CN112473409A

CN112473409A - Rapid controllable proportion liquid mixing equipment and operation method thereof

Info

Publication number: CN112473409A
Application number: CN202011126015.4A
Authority: CN
Inventors: 谢石辉; 彭俊吉; 范名扬; 管伟
Original assignee: Hunan Guangsi Technology Co ltd
Current assignee: Hunan Guangsi Technology Co ltd
Priority date: 2020-10-20
Filing date: 2020-10-20
Publication date: 2021-03-12

Abstract

The invention provides a rapid controllable proportion liquid mixing device and an operation method thereof. The rapid controllable proportion liquid mixing equipment comprises a first stock solution container, a second stock solution container, a liquid mixing container, a first mixing cylinder, a second mixing cylinder, a first piston, a second piston, a displacement sensor and a connecting rod; and connecting the pipeline and the first valve to the seventh valve. The operation method of the rapid controllable proportion liquid mixing equipment comprises the steps of initial preparation, liquid filling, filling condition switching, liquid adding mixing, mixed liquid emptying and initial state returning. The rapid controllable proportion liquid mixing equipment and the operation method thereof provided by the invention solve the technical problems of poor precision or high implementation cost of a liquid flow control mode in the prior art.

Description

Rapid controllable proportion liquid mixing equipment and operation method thereof

Technical Field

The invention relates to the field of flow control, in particular to a quick controllable proportion liquid mixing device and an operation method thereof.

Background

At present, when liquids are mixed according to a proportion, the liquids are mixed by a method that each liquid is input according to flow control, and the flow control is most commonly carried out by adopting a mode of installing a flowmeter. When liquid flows through the flowmeter, a pulse signal is output, and the volume of the liquid can be calculated by capturing and accumulating the pulse signal. When the method is used, a flowmeter and a control valve are required to be installed on an outflow pipeline of each liquid, when the method is used, the control valve is opened firstly, the liquid flows through the flowmeter, pulse signals are output outwards, the control valve is closed when the pulses of the flowmeter are detected and accumulated to calculate the number of the specified liquid volumes, and the outflow part of the liquid is the liquid volume needing liquid mixing.

The method of using a flow meter to mix liquids has two drawbacks: the accuracy of the volume measurement of the liquid flow is limited by the flowmeter itself; the liquid flowing in and out is required to be in a certain pressure difference range, the flowmeter cannot work normally when the pressure difference is too small, and the accurate measurement cannot be carried out when the pressure difference is too large. In addition, because the precision of a common flowmeter is not high, only a mass flowmeter can be adopted for realizing accurate control with high precision, but the price of the mass flowmeter is more than 10 times that of a common volume flowmeter. And the liquids that need to be mixed each need to be pressurized, which is costly to implement.

Disclosure of Invention

In order to solve the technical problems of poor precision or high implementation cost of a liquid flow control mode in the prior art, the invention provides the quick controllable proportional liquid mixing equipment for realizing high-precision liquid flow control according to lower cost and the operation method thereof.

A quick controllable proportion liquid mixing device comprises a first stock solution container, a second stock solution container, a liquid mixing container, a first mixing cylinder, a second mixing cylinder, a first piston, a second piston, a displacement sensor and a connecting rod; and connecting the pipeline and the first valve to the seventh valve.

The first mixing cylinder and the second mixing cylinder are both cylindrical cylinder bodies, one end of the first mixing cylinder is sealed, one end of the first mixing cylinder is open, two ends of the second mixing cylinder are sealed, and the lengths of the inner spaces of the first mixing cylinder and the second mixing cylinder are the same. The first mixing cylinder and the second mixing cylinder are coaxially arranged, and the open end of the first mixing cylinder faces the second mixing cylinder.

The first piston and the second piston are respectively arranged in the first mixing cylinder and the second mixing cylinder at an angle parallel to the end faces of the first mixing cylinder and the second mixing cylinder, and can slide along the axial direction in a sealing manner, and the sliding strokes of the first piston and the second piston are the same. The distance between the first mixing cylinder and the second mixing cylinder is larger than or equal to the stroke of the displacement sensor, and the stroke of the displacement sensor is larger than or equal to the stroke of the first piston and the stroke of the second piston.

The length of the connecting rod is equal to the distance between the first mixing cylinder and the second mixing cylinder; the connecting rod is parallel to the axial direction of the first mixing cylinder and the second mixing cylinder, one end of the connecting rod extends into the first mixing cylinder to be connected with the first piston, and the other end of the connecting rod penetrates through the end face of the second mixing cylinder in a sealing mode to be connected with the second piston. A branch is derived from the middle position of the connecting rod and connected with the sensing end of the displacement sensor, and the branch does not contact with the first mixing cylinder and the second mixing cylinder during movement.

The first stock solution container is communicated with one end of the first mixing cylinder, which is far away from the connecting rod, one end of the second mixing cylinder, which is close to the connecting rod, and one end of the second mixing cylinder, which is far away from the connecting rod through pipelines, and is respectively provided with a first valve, a third valve and a fourth valve; the second stock solution container is communicated with one end, close to the connecting rod, of the second mixing cylinder through a pipeline and is provided with a second valve; the liquid mixing container is communicated with one end, far away from the connecting rod, of the first mixing cylinder, one end, close to the connecting rod, of the second mixing cylinder and one end, far away from the connecting rod, of the second mixing cylinder through pipelines, and is respectively provided with a fifth valve, a sixth valve and a seventh valve.

The axial direction of the first mixing cylinder and the second mixing cylinder is horizontal, and the height of the first mixing cylinder and the second mixing cylinder is positioned below the first stock solution container and the second stock solution container and above the mixing container; the pressure of the liquid in the first stock solution container can push the first piston and the second piston.

In a preferred embodiment of the rapid and controllable proportion liquid mixing device provided by the invention, the first valve, the second valve, the seventh valve and the fourth valve are all solenoid valves.

The operation method of the rapid controllable proportion liquid mixing equipment comprises the following steps:

step one, initial preparation:

more liquid is used in the filling and mixing process of the first stock solution container, and the cross-sectional area of the inner space is marked as S_AThe second stock solution container is filled with less liquid in the mixing process, and the cross-sectional area of the inner space is marked as S_B(ii) a And the second mixing cylinder is filled with the liquid in the first stock solution container.

The first piston moves to one end far away from the second mixing cylinder and is marked as a left end, and the sensing ends of the second piston and the displacement sensor synchronously move to the corresponding left end along with the connecting rod and are marked as initial positions at the moment.

The strokes of the first piston and the second piston are marked as L, and the displacement of the sensing end of the displacement sensor from the initial position to the right is marked as L_S(ii) a The first valve to the seventh valve are all closed.

Step two, filling liquid:

opening the first valve, the second valve, the seventh valve; the liquid in the first stock solution container flows to the left end of the first mixing cylinder through the first valve to push the first piston to move rightwards; the second piston is driven to move rightwards, and the liquid in the second stock solution container is pumped to the left end of the second mixing cylinder through the second valve; and liquid at the right end of the second mixing cylinder is discharged to the liquid mixing container through the seventh valve.

Step three, switching filling conditions:

L_Spresetting according to the liquid mixing proportion, and when the reading of the displacement sensor is L_SAnd when the second valve is closed, the third valve is opened, namely the liquid in the first stock solution container is pumped to the left end of the second mixing cylinder through the third valve, and the rest of the liquid is unchanged.

Step four, mixing and adding liquid:

when the first piston and the second piston move to the rightmost end, all valves are closed; at this time, the left end in the first mixing cylinder is filled with the liquid in the first stock solution container, and the left end in the second mixing cylinder is filled with the mixed liquid, and the proportion can be L_SAnd (4) determining.

Step five, emptying the mixed solution:

opening the fourth valve, the fifth valve, the sixth valve; the liquid in the first stock solution container flows to the right end of the second mixing cylinder through the fourth valve, the second piston is pushed to move leftwards, and the mixed liquid at the left end of the second mixing cylinder is discharged to the mixed solution container through the sixth valve; the first piston is driven to move leftwards, and the liquid at the left end of the first mixing cylinder flows to the liquid mixing container through the fifth valve.

Step six, restoring the initial state:

when the first piston and the second piston move to the leftmost end, all valves are closed, and the initial state is recovered; and obtaining mixed liquid in the liquid mixing container.

Step III, L_SThe value of (A) is related to the ratio of the two stock solutions, and the calculation formula is as follows:

。

in the calculation formula (S)_A/S_B) +2 is a constant and is modified by replacing the first mixing cylinder and the second mixing cylinder with different sizes. Can be according to V₁/V₂To avoid L/L_SToo large, thereby ensuring the precision of liquid mixing.

Compared with the prior art, the piston cylinder, the electromagnetic valve and other parts adopted by the rapid controllable proportion liquid mixing equipment are common products in the market, the piston is pushed to move back and forth by the pressure of liquid, an electric pushing device is not needed, the height of a liquid container is slightly increased, and high-precision liquid mixing is realized by a very simple structure and extremely low cost.

Compared with the prior art, the rapid controllable proportion liquid mixing equipment provided by the invention realizes liquid mixing by a method of setting a fixed volume without dynamic metering and calculation, so that high precision can be obtained and the consistency is good; the method is very convenient for preparing the mixed solution with equal weight.

Drawings

FIG. 1 is a schematic structural diagram of a rapid controllable ratio liquid mixing device.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Fig. 1 is a schematic structural diagram of a rapid controllable ratio liquid mixing apparatus 1 according to the present invention. The quick controllable proportion liquid mixing equipment 1 comprises a first stock solution container C, a second stock solution container D, a liquid mixing container E, a first mixing cylinder A, a second mixing cylinder B, a first piston A1, a second piston B1, a displacement sensor F and a connecting rod G; solenoid valves k1 to k 7.

The first mixing cylinder A and the second mixing cylinder B are both cylindrical cylinder bodies, the left end of the first mixing cylinder A is sealed, the right end of the first mixing cylinder A is open, and the two ends of the second mixing cylinder B are sealed. The diameter of the inner space of the first mixing cylinder A is twice that of the second mixing cylinder B, and the lengths of the inner spaces are the same. The first mixing cylinder A and the second mixing cylinder B are coaxially arranged, and the open end of the first mixing cylinder A faces the second mixing cylinder B.

The first piston A1 and the second piston B1 are respectively arranged in the first mixing cylinder A and the second mixing cylinder B at an angle parallel to the end faces of the first mixing cylinder A and the second mixing cylinder B, and can slide along the axial direction of the first mixing cylinder A and the second mixing cylinder B in a sealing way, and the slidable strokes of the first piston A1 and the second piston B in the cylinders are the same. The distance between the first mixing cylinder A and the second mixing cylinder B is larger than the stroke of the displacement sensor F, and the stroke of the displacement sensor F is equal to the stroke of the first piston A1 and the second piston B1.

The length of the connecting rod G is equal to the distance between the first mixing cylinder A and the second mixing cylinder B; the connecting rod G is parallel to the axial direction of the first mixing cylinder A and the second mixing cylinder B, one end of the connecting rod G extends into the first mixing cylinder A and is connected with the first piston A1, and the other end of the connecting rod G hermetically penetrates through the end face of the second mixing cylinder B and is connected with the second piston B1. A branch G1 is derived from the middle position of the connecting rod G and is connected with the sensing end of the displacement sensor F, and the branch G1 does not contact with the first mixing cylinder A and the second mixing cylinder B during movement.

The first stock solution container C is communicated with the left end of the first mixing cylinder A, the left end of the second mixing cylinder B and the right end of the second mixing cylinder B through pipelines, and is respectively provided with an electromagnetic valve K1, an electromagnetic valve K3 and an electromagnetic valve K4.

The second stock solution container D is communicated with the left end of the second mixing cylinder B through a pipeline and is provided with an electromagnetic valve K2; the liquid mixing container E is communicated with the left end of the first mixing cylinder A, the left end of the second mixing cylinder B and the right end of the second mixing cylinder B through pipelines, and is respectively provided with an electromagnetic valve K5, an electromagnetic valve K6 and an electromagnetic valve K7.

The first stock solution container C is higher than the second stock solution container D, higher than the first mixing cylinder A and the second mixing cylinder B and higher than the mixing container E. The specific height is based on the ability to smoothly push the first piston a1 and the second piston B1.

The operation method of the rapid controllable proportion liquid mixing equipment 1 is as follows:

step one, initial preparation:

more liquid is used in the filling and mixing process of the first stock solution container C, and the cross-sectional area of the inner space is marked as S_AThe second stock solution container D uses less liquid in the filling and mixing process, and the cross-sectional area of the inner space is marked as S_B(ii) a The second mixing cylinder B is filled with the liquid in the first stock solution container C.

The first piston a1 moves to the left, and the second piston B1, the sensing end of the displacement sensor F, and the connecting rod G move synchronously to the left, which is marked as the initial position. The first activityThe stroke of the plug A1 and the second piston B1 is marked as L, and the displacement amount of the sensing end of the displacement sensor F from the initial position to the right is marked as L_S。

The electromagnetic valves K1-K7 are all closed.

Step two, filling liquid:

opening an electromagnetic valve K1, an electromagnetic valve K2 and an electromagnetic valve K7; the liquid in the first stock solution container C flows to the left end of the first mixing cylinder A through a solenoid valve K1, and pushes the first piston A1 to move to the right; the second piston B1 is driven to move rightwards, and the liquid in the second stock solution container D is pumped to the left end of the second mixing cylinder B through an electromagnetic valve K2; and the liquid at the right end of the second mixing cylinder B is discharged to the liquid mixing container E through an electromagnetic valve K7.

Step three, switching filling conditions:

L_Spreset (1/2) to L when the displacement sensor reads L_SWhen the electromagnetic valve K2 is closed, the electromagnetic valve K3 is opened, namely the liquid in the first stock solution container C is pumped to the left end of the second mixing cylinder B through the electromagnetic valve K3, and the rest is unchanged.

Step four, mixing and adding liquid:

when the first piston A1 and the second piston B1 both move to the rightmost end, all electromagnetic valves are closed; at this time, the left end of the first mixing cylinder a is filled with the liquid in the first raw liquid container C, and the left end of the second mixing cylinder B is filled with the mixed liquid.

Step five, emptying the mixed solution:

opening an electromagnetic valve K4, an electromagnetic valve K5 and an electromagnetic valve K6; the liquid in the first stock solution container C flows to the right end of the second mixing cylinder B through a solenoid valve K4, the second piston B1 is pushed to move leftwards, and the mixed liquid at the left end of the second mixing cylinder B is discharged to the mixed solution container E through a solenoid valve K6; the first piston A1 is driven to move leftwards, and the liquid at the left end of the first mixing cylinder B flows to the liquid mixing container E through a solenoid valve K5.

Step six, restoring the initial state:

when the first piston A1 and the second piston B1 both move to the leftmost end, all the electromagnetic valves are closed, and the initial state is restored.

The mixed liquid is obtained in the liquid mixing container E due to the preset L_SL (1/2), the diameter of the inner space of the first mixing cylinder A is two times that of the second mixing cylinder B, namely S_A/S_B4/1, according to the formula:

calculated V₁/V₂Is 11/1. The specific derivation process of the calculation formula is as follows:

due to the first mixing cylinder A and the second mixing cylinder BThe size is determined, in the formula (S)_A/S_B) +2 is a constant and is modified by replacing the first mixing cylinder and the second mixing cylinder with different sizes. Can be according to V in the actual using process₁/V₂To avoid L/L_SToo large, thereby ensuring the precision of liquid mixing.

If so (S)_A/S_B) +2=3, preparation V₁/V₂A mixed liquid of 2/1, then L_S=L；

Preparation of V₁/V₂A mixed liquid of =10/1, then L_S=（1/3）L；

When required to make V₁/V₂In the case of the mixed liquid of =30/1, the liquid is used as it is (S)_A/S_B) A structure of +2=3, leads to L_S= (3/31) L, accuracy is difficult to guarantee;

to adopt (S)_A/S_B) +2=10, then L_S=（10/31）L。

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by the present specification, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. The utility model provides a quick controllable proportion liquid mixing equipment, includes first stoste container, second stoste container, mixes liquid container, its characterized in that: the device also comprises a first mixing cylinder, a second mixing cylinder, a first piston, a second piston, a displacement sensor and a connecting rod; the first mixing cylinder and the second mixing cylinder are respectively provided with the first piston and the second piston which can slide in a sealing manner, and the sliding directions of the first piston and the second piston and the telescopic direction of the displacement sensor are parallel; the connecting rod is simultaneously connected with the first piston, the second piston and the sensing end of the displacement sensor; the first stock solution container is communicated with one end of the first mixing cylinder, which is far away from the connecting rod, one end of the second mixing cylinder, which is close to the connecting rod, and one end of the second mixing cylinder, which is far away from the connecting rod through pipelines, and is respectively provided with a first valve, a third valve and a fourth valve; the second stock solution container is communicated with one end, close to the connecting rod, of the second mixing cylinder through a pipeline and is provided with a second valve; the liquid mixing container is communicated with one end, far away from the connecting rod, of the first mixing cylinder, one end, close to the connecting rod, of the second mixing cylinder and one end, far away from the connecting rod, of the second mixing cylinder through pipelines, and is respectively provided with a fifth valve, a sixth valve and a seventh valve.

2. The rapid controllable proportion liquid mixing apparatus according to claim 1, wherein: the first mixing cylinder and the second mixing cylinder are both cylindrical cylinder bodies, one end of the first mixing cylinder is sealed, one end of the first mixing cylinder is open, two ends of the second mixing cylinder are sealed, and the first piston and the second piston are arranged in the first mixing cylinder and the second mixing cylinder respectively at an angle parallel to the end faces of the first mixing cylinder and the second mixing cylinder.

3. The rapid controllable proportion mixing apparatus according to claim 2, wherein: the length of the first mixing cylinder inner space is equal to the length of the second mixing cylinder inner space, namely the strokes of the first piston and the second piston are the same.

4. The rapid controllable proportion mixing apparatus of claim 3, wherein: the first mixing cylinder and the second mixing cylinder are coaxially arranged, the distance between the first mixing cylinder and the second mixing cylinder is larger than or equal to the stroke of the displacement sensor, and the open end of the first mixing cylinder faces the second mixing cylinder.

5. The rapid controllable proportion mixing apparatus according to claim 4, wherein: the length of the connecting rod is equal to the distance between the first mixing cylinder and the second mixing cylinder; the connecting rod is parallel to the axial direction of the first mixing cylinder and the second mixing cylinder, one end of the connecting rod extends into the first mixing cylinder and is connected with the first piston, and the other end of the connecting rod penetrates through the end face of the second mixing cylinder in a sealing mode and is connected with the second piston.

6. The rapid controllable proportion mixing apparatus according to claim 4, wherein: the stroke of the displacement sensor is greater than or equal to the stroke of the first piston and the stroke of the second piston; a branch is derived from the middle position of the connecting rod and connected with the sensing end of the displacement sensor, and the branch does not contact with the first mixing cylinder and the second mixing cylinder during movement.

7. The rapid controllable proportion mixing apparatus according to claim 4, wherein: the axial direction of the first mixing cylinder and the second mixing cylinder is horizontal, and the height of the first mixing cylinder and the second mixing cylinder is positioned below the first stock solution container and the second stock solution container and above the mixing container; the pressure of the liquid in the first stock solution container can push the first piston and the second piston.

8. The rapid controllable proportion liquid mixing equipment according to any one of claims 1 to 7, wherein the operation method of the rapid controllable proportion liquid mixing equipment is as follows:

the method comprises the following steps:

more liquid is used in the filling and mixing process of the first stock solution container, and the cross-sectional area of the inner space is marked as S_AThe second stock solution container is filled with less liquid in the mixing process, and the cross-sectional area of the inner space is marked as S_B(ii) a The second mixing cylinder is filled with the liquid in the first stock solution container; the first piston moves to one end far away from the second mixing cylinder and is marked as a left end, and the sensing ends of the second piston and the displacement sensor synchronously move to the corresponding left end along with the connecting rod and are marked as initial positions at the moment; the strokes of the first piston and the second piston are marked as L, and the displacement of the sensing end of the displacement sensor from the initial position to the right is marked as L_S(ii) a The first valve to the seventh valve are all closed;

step two:

opening the first valve, the second valve, the seventh valve; the liquid in the first stock solution container flows to the left end of the first mixing cylinder through the first valve to push the first piston to move rightwards; the second piston is driven to move rightwards, and the liquid in the second stock solution container is pumped to the left end of the second mixing cylinder through the second valve; the liquid at the right end of the second mixing cylinder is discharged to the liquid mixing container through the seventh valve;

step three:

L_Spresetting according to the liquid mixing proportion, and when the reading of the displacement sensor is L_SWhen the second valve is closed, the third valve is opened, namely the liquid in the first stock solution container is pumped to the left end of the second mixing cylinder through the third valve, and the rest of the liquid is unchanged;

step four:

when the first piston and the second piston move to the rightmost end, all valves are closed; at this time, the left end in the first mixing cylinder is filled with the liquid in the first stock solution container, and the left end in the second mixing cylinder is filled with the mixed liquid, and the proportion can be L_SDetermining;

step five:

opening the fourth valve, the fifth valve, the sixth valve; the liquid in the first stock solution container flows to the right end of the second mixing cylinder through the fourth valve, the second piston is pushed to move leftwards, and the mixed liquid at the left end of the second mixing cylinder is discharged to the mixed solution container through the sixth valve; the first piston is driven to move leftwards, and the liquid at the left end of the second mixing cylinder flows to the liquid mixing container through the fifth valve;

step six:

9. The rapid controllable ratio mixing apparatus according to claim 8, wherein: the liquid in the first stock solution container and the liquid in the second stock solution container are inThe volumes in the liquid mixing containers are respectively marked as V₁、V₂The formula for calculating the ratio of the two is as follows:

。

10. the rapid controllable ratio mixing apparatus according to claim 9, wherein: in the calculation formula (S)_A/S_B) +2 is a constant number which follows V₁/V₂And (4) adjusting the size.