger 11 to move.

The phase angles of the first crank throw 1201 and the second crank throw 1202 are 180 degrees apart, so the liquid inlet and outlet states of the half-stroke pump cavity 20 and the full-stroke pump cavity are completely opposite, that is, the half-stroke pump cavity 20 is in a liquid discharging state when the full-stroke pump cavity 21 is in a liquid inlet state, and the half-stroke pump cavity 20 is in a liquid inlet state when the full-stroke pump cavity 21 is in a liquid discharging state. Thus, the flow peak phases of the full-stroke pump cavity 21 and the half-stroke pump cavity 20 are 180 degrees, the pulsation is greatly reduced after superposition, and the flow is stable; meanwhile, liquid suction of the pump head of the half-stroke plunger 3 is high-pressure fluid supplied by liquid discharge of the pump head of the full-stroke plunger 11, so that the half-stroke plunger 3 generates reverse thrust to act on the crankshaft 1 when liquid is fed into the half-stroke pump cavity 20, the power is assisted in the liquid discharge process of the pump head of the full-stroke plunger 11, and the energy consumption can be greatly reduced in the process.

In conclusion, in the scheme, the flow peak phases of the full-stroke pump cavity 21 and the half-stroke pump cavity 20 are 180 degrees, so that the pulsation is greatly reduced after superposition, and the flow is stable; and the half-stroke plunger 3 can generate a reverse thrust to act on the crankshaft 1 in the liquid suction process of the half-stroke pump cavity 20, so that the power is assisted in the liquid discharge process of the pump head of the full-stroke plunger 11, the energy consumption is reduced, and the energy consumption can be saved by 25%.

As shown in fig. 1, fig. 2 and fig. 3, the full-stroke plunger piston type air conditioner further comprises a connecting rod 2, wherein the first crank 1201 drives the half-stroke plunger 3 to move through the connecting rod 2, and the second crank 1202 drives the full-stroke plunger 11 to move through the connecting rod 2.

Because the rotation of the crankshaft 1 is rotary motion, and the motion of the full-stroke plunger 11 and the motion of the half-stroke plunger 3 are linear motion, the connecting rod 2 is arranged, the crankshaft 1 is linked with the full-stroke plunger 11 and the half-stroke plunger 3 through the action of the connecting rod 2, and two ends of the connecting rod 2 are hinged and matched with the crankshaft 1 and the full-stroke plunger 11.

As shown in fig. 1, fig. 2 and fig. 3, the device further includes a liquid guide tube 1601 and a connector 15, the liquid guide tube 1601 and the connector 15 communicate with the full-stroke pump chamber 21 and the half-stroke pump chamber 20, and the second one-way valve 502 is connected to the connector 15 or the liquid guide tube 1601.

As shown in fig. 1, fig. 2 and fig. 3, the liquid discharging device further includes a liquid discharging pipe 1602, the first one-way valve and the third one-way valve are communicated through the liquid discharging pipe 1602, and a liquid discharging port 6 is disposed on the liquid discharging pipe 1602.

As shown in fig. 1, fig. 2 and fig. 3, the plunger-type full-stroke plunger piston pump further comprises a plunger stuffing box 10, the full-stroke pump cavity 21 and the half-stroke pump cavity 20 are both provided with the plunger stuffing box 10, and the full-stroke plunger piston 11 and the half-stroke plunger piston 3 are both in sliding fit with the plunger stuffing box 10.

As shown in fig. 1, fig. 2 and fig. 3, the variable frequency motor 19 is further included, and the variable frequency motor 19 drives the crankshaft 1 to rotate through the worm wheel 17 and the worm 18.

The variable frequency motor 19 and the worm wheel 17 and the worm 18 function to stably drive the crankshaft 1 to rotate and to reduce energy consumption to the maximum extent.

As shown in fig. 1, 2 and 3, the pump body is provided with a full-stroke pump head 7 and a half-stroke pump head 4, a half-stroke pump cavity 20 is arranged in the half-stroke pump head 4, and a full-stroke pump cavity 21 is arranged in the full-stroke pump head 7.

As shown in fig. 1, fig. 2 and fig. 3, a liquid inlet port 9 is arranged on the liquid inlet valve 8.

As shown in fig. 1, 2 and 3, the full-stroke pump chamber 21 includes a first through hole 13 and a second through hole 14, and the first through hole 13 is communicated with the second through hole 14; the half-stroke pump chamber 20 includes a first through hole 13 and a second through hole 14, and the first through hole 13 communicates with the second through hole 14. The first through hole 13 and the second through hole 14 are perpendicular to each other.

The first design that the first through hole 13 and the second through hole 14 are adopted for the full-stroke pump cavity 21 and the half-stroke pump cavity 20 is to facilitate the rapid installation of the first drain valve, the second drain valve, the third drain valve, the full-stroke plunger 11 and the half-stroke plunger 3; and secondly, the liquid can stably flow.

Referring to fig. 4, the operation of the advection measuring pump will be further described, when the full-stroke plunger 11 moves downward (based on the direction shown in fig. 4), the volume of the full-stroke pump cavity 21 increases, a negative pressure is generated, the second check valve 502 and the third check valve 503 are closed, the liquid inlet check valve 8 is opened, the liquid enters the full-stroke pump cavity 21, and the half-stroke pump head 4 is in the liquid discharge process. When the full stroke plunger 11 reaches the rear dead center, the pipetting process is completed.

Liquid drainage process of the advection metering pump:

when the full-stroke plunger 11 moves forward, the volume of the full-stroke pump cavity 21 is reduced, positive pressure is generated, the liquid inlet check valve 8 is closed at the moment, the third check valve 503 is opened, half of the liquid is discharged through the third check valve 503, the other half of the liquid is discharged through the second check valve 502 and enters the half-stroke pump cavity 20, and the half-stroke pump head 4 is in a liquid suction process at the moment. When the full-stroke plunger 11 runs to a front dead center, the liquid discharging process is finished;

the phase difference between the liquid inlet and outlet of the half-stroke pump body 4 and the full-stroke pump body 7 is 180 degrees, namely the liquid suction process of the full-stroke pump body 7, the liquid discharge process of the half-stroke pump body 4, the liquid discharge process of the full-stroke pump body 7 and the liquid suction process of the half-stroke pump body 4 are performed, the flow is mutually adjusted and supplemented, and the pulsation is smoothed. The black arrows in fig. 4 indicate the flow direction of the liquid.

The above only is the preferred embodiment of the present invention, not therefore the limitation of the patent protection scope of the present invention, all applications the equivalent transformation made by the content of the specification of the present invention, directly or indirectly applied to other related technical fields, all included in the protection scope of the present invention.

Claims

1. A advection measuring pump is characterized by comprising a pump body, a crankshaft, a half-stroke plunger and a full-stroke plunger;

2. The advection metering pump of claim 1, further comprising a connecting rod, wherein the first bell crank drives a half-stroke plunger to move through the connecting rod, and the second bell crank drives a full-stroke plunger to move through the connecting rod.

3. The advection metering pump of claim 1, further comprising a fluid conduit and a connector, said fluid conduit and connector communicating with said full-stroke pump chamber and half-stroke pump chamber, and a second one-way valve connected to said connector or to said fluid conduit.

4. The advection metering pump of claim 1, further comprising a drain, the first one-way valve and the third one-way valve being in communication via the drain, the drain having a drain port formed thereon.

5. The advection metering pump of claim 1, further comprising a plunger stuffing box, wherein the plunger stuffing box is disposed on both the full stroke pumping chamber and the half stroke pumping chamber, and wherein the full stroke plunger and the half stroke plunger are slidably engaged with the plunger stuffing box.

6. The advection metering pump of claim 1, further comprising a variable frequency motor, said variable frequency motor driving said crankshaft to rotate via a worm gear.

7. The advection metering pump of claim 1, wherein said pump body is provided with a full stroke pump head and a half stroke pump head, said half stroke pump chamber being provided within the half stroke pump head, said full stroke pump chamber being provided within the full stroke pump head.

8. The advection metering pump of claim 1, wherein said inlet valve is provided with an inlet port.

9. The advection metering pump of claim 1, wherein said full-stroke pump chamber comprises a first through-hole and a second through-hole, said first through-hole communicating with said second through-hole; the half-stroke pump cavity comprises a first through hole and a second through hole, and the first through hole is communicated with the second through hole.