CN214466280U - Magnetoelectric flow control valve - Google Patents

Abstract

The utility model provides a magnetoelectric flow control valve, including fixed frame, drive assembly, sensing assembly and moving valve body, form the runner between fixed frame and the moving valve body, be provided with the case on the moving valve body, the case can move between the first position and the second position under the driving assembly's driving and then can adjust the aperture of runner, the sensing assembly can export corresponding detected signal owing to the motion, the detected signal matches the aperture; wherein, when the primary importance, the runner is in the closed condition, when the second place, the runner is in the state of opening completely, the utility model discloses can utilize the magnetostrictive and the direct measuring valve's of piezoelectricity combined material output displacement and pressure that have accurate sensing function, need not extra sensor, simple structure is favorable to the miniaturized design of valve design.

Description

Magnetoelectric flow control valve

Technical Field

The utility model relates to a flow control technical field specifically, relates to a magnetoelectric flow control valve especially relates to a hydraulic control component that collects valve drive and sensing and detect function in an organic whole.

Background

With the development of miniature propulsion systems in aerospace, cell titration drug delivery in bioengineering, deep sea exploration and the like, the combination of new material technology, ultra-precise positioning technology and hydraulic technology to realize large-stroke high-precision driving is a trend of fluid control system development, so that higher requirements are provided for the precision and automation degree of a hydraulic valve for controlling flow. At present, the driving element of most control valves in China is an electromagnetic torque motor, the defects of large size, complex structure, low precision and the like exist, the traditional electromagnetic control valve can only realize two-position control and cannot be continuously adjusted, and therefore gear transformation is controlled by opening and closing actions of a plurality of electromagnetic valves together, and the requirements of high-speed and precision control cannot be met.

There are also numerous designs for control valves in the prior art, for example patent document CN1434217A discloses a piezo-actuated servo valve in which the position signal needs to be measured by an external displacement sensor; for another example, patent document CN103032296A discloses a piezoelectric stack pump based on a butterfly sensor valve, which measures the output pressure and flow rate of the valve through the butterfly sensor while the piezoelectric stack pumps liquid.

However, the piezoelectric valve provided by the design can only realize a single driving or sensing function, the two functions are not integrated, an independent sensor needs to be installed, the structure is not compact, and the valve volume and the structural complexity are increased.

SUMMERY OF THE UTILITY MODEL

To the defect among the prior art, the utility model aims at providing a magnetoelectric flow control valve.

According to the utility model, the magnetoelectric flow control valve comprises a fixed frame, a driving component, a sensing component and a movable valve body, wherein a flow passage is formed between the fixed frame and the movable valve body;

the movable valve body is provided with a valve core, the valve core can move between a first position and a second position under the driving of the driving assembly so as to adjust the opening degree of the flow channel, and the sensing assembly is connected with the valve core;

wherein, in the first position, the flow passage is in a closed state, and in the second position, the flow passage is in a fully open state.

Preferably, the driving mode of the driving component can adopt any one form of electromagnetic driving, magnetostriction driving, shape memory alloy driving, piezoelectric driving, fluid driving, motor driving and thermal expansion driving.

Preferably, the drive assembly is mounted on the fixed frame; the driving assembly comprises a first permanent magnet and a first electromagnetic coil, and the first electromagnetic coil is arranged along the circumferential direction of the first permanent magnet;

the valve core adopts a permanent magnet, the valve core and the first permanent magnet are respectively arranged on two sides of the flow channel, the opposite sides have opposite polarities, and the valve core can move between a first position and a second position under the driving of the first permanent magnet and the first electromagnetic coil.

Preferably, when the valve core moves, the movable valve body can move towards or away from the valve core under the driving of the valve core.

Preferably, the movable valve body can be driven by the valve core to translate or rotate.

Preferably, the sensing assembly includes a piezoelectric body and a magnetostrictive body, a second magnetic yoke is arranged on the movable valve body, the piezoelectric body and the magnetostrictive body are sequentially mounted on the second magnetic yoke, and an excitation coil is arranged in the circumferential direction of the magnetostrictive body;

and a first magnetic yoke is arranged on the fixed frame, and a second permanent magnet is arranged on the first magnetic yoke.

Preferably, the first magnetic yoke and the second magnetic yoke are both made of permalloy.

Preferably, the excitation coil is wound on a magnetostrictive body and provides a stable alternating magnetic field to the magnetostrictive body.

Preferably, the second permanent magnet forms a closed magnetic circuit between the first and second yokes, the magnetostrictive body being in the closed magnetic circuit during movement.

Preferably, the flow channel can be filled with liquid, gas or gas-liquid mixed fluid.

Compared with the prior art, the utility model discloses following beneficial effect has:

1. the utility model discloses can utilize the magnetostrictive that has the accurate sensing function and the output displacement and the pressure of piezoelectricity composite construction direct measurement valve, need not extra sensor, simple structure is favorable to the miniaturized design of valve.

2. The utility model discloses can be suitable for the real-time supervision in the pumping process of different media such as liquid, gas and gas-liquid mixture.

3. The utility model provides a driving method can adopt multiple forms such as electromagnetic drive, magnetostrictive drive, shape memory alloy drive, piezoelectric drive, and structural style is various, can be applicable to multiple application scene, and the practicality is strong.

4. The utility model discloses sensing sensitivity and measurement accuracy are high, and have high reliability.

5. The utility model provides a survey of velocity of flow and flow can be realized to the structure, and the practicality is strong.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

fig. 1 is the structural schematic diagram of the magnetoelectric flow control valve provided by the utility model.

Fig. 2 is a schematic structural diagram of the electromagnetic driving valve element of the magnetoelectric flow control valve provided by the present invention.

Fig. 3 is a schematic structural diagram of the magnetostrictive driving valve element of the magnetoelectric flow control valve according to the present invention.

Fig. 4 is a schematic structural diagram of the driving valve core of the shape memory alloy body of the magnetoelectric flow control valve provided by the present invention.

Fig. 5 is a schematic structural diagram of the piezoelectric self-sensing driving valve element of the magnetoelectric flow control valve provided by the present invention.

The figures show that:

fixed frame 1 first permanent magnet 9

Second permanent magnet 2 first electromagnetic coil 10

First yoke 3 flow channel 11

Sliding guide 4 shape memory alloy body 12

Second yoke 13 of piezoelectric body 5

Second electromagnetic coil 14 of magnetostrictive body 6

Elastic body 15 of exciting coil 7

Spool 8 piezoelectric strip 16

Detailed Description

The present invention will be described in detail with reference to the following embodiments. The following examples will assist those skilled in the art in further understanding the present invention, but are not intended to limit the invention in any way. It should be noted that various changes and modifications can be made by one skilled in the art without departing from the spirit of the invention. These all belong to the protection scope of the present invention.

Example 1:

aiming at the defects of poor accuracy of measurement and large occupied space of the existing flow control valve, the embodiment provides a magnetoelectric flow control valve, which comprises a fixed frame 1, a driving component, a sensing component and a movable valve body, wherein a flow channel 11 is formed between the fixed frame 1 and the movable valve body, the flow channel 11 can be a flow channel generated between the fixed frame 1 and the movable valve body due to structure arrangement, or can be a single-strand installation pipeline, when the pipeline is installed independently, the flow channel 11 preferably adopts a hose, the movable valve body is provided with a valve core 8, the valve core 8 can move between a first position and a second position under the driving of the driving component so as to adjust the opening degree of the flow channel 11, the sensing component can output corresponding detection signals due to the movement, and the detection signals are matched with the opening degree, the sensing assembly is connected to the valve element 8, wherein in the first position the flow channel 11 is in a closed state, and in the second position the flow channel 11 is in a fully open state.

Further, the driving mode of the driving assembly can adopt any one of electromagnetic driving, magnetostrictive driving, shape memory alloy driving, piezoelectric driving, fluid driving, motor driving and thermal expansion driving, the fluid driving can be hydraulic driving or air cylinder driving, and the magnetostrictive driving, the shape memory alloy driving and the piezoelectric driving modes directly control the valve core 8 to continuously move by changing the current, the temperature and the voltage of the exciting coil respectively.

The utility model discloses in runner 11 can let in liquid, gas or gas-liquid mixture fluid. The size of the sectional area of an opening of a flexible pipe is controlled by the movement of a movable valve body, a magnetoelectric frame generates synchronous displacement along with the movable valve body so as to change a magnetic field passing through a magnetoelectric material, under the action of the changed magnetic field, the displacement of the magnetoelectric frame and the movable valve body is determined according to the change of output voltage generated by a magnetoelectric effect, the speed of fluid flowing into a flow channel 11 at a valve port and the pressure of the pipe wall are determined by calibration, and finally the flow control target is realized.

Example 2:

this embodiment is a preferred embodiment of embodiment 1.

In this embodiment, a driving assembly is driven by an electromagnetic driving method, the driving assembly is mounted on the fixed frame 1, as shown in fig. 1 and fig. 2, the driving assembly includes a first permanent magnet 9 and a first electromagnetic coil 10, the first electromagnetic coil 10 is arranged along the circumferential direction of the first permanent magnet 9, the valve element 8 is made of a permanent magnet, the valve element 8 and the first permanent magnet 9 are respectively arranged on two sides of the flow passage 11, and opposite sides of the valve element 8 and the first electromagnetic coil 10 have opposite polarities, and the valve element 8 can move between a first position and a second position under the driving of the first permanent magnet 9 and the first electromagnetic coil 10.

Further, when the valve core 8 moves, the movable valve body can move towards or away from the valve core 8 under the driving of the valve core 8. In this embodiment, the movable valve body can be driven by the valve core 8 to move in a translational or rotational manner, where the translational movement may be rolling or sliding, for example, the sliding guide rails 4 disposed at two ends of the movable valve body, the movable valve body slides through the sliding guide rails 4 disposed at two ends, and for example, the rollers disposed at two ends of the movable valve body realize reciprocating movement through rolling.

And a composite magnetoelectric structure is further arranged in the movable valve body, the second permanent magnet 2 forms a closed magnetic circuit between the first magnetic yoke 3 and the second magnetic yoke 13, and the magnetostrictive body 6 is in the closed magnetic circuit in the process of following the movement of the valve core 8. The composite magnetoelectric structure comprises a piezoelectric body 5, a magnetostrictive body 6 and an excitation coil 7, wherein the excitation coil 7 is wound on the magnetostrictive body 6 and provides a stable alternating current magnetic field for the magnetostrictive body 6, the excitation coil 7 generates a magnetic field to enable the magnetostrictive body 6 to generate stress and strain, and the piezoelectric body 5 generates a voltage signal through the mechanical coupling action on the piezoelectric body 5.

Further, when the movable valve body is driven by the driving assembly to displace, the relative position between the fixed frame 1 and the valve core 8 changes, so that the magnetic field acting on the magnetostrictive body 6 changes, magnetostrictive strain related to displacement to be detected is generated, and finally, a voltage signal related to displacement d to be detected is generated on the piezoelectric body 5 due to the piezoelectric effect, so that the sensing and detecting functions are realized.

The movable valve body controls the sectional area of the hose in a hose extruding mode, so that the flow is controlled, the first permanent magnet 9 provides permanent magnetic attraction for the movable valve body, and the first electromagnetic coil 10 controls the mechanical movement of the movable valve body. In the process of reciprocating extrusion of the flexible pipe by the movable valve body, the function of the sensor is realized along with the change of the cross section area of the flexible pipe, the opening state of the corresponding flow valve and the generation of voltage signals on the piezoelectric sheet in the movable magneto-electronic frame; when the input fluid pressure is certain, the valve body is in different positions, the speed of the fluid flowing into the hose at the valve port and the pressure of the pipe wall have a certain proportional relation with the generated voltage value, and the output voltage signal can be used for calculating the flow rate of the fluid flowing into the hose and the pressure value at the side wall of the hose through calibration.

Specifically, the sensing assembly comprises a piezoelectric body 5 and a magnetostrictive body 6, a second magnetic yoke 13 is arranged on the movable valve body, the piezoelectric body 5 and the magnetostrictive body 6 are sequentially mounted on the second magnetic yoke 13, an excitation coil 7 is arranged in the circumferential direction of the magnetostrictive body 6, the excitation coil 7 is wound on the magnetostrictive body 6, the excitation coil 7 is electrified to provide a stable alternating current magnetic field for the magnetostrictive body 6 in the second magnetic yoke 13, a first magnetic yoke 3 is arranged on the fixed frame 1, a second permanent magnet 2 is mounted on the first magnetic yoke 3, and the first magnetic yoke 3 and the second magnetic yoke 13 are preferably made of permalloy.

Example 3:

this embodiment is a modification of embodiment 1.

In this embodiment, the driving assembly is driven by magnetostriction, as shown in fig. 3, the valve element 8 is made of a magnetostrictive material, the second electromagnetic coil 14 is arranged in the circumferential direction of the valve element 8, when the current of the second electromagnetic coil 14 changes, the magnetic field around the valve element 8 can be changed, and then the valve element 8 made of the magnetostrictive material can be driven to extend or shorten, so that the valve element 8 can move between the first position and the second position, the driving of the valve element 8 is realized, and the control valve switch control is further realized, meanwhile, the magnitude of the current passed through the second electromagnetic coil 14 determines the degree of deformation of the valve element 8, and therefore, the sensing of the movement displacement of the valve element 8 can also be obtained by detecting the current in the second electromagnetic coil 14.

Example 4:

this embodiment is still another modification of embodiment 1.

In this embodiment, the driving assembly is driven by a shape memory alloy body, as shown in fig. 4, the driving assembly is a shape memory alloy body 12, the end of the shape memory alloy body 12 is connected to the valve core 8, and when the temperature of the shape memory alloy body 12 is changed, the driving assembly can extend or shorten to drive the valve core 8 to move between a first position and a second position, so as to realize control valve switch control, wherein, due to the deformation of the shape memory alloy body 12, the resistance value changes, and by detecting the change of the resistance value of the shape memory alloy body 12, the sensing of the displacement of the movable valve body can be realized.

Example 5:

this embodiment is still another modification of embodiment 1.

In this embodiment, the driving assembly is driven by a piezoelectric material, as shown in fig. 5, the driving assembly includes an elastic body 15, and a first piezoelectric chain 17 and a second piezoelectric chain 18 disposed on two sides of the elastic body 15, two ends of the first piezoelectric chain 17 and the second piezoelectric chain 18 are both connected to two ends of the elastic body 15, the first piezoelectric chain 17 and the second piezoelectric chain 18 are both provided with a plurality of piezoelectric strips 16 connected in sequence, wherein the middle of the first piezoelectric chain 17 is fixed, the middle of the second piezoelectric chain 18 is connected to the valve core 8, when a control voltage is simultaneously applied to the piezoelectric strips 16 on the first piezoelectric chain 17 and the second piezoelectric chain 18, the piezoelectric strips 16 are extended to further extend the first piezoelectric chain 17 and the second piezoelectric chain 18, the elastic body 15 is driven by the two piezoelectric chains to deform synchronously to further move the valve core 8 to realize the on-off control of the control valve, and at the same time, there is a one-to-one matching relationship between the magnitude of the applied voltage and the magnitude of the displacement of the valve core 8, therefore, the displacement of the valve element 8 can be sensed by detecting the magnitude of the applied voltage.

Taking embodiment 2 as an example, the utility model discloses a theory of operation as follows:

as shown in fig. 1, a certain gap exists between the fixed frame 1 and the moving valve body, and the fixed frame 1 applies a bias magnetic field to the composite magnetoelectric structure (the piezoelectric body 5 and the magnetostrictive body 6) in the moving valve body.

The sensing assembly forms a closed magnetic circuit through the second permanent magnet 2, the first magnetic yoke 3 and the second magnetic yoke 13, and the closed magnetic circuit is indicated by black implementation arrows in fig. 1. The second permanent magnet 2 and the first magnetic yoke 3 are mainly used for applying a bias magnetic field to a composite magnetoelectric structure on the movable valve body, the piezoelectric body 5 and the magnetostrictive body 6 are sequentially arranged on the movable valve body, when the movable valve body moves to generate displacement d, the relative position between the fixed frame 1 and the movable valve body changes along with the displacement, and the magnetostrictive body 6 moves close to the second permanent magnet 2, so that the magnetic field applied to the magnetostrictive body 6 by the second permanent magnet 2 changes, when the movable valve body moves, the magnetostrictive body 6 generates magnetostrictive strain related to displacement to be detected due to the change of the surrounding magnetic field, so that the magnetostrictive body extends or shortens, a voltage signal related to the displacement d to be detected is generated by the piezoelectric body 5 due to the piezoelectric effect, and finally a voltage signal V to be detected is generated on the piezoelectric sheet, so that a sensing function is realized.

A first permanent magnet 9 in the driving assembly provides permanent magnetic attraction for the valve core 8, and a first electromagnetic coil 10 controls the mechanical movement of the valve core 8. When the electromagnetic valve works, when the first electromagnetic coil 10 has no current passing through, the valve core 8 is attracted to the same side by the first permanent magnet 9, and the valve is in a closed state; when the first electromagnetic coil 10 is energized, the first electromagnetic coil 10 generates a magnetic field in a direction opposite to that of the first permanent magnet 9 so as to control the movement of the valve element 8, thereby realizing a driving function.

In the description of the present application, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience in describing the present application and simplifying the description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present application.

The foregoing description of the specific embodiments of the invention has been presented. It is to be understood that the present invention is not limited to the specific embodiments described above, and that various changes or modifications may be made by those skilled in the art within the scope of the appended claims without departing from the spirit of the invention. The embodiments and features of the embodiments of the present application may be combined with each other arbitrarily without conflict.

Claims (10)

1. The magnetoelectric flow control valve is characterized by comprising a fixed frame (1), a driving assembly, a sensing assembly and a movable valve body, wherein a flow channel (11) is formed between the fixed frame (1) and the movable valve body;

a valve core (8) is arranged on the movable valve body, the valve core (8) can move between a first position and a second position under the driving of the driving assembly so as to adjust the opening degree of the flow passage (11), and the sensing assembly is connected with the valve core (8);

wherein in the first position the flow channel (11) is in a closed state and in the second position the flow channel (11) is in a fully open state.

2. The magnetoelectric flow control valve according to claim 1, wherein the driving mode of the driving component can adopt any one of electromagnetic driving, magnetostrictive driving, shape memory alloy driving, piezoelectric driving, fluid driving, motor driving and thermal expansion driving.

3. Magneto-electric flow control valve according to claim 1, characterized in that the drive assembly is mounted on the fixed frame (1); the driving assembly comprises a first permanent magnet (9) and a first electromagnetic coil (10), wherein the first electromagnetic coil (10) is arranged along the circumferential direction of the first permanent magnet (9);

the permanent magnet is adopted by the valve core (8), the valve core (8) and the first permanent magnet (9) are respectively arranged on two sides of the flow channel (11), the opposite sides of the two sides attract each other in polarity, and the valve core (8) can move between a first position and a second position under the driving of the first permanent magnet (9) and the first electromagnetic coil (10).

4. The magnetoelectric flow control valve according to claim 3, characterized in that when the valve core (8) moves, the moving valve body can move towards or away from the valve core (8) under the driving of the valve core (8).

5. The magnetoelectric flow control valve according to claim 4, characterized in that the moving valve body can be driven by the valve core (8) to translate or rotate.

6. The magnetoelectric flow control valve according to claim 1, wherein the sensing assembly comprises a piezoelectric body (5) and a magnetostrictive body (6), a second magnetic yoke (13) is arranged on the movable valve body, the piezoelectric body (5) and the magnetostrictive body (6) are sequentially mounted on the second magnetic yoke (13), and an exciting coil (7) is arranged on the circumference of the magnetostrictive body (6);

the fixed frame (1) is provided with a first magnetic yoke (3), and a second permanent magnet (2) is mounted on the first magnetic yoke (3).

7. The magnetoelectric flow control valve according to claim 6, wherein the first yoke (3) and the second yoke (13) are both made of permalloy.

8. The magnetoelectric flow control valve according to claim 6, characterized in that the exciting coil (7) is wound on a magnetostrictive body (6) and provides a stable alternating current magnetic field to the magnetostrictive body (6).

9. The magnetoelectric flow control valve according to claim 6, characterized in that the second permanent magnet (2) forms a closed magnetic circuit between the first yoke (3) and the second yoke (13), in which closed magnetic circuit the magnetostrictive body (6) moves.

10. The magnetoelectric flow control valve according to claim 1, wherein the flow channel (11) is capable of introducing liquid, gas or gas-liquid mixed fluid.

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