CN212417987U - Liquid metal micro-fluidic mixing arrangement - Google Patents

Abstract

A liquid metal micro-fluidic mixing device belongs to the technical field of micro-fluidic. All the microfluidic film layers are stacked, a microelectrode device layer or a micro-magnetic device layer is arranged between every two adjacent microfluidic film layers, and a mixed liquid outlet, a micro-mixing cavity, a spiral track, a liquid sample inlet and at least two micro-channels are arranged on each microfluidic film layer; the spiral tracks are arranged in the micro-mixing cavity, the micro-channels are communicated with the micro-mixing cavity, one micro-channel is provided with a mixed liquid outlet, the rest micro-channels are provided with liquid sample inlets, liquid metal is arranged in each spiral track, and the mixed liquid outlet of the upper micro-fluidic thin film layer is connected with one liquid sample inlet of the lower micro-fluidic thin film layer adjacent to the mixed liquid outlet; the utility model discloses utilize the cyclic motion of liquid metal in predetermined spiral track, realize the flash mixed of liquid sample. The utility model is used for liquid metal micro-fluidic mixes.

Description

Liquid metal micro-fluidic mixing arrangement

Technical Field

The utility model belongs to the technical field of it is micro-fluidic, concretely relates to liquid metal micro-fluidic mixing arrangement.

Background

Liquid mixing is a physical process that is often required to be accomplished in the biomedical field, and the mixing efficiency and mixing effect are directly related to the mixing method adopted. With the development of microfluidic chip laboratories, there are more and more extensive demands and applications for realizing micro-liquid mixing at a micro-scale (usually <1mm) by using a microfluidic technology. At present, the mixing modes of liquid samples at microscale are mainly divided into two main categories: an active mixing mode and a passive mixing mode. In the passive mixing mode, the liquid flow speed is slow (mainly laminar flow) at the micro-scale, so that the mixing efficiency is low, and the improved passive mixing device generally has a complex structural design. The active mixing method is to mix the liquid sample by external force in a certain micro-scale range, and the active mixing methods commonly used at present mainly include stirring type, magnetic bead type, electroosmosis driving type, etc., but these mixing methods have some disadvantages: the adopted external components are easy to generate chemical reaction with the liquid to be mixed, so that liquid pollution is caused; the adopted moving parts are fixed in shape, mixing dead zones are easily generated in the moving process, the mixing effect is reduced, and the controllability of the moving track is poor; the system needs high power voltage and large volume, and is not convenient for integration, popularization and application of the microfluidic system.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the problems that the prior micro-fluidic mixing device is easy to pollute, easily forms dead zones, has poor controllability and high energy consumption, is inconvenient to integrate and the like, and providing the liquid metal micro-fluidic mixing device.

In order to achieve the purpose, the utility model adopts the technical proposal that:

a liquid metal micro-fluidic mixing device comprises at least two micro-fluidic thin film layers and at least one microelectrode device layer or at least one micro-magnetic pole device layer, wherein all the micro-fluidic thin film layers are tiled and stacked up and down, one microelectrode device layer or one micro-magnetic pole device layer is arranged between every two adjacent micro-fluidic thin film layers, and the upper surface of each micro-fluidic thin film layer is provided with a mixed liquid outlet, a micro-mixing cavity, a spiral track, at least one liquid sample inlet and at least two micro-channels; the spiral tracks are arranged in the micro-mixing cavities, all the micro-channels of each micro-fluidic thin film layer are communicated with the micro-mixing cavities of the micro-fluidic thin film layers, the mixed liquid outlet is vertically arranged on one micro-channel, the liquid sample inlets are vertically arranged on the rest micro-channels, liquid metal is arranged in the spiral track of each micro-fluidic thin film layer and moves along the spiral track, and the mixed liquid outlet of the micro-fluidic thin film layer positioned above is connected with one liquid sample inlet of the micro-fluidic thin film layer positioned below and adjacent to the mixed liquid outlet;

the positive poles of the electrodes in all the microelectrode device layers are vertically aligned with the centers of all the spiral tracks, and the negative poles of the electrodes in all the microelectrode device layers are vertically aligned with the inlets of all the spiral tracks; or one of the two magnetic poles of the built-in electromagnets of all the micro-magnetic pole device layers is vertically aligned with the center of all the spiral tracks, and the other magnetic pole of the built-in electromagnets of all the micro-magnetic pole device layers is vertically aligned with the entrance of all the spiral tracks.

The utility model discloses beneficial effect for prior art is: the utility model provides a liquid metal micro-fluidic mixing arrangement utilizes the liquid metal at the cyclic motion of predetermineeing spiral track in, realizes the flash mixed of liquid sample. The liquid metal has stable characteristics, is not easy to generate chemical reaction with a liquid sample to be mixed to cause sample pollution, and has no influence even if the phase state of the liquid metal is changed due to the temperature; the liquid metal is not limited by the shape and the size of the track, the shape of the liquid metal can be changed along with the change of the shape and the size of the track, a mixing dead zone is not easy to generate in the motion, and the mixing effect can be effectively improved; the strength and polarity of the electric field or the magnetic field are changed, the movement speed and the movement track of the liquid metal can be changed, and the system controllability is high; the voltage of an electric field for driving the liquid metal to move is direct current voltage, the minimum voltage is only 3-5V, the energy consumption is low, the size is small, and the integration with other microfluidic systems is facilitated; and the shape of the spiral track can be changed according to the mixing requirement and the spiral track can be quickly formed, so that the cost is low, and the spiral track can be quickly and conveniently manufactured.

Drawings

FIG. 1 is an isometric view of a liquid metal microfluidic mixing device of example 1;

FIG. 2 is a left side view of a liquid metal microfluidic mixing device of example 1;

FIG. 3 is a top view of a first microfluidic thin film layer in example 1;

fig. 4 is a top view of a second microfluidic thin film layer in example 1.

The names and reference numbers of the components referred to in the above figures are as follows:

the micro-electrode device comprises a first micro-fluidic thin film layer 1, a first liquid sample inlet 1-1, a first liquid metal 1-2, a first mixed liquid outlet 1-3, a first micro-channel 1-4, a first micro-mixing cavity 1-5, a first spiral track 1-6, a micro-electrode device layer 2, a second micro-fluidic thin film layer 3, a second liquid sample inlet 3-1, a second liquid metal 3-2, a second mixed liquid outlet 3-3, a second micro-channel 3-4, a second micro-mixing cavity 3-5 and a second spiral track 3-6.

Detailed Description

The first embodiment is as follows: the embodiment discloses a liquid metal microfluidic mixing device, which comprises at least two microfluidic film layers and at least one microelectrode device layer 2 or at least one micro-magnetic pole device layer, wherein all the microfluidic film layers are tiled and stacked up and down, one microelectrode device layer 2 or one micro-magnetic pole device layer is arranged between every two adjacent microfluidic film layers, and the upper surface of each microfluidic film layer is provided with a mixed liquid outlet, a micro-mixing cavity, a spiral track, at least one liquid sample inlet and at least two micro-channels; the spiral tracks are arranged in the micro-mixing cavities, all the micro-channels of each micro-fluidic thin film layer are communicated with the micro-mixing cavities of the micro-fluidic thin film layers, the mixed liquid outlet is vertically arranged on one micro-channel, the liquid sample inlets are vertically arranged on the rest micro-channels, liquid metal is arranged in the spiral track of each micro-fluidic thin film layer and moves along the spiral track, and the mixed liquid outlet of the micro-fluidic thin film layer positioned above is connected with one liquid sample inlet of the micro-fluidic thin film layer positioned below and adjacent to the mixed liquid outlet;

the positive poles of the electrodes in all the microelectrode device layers 2 are vertically aligned with the centers of all the spiral tracks, and the negative poles of the electrodes in all the microelectrode device layers 2 are vertically aligned with the inlets of all the spiral tracks; or one of the two magnetic poles of the built-in electromagnets of all the micro magnetic pole device layers is vertically aligned with the centers of all the spiral tracks, and the other magnetic pole of the built-in electromagnets of all the micro magnetic pole device layers is vertically aligned with the inlets of all the spiral tracks (the liquid metal moves along the tracks under the action of the magnetic field or the electric field to drive the liquid sample to flow; the polarity of the magnetic field or the electric field is changed, and the liquid metal moves in the opposite direction along the spiral tracks to realize the rapid mixing of the liquid sample).

Further, the method comprises the following steps: all the micro mixing cavities have the same height, and all the spiral tracks have the same depth and are consistent with the height of the micro mixing cavities.

Further, all of the spiral tracks may be of equal or unequal width.

Further, the spiral shape of all the spiral tracks is an elliptical spiral shape, a rectangular spiral shape or a triangular spiral shape.

Further, the liquid metal is made of low-melting point elemental metal or metal alloy, the elemental metal is liquid mercury or liquid metal gallium, the metal alloy is gallium aluminum alloy, gallium bismuth alloy, gallium tin alloy or gallium indium alloy, and the liquid metal is one of the elemental metals or a combination of two of the elemental metals or one of the metal alloys or a combination of several of the metal alloys.

Further, the phase state of the liquid metal is a solid state or a solid-liquid critical phase state.

Furthermore, the material of all the microfluidic thin film layers is one or a combination of several of Polydimethylsiloxane (PDMS), polymethyl methacrylate, glass and polymer resin.

Further, the liquid metal is in the shape of a strip or a sphere.

Furthermore, the number of the microfluidic film layers is three or more (at most 5 microfluidic film layers) so as to realize the graded mixing of more liquid samples, and a microelectrode device layer 2 is arranged between every two adjacent microfluidic film layers.

Example 1:

as shown in fig. 1-4, the embodiment discloses a liquid metal microfluidic mixing device, which includes a first microfluidic thin film layer 1, a second microfluidic thin film layer 3, and a microelectrode device layer 2, wherein the first microfluidic thin film layer 1 and the second microfluidic thin film layer 3 are tiled and stacked up and down, the microelectrode device layer 2 is disposed between the first microfluidic thin film layer 1 and the second microfluidic thin film layer 3, and the upper surface of the first microfluidic thin film layer 1 is provided with a first mixed liquid outlet 1-3, a first micro-mixing cavity 1-5, a first spiral track 1-6, two first liquid sample inlets 1-1, and three first microchannels 1-4; the first spiral tracks 1-6 are arranged in the first micro-mixing cavities 1-5, the three first micro-channels 1-4 are communicated with the first micro-mixing cavities 1-5, one first micro-channel 1-4 is vertically provided with a first mixed liquid outlet 1-3, the rest two first micro-channels 1-4 are vertically provided with a first liquid sample inlet 1-1, the first spiral tracks 1-6 of the first micro-fluidic thin film layer 1 are internally provided with first liquid metal 1-2, and the first liquid metal 1-2 moves along the first spiral tracks 1-6;

the upper surface of the second microfluidic thin film layer 3 is provided with a second mixed liquid outlet 3-3, a second micro mixing cavity 3-5, a second spiral track 3-6, two second liquid sample inlets 3-1 and three second micro channels 3-4; the second spiral tracks 3-6 are arranged in the second micro mixing cavities 3-5, the three second micro channels 3-4 are all communicated with the second micro mixing cavities 3-5, one second micro channel 3-4 is vertically provided with the second mixed liquid outlet 3-3, the rest two second micro channels 3-4 are vertically provided with a second liquid sample inlet 3-1 respectively, the second spiral track 3-6 of the second micro-fluidic thin film layer 3 is internally provided with a second liquid metal 3-2, the second liquid metal 3-2 moves along the second spiral track 3-6, and the first mixed liquid outlet 1-3 is vertically connected with one second liquid sample inlet 3-1 (so as to be convenient for the fractional mixing of multiple liquid samples);

the positive pole of the electrode in the microelectrode device layer 2 is vertically aligned with the centers of the first spiral tracks 1-6 and the second spiral tracks 3-6, and the negative pole of the electrode in the microelectrode device layer 2 is vertically aligned with the inlets of the first spiral tracks 1-6 and the second spiral tracks 3-6;

the heights of the first micro mixing cavity 1-5 and the second micro mixing cavity 3-5 are the same, the depths of the first spiral track 1-6 and the second spiral track 3-6 are the same, and the heights of the first spiral track 1-5 and the second spiral track 3-5 are the same;

the first spiral tracks 1-6 are of equal or unequal width and the second spiral tracks 3-6 are of equal or unequal width;

the widths of the first spiral tracks 1-6 and the second spiral tracks 3-6 are equal or different (the shape of the liquid metal is not limited by the shape of the spiral tracks, and no dead angle is generated in the flowing process);

the spiral shapes of the first spiral-shaped tracks 1-6 and the second spiral-shaped tracks 3-6 are each an elliptical spiral shape, a rectangular spiral shape or a triangular spiral shape.

The first liquid metal 1-2 and the second liquid metal 3-2 are both low-melting-point elemental metals or metal alloys, the elemental metals are liquid mercury and liquid metal gallium, the metal alloys are gallium aluminum alloys, gallium bismuth alloys, gallium tin alloys and gallium indium alloys, the first liquid metal is one of the elemental metals or a combination of two of the elemental metals, or one of the metal alloys or a combination of several of the metal alloys, and the second liquid metal is one of the elemental metals or a combination of two of the elemental metals, or one of the metal alloys or a combination of several of the metal alloys;

the phase states of the first liquid metal 1-2 and the second liquid metal 3-2 are both solid or solid-liquid critical phase states; the first liquid metal 1-2 and the second liquid metal 3-2 are both strip-shaped or spherical;

the materials of the first micro-fluidic thin film layer 1 and the second micro-fluidic thin film layer 3 are one or a combination of several of Polydimethylsiloxane (PDMS), polymethyl methacrylate, glass and high polymer resin;

the working principle of the embodiment 1 is as follows: two liquid samples to be mixed enter a first micro-mixing cavity 1-5 through two first liquid sample inlets 1-1 of a first micro-fluidic thin film layer 1 respectively, a first liquid metal 1-2 in the first micro-mixing cavity 1-5 moves along a first spiral track 1-6 under the action of an electric field, and the liquid samples in the nearby flow field are driven to flow and mix under the action of Newton internal friction force. And the polarity of the electric field is changed, and the first liquid metal 1-2 moves along the first spiral track 1-6 in the opposite direction to drive the liquid sample to reversely flow and mix, so that the mixing efficiency of the sample is improved. After the liquid in the first microfluidic film layer 1 is mixed, the mixed liquid flows into a second micro mixing cavity 3-5 of the second microfluidic film layer 3 through the first mixed liquid outlet 1-3 and the second liquid sample inlet 3-1, and the mixing with other liquid samples is continuously completed. By changing the strength and polarity of the electric field, the moving speed of the second liquid metal 3-2 and the mixing effect of the liquid can be effectively controlled.

Claims (9)

1. A liquid metal microfluidic mixing device, characterized in that: the micro-fluidic device comprises at least two micro-fluidic film layers and at least one microelectrode device layer (2) or at least one micro-magnetic pole device layer, wherein all the micro-fluidic film layers are tiled and stacked up and down, one microelectrode device layer (2) or one micro-magnetic pole device layer is arranged between every two adjacent micro-fluidic film layers, and the upper surface of each micro-fluidic film layer is provided with a mixed liquid outlet, a micro-mixing cavity, a spiral track, at least one liquid sample inlet and at least two micro-channels; the spiral tracks are arranged in the micro-mixing cavities, all the micro-channels of each micro-fluidic thin film layer are communicated with the micro-mixing cavities of the micro-fluidic thin film layers, the mixed liquid outlet is vertically arranged on one micro-channel, the liquid sample inlets are vertically arranged on the rest micro-channels, liquid metal is arranged in the spiral track of each micro-fluidic thin film layer and moves along the spiral track, and the mixed liquid outlet of the micro-fluidic thin film layer positioned above is connected with one liquid sample inlet of the micro-fluidic thin film layer positioned below and adjacent to the mixed liquid outlet;

the positive poles of the electrodes in all the microelectrode device layers (2) are vertically aligned with the centers of all the spiral tracks, and the negative poles of the electrodes in all the microelectrode device layers (2) are vertically aligned with the inlets of all the spiral tracks; or one of the two magnetic poles of the built-in electromagnets of all the micro-magnetic pole device layers is vertically aligned with the center of all the spiral tracks, and the other magnetic pole of the built-in electromagnets of all the micro-magnetic pole device layers is vertically aligned with the entrance of all the spiral tracks.

2. The microfluidic mixing device of claim 1, wherein: all the micro mixing cavities have the same height, and all the spiral tracks have the same depth and are consistent with the height of the micro mixing cavities.

3. A liquid metal microfluidic mixing device according to claim 1 or 2, wherein: all of the spiral tracks may be of equal or unequal width.

4. The microfluidic mixing device of claim 1, wherein: the spiral shape of all the spiral tracks is an elliptical spiral shape, a rectangular spiral shape or a triangular spiral shape.

5. The microfluidic mixing device of claim 1, wherein the liquid metal is a low-melting-point elemental metal or a metal alloy, the elemental metal is liquid mercury or liquid metal gallium, the metal alloy is gallium-aluminum alloy, gallium-bismuth alloy, gallium-tin alloy or gallium-indium alloy, and the liquid metal is one of the elemental metals or one of the metal alloys.

6. The microfluidic mixing device of claim 1, wherein: the phase state of the liquid metal is a solid state or a solid-liquid critical phase state.

7. The microfluidic mixing device of claim 1, wherein: all the microfluidic thin film layers are made of one of polydimethylsiloxane, polymethyl methacrylate, glass and high polymer resin.

8. The microfluidic mixing device of claim 1, wherein: the liquid metal is in the shape of a strip or a ball.

9. The microfluidic mixing device of claim 1, wherein: the number of the microfluidic film layers is three or more.

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