Multi-channel magnetic control system

Abstract

A multi-channel magnetic control system is provided, which is used for mixing fluids containing magnetic particles or separating magnetic species. In the multi-channel magnetic control system, a plurality of magnetic field switches are allocated to surround a plurality of channels, and the magnetization directions of the magnetic field switches are controlled to generate an uneven local magnetic field gradient, so as to achieve the purpose of fluid mixing or separating the magnetic species. This system can be also used as controllable flow resistance devices for magnetic fluids. Based on the demand of magnetic field distribution, overall or local control of the magnetic field switches can be executed to perform parallel processing over the multi-channel system of multi-dimensional allocation, so as to effectively save the processing time. The mixing or separation rate can be obtained via detecting residual magnetic species by magnetoresistive sensors arranged in inlets and outlets of channels.

Claims

1. A multi-channel magnetic control system, comprising: a plurality of channels; a plurality of magnetic field switches disposed around each of the plurality of channels, and each magnetic field switch comprises a plurality of magnetic elements having different magnetic anisotropies; and a control module providing an external magnetic field to change a magnetization direction of the magnetic elements of the at least one magnetic field switch, so as to generate a local magnetic field gradient in the plurality of channels.

2. The multi-channel magnetic control system of claim 1, wherein when the plurality of magnetic field switches allocated at two sides of each of the plurality of channels, the magnetic field switches allocated at one side of the channel and the magnetic field switches allocated at the other side of the channel are symmetrical to each other, or the magnetic field switches allocated at one side of the channel are between the magnetic field switches allocated at the other side of the channel.

3. The multi-channel magnetic control system of claim 2, wherein the magnetic field switches allocated at the same side of the channel are arranged in a fixed distance from each other.

4. The multi-channel magnetic control system of claim 3, wherein the fixed distance is between 0.1 m and 2000 m.

5. The multi-channel magnetic control system of claim 1, wherein the control module controls a magnetization direction of the magnetic field switches intermittently.

6. The multi-channel magnetic control system of claim 1, wherein the control module controls the plurality of magnetic field switches entirely or locally.

7. The multi-channel magnetic control system of claim 1, wherein each magnetic anisotropy of the magnetic elements is generated from a shape anisotropy or a magnetocrystalline anisotropy.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) For better understanding, like elements are designated by like reference numerals in the accompanying drawings and the following description for the embodiments.

(2) FIG. 1 is a schematic diagram illustrating the structure of the multi-channel magnetic control system of the present disclosure.

(3) FIG. 2 is a schematic diagram illustrating the conception of the magnetic field switch of the multi-channel magnetic control system of the present disclosure.

(4) FIG. 3 is a schematic diagram illustrating the fluid mix of the multi-channel magnetic control system of the present disclosure.

(5) FIG. 4 is a diagram showing the experiment result of fluid mix of the multi-channel magnetic control system of the present disclosure.

(6) FIG. 5 is a schematic diagram illustrating the species separation of the multi-channel magnetic control system of the present disclosure.

(7) FIG. 6 is a schematic diagram illustrating the configuration of two adjacent channels, which are both performing fluid mix, of the multi-channel magnetic control system of the present disclosure.

(8) FIG. 7 is a schematic diagram illustrating the configuration of two adjacent channels, which are both performing fluid mix and species separation simultaneously, of the multi-channel magnetic control system of the present disclosure.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

(9) In order to facilitate the understanding of the technical features, the contents and the advantages of the present disclosure, and the effectiveness thereof that can be achieved, the present disclosure will be illustrated in detail below through embodiments with reference to the accompanying drawings. On the other hand, the diagrams used herein are merely intended to be schematic and auxiliary to the specification, but are not necessary to be true scale and precise configuration after implementing the present disclosure. Thus, it should not be interpreted in accordance with the scale and the configuration of the accompanying drawings to limit the scope of the present disclosure on the practical implementation.

(10) Hereinafter, embodiments of the present disclosure will be described in detail with reference to the accompanying drawings so that those skilled in the art to which the present disclosure pertains can realize the present disclosure. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present disclosure.

(11) Please refer to FIG. 1 which is a schematic diagram illustrating the structure of the multi-channel magnetic control system of the present disclosure. As shown in the figure, a multi-channel magnetic control system of the present disclosure includes a plurality of channels 10, a plurality of magnetic field switches 20 and a control module 30. The plurality of channels 10 can be arranged in a two-dimensional model or a three-dimensional model according to the actual requirement or application. In practice, it can further extend in the space with an arbitrary direction.

(12) The plurality of magnetic field switches 20 are respectively disposed between the plurality of channels 10, wherein at least one magnetic field switch 20 is shared by at least two channels 10. Each magnetic field switch 20 includes a plurality of magnetic elements characterized of respective magnetic anisotropies. The plurality of magnetic field switches 20 allocated at two sides of at least one channel 10 are arranged in a corresponding arrangement, a staggering arrangement, or a combination thereof.

(13) For example, each magnetic field switch 20 includes two magnetic elements 21 having a smaller magnetic anisotropy and one magnetic element 22 having a larger magnetic anisotropy. The magnetic element is made of a magnetic material, and can be formed by a stacked multilayer film, a plurality of separated films, or a plurality of separated multilayer films. But it shall be not limited thereto.

(14) The control module 30 changes a magnetization direction of the magnetic elements of at least one the magnetic field switch 20 according to a magnetic field distribution demand, so as to generate a local magnetic field gradient in the plurality of channels 10. The control module 30 controls the magnetization direction of the magnetic field switch 20 intermittently so as to increase the efficiency of mixing fluid containing magnetic particles and/or separating magnetic species in the plurality of channels 10.

(15) Please refer to FIG. 2 which is a schematic diagram illustrating the conception of the magnetic field switch of the multi-channel magnetic control system of the present disclosure. As shown in the figure, the two magnetic elements 21 having the smaller magnetic anisotropy and the magnetic element 22 having the larger magnetic anisotropy are made of magnetic materials characterized of respective switching magnetic fields. The switching magnetic fields are generated from the same magnetic material characterized of different magnetic properties or anisotropies such as shape anisotropy, magnetocrystalline anisotropy, or from various magnetic materials, indicating that the two magnetic elements 21 having the smaller magnetic anisotropy and the magnetic element 22 having the larger magnetic anisotropy have respective switching magnetic fields for switching the magnetization direction.

(16) When arranging the magnetic elements having different magnetic anisotropies, an external magnetic field with larger magnitude is added to magnetize all the magnetic elements to the same magnetization direction (the arrowheads of the magnetic elements), that is, the north and south magnetic poles of all the magnetic elements are magnetized to the same direction, such that these magnetic elements are combined to become a large magnet so as to form a strong magnetic cluster 82, and then the magnetic field switch 20 is defined as ON.

(17) Similarly, when an external magnetic field which has a magnetization direction opposing to an initial magnetization direction of a magnetic element is added and the external magnetic field can only enable the two magnetic elements 21 having the smaller magnetic anisotropy to generate the magnetization switching, therefore the magnetic poles of the two magnetic elements 21 having the smaller magnetic anisotropy will have a reverse direction to the magnetic pole of the magnetic element 22 having the larger magnetic anisotropy. As a result, the magnetic field of the two magnetic elements 21 having the smaller magnetic anisotropy inters the end point of the magnetic element 22 having the larger magnetic anisotropy to form a weak magnetic cluster 84. The aspect is applied to define the magnetic field switch 20 to be OFF.

(18) Please refer to FIG. 3 and FIG. 4 together. As shown in the figures, in the multi-channel magnetic control system of the present disclosure, the magnetic field switches 20 allocated at one side of at least one channel 10 is arranged in a fixed distance d, and the magnetic field switches 20 allocated at opposing sides of the at least one channel 10 is allocated with a staggering arrangement. The fixed distance d is between 0.1 m and 2000 m. In practice, when the magnetic element of the magnetic field switch 20 is a stacked multilayer film, the gap between each fixed distance is smaller than 0.1 m.

(19) Firstly, a magnetic fluid 41 and a non-magnetic fluid 42 are introduced into the channel 10. If the magnetic field switches 20 allocated at two sides of the channel 10 are not turned on, the magnetic fluid 41 and the non-magnetic fluid 42 will only be slightly mixed after flowing a long distance.

(20) When mixing the fluids, the plurality of magnetic field switches 20 are turned on, and the strong magnetic cluster 82 of the plurality of magnetic field switches 20 affects the magnetic fluid 41 magnetically to draw the magnetic fluid 41 towards the plurality of magnetic field switches 20 while ruling out the non-magnetic fluid 42, enabling the flow path of the fluids to have a curve trend so as to increase the contact length and the contact time between the fluids and to cause a chaotic flow field to mix the fluids. As a result, it can enhance the mixing efficiency of the magnetic fluid 41 and the non-magnetic fluid 42, such that when the magnetic fluid 41 and the non-magnetic fluid 42 flow through the plurality of magnetic field switches 20, they are mixed to become an even fluid 43.

(21) FIG. 4 also illustrates that the mixing efficiency varies with the variation of the magnetic cluster intensity of the plurality of magnetic field switches 20. The plurality of magnetic field switches 20 are allocated in a distance starting from an inlet of the channel 10 to 500 m. When a conducted magnetic field intensity is over 30000 A/m, the mixing efficiency is over 84% in 1500 m of the channel 10. The experiment result also shows that the stronger the magnetic field intensity is, the better the mixing efficiency will become. Therefore, the experiment results verify that the multi-channel magnetic control system of the present disclosure does promote the mixing efficiency of the even fluid 43.

(22) Please refer to FIG. 5 which is a schematic diagram illustrating the magnetic species 50 separation of the multi-channel magnetic control system of the present disclosure. The plurality of magnetic field switches 20 are allocated at two sides of the channel 10 correspondingly. Besides, the magnetic field switches 20 allocated at the same side is still arranged in the fixed distance d.

(23) As shown in the figure, the fluid containing the magnetic species 50 is introduced into the channel 10. If the plurality of magnetic field switches 20 allocated at two sides of the channel 10 are not turned on, the fluid is not affected. When the plurality of magnetic field switches 20 allocated at two sides of the channel 10 are turned on, the strong magnetic cluster 82 of the plurality of magnetic field switches 20 draws the magnetic species 50 from the channel 10 towards the plurality of magnetic field switches 20. The amount of drawn magnetic species 51 which adhere to the periphery of the wall of the channel 10 is obviously greater than the amount of other magnetic species 52 which keep flowing through the channel 10. This proves that the plurality of magnetic field switches 20 can effectively draw and capture most magnetic species 50.

(24) When the plurality of magnetic field switches 20 are OFF, the weak magnetic cluster 84 releases the magnetic species 51 back to the channel 10 and the magnetic species 50 can be collected in the outlet of the channel 10, such that the purpose of separating the magnetic species 50 is achieved.

(25) Please refer to FIG. 6. As shown in the figure, the present embodiment shows an example when two channels 10 are parallel to each other, and the plurality of magnetic field switches 20 between the two adjacent channels 10 are being shared by the two channels 10. The control module 30 is applied to adjust the plurality of magnetic field switches 20 entirely or locally according to the magnetic field distribution demand.

(26) When the two adjacent channels 10 are performing fluid mix simultaneously, the plurality of magnetic field switches 20 are allocated with a staggering arrangement outside the periphery of the channels 10. As the magnetic cluster of the plurality of magnetic field switches 20 is surrounding in a cubical space, it can magnetically affect the two channels 10 simultaneously. When the plurality of magnetic field switches 20 are ON, the mixing efficiencies of both the magnetic fluid 41 and the non-magnetic fluid 42 are increased in the two channels 10. Compared with single channel 10, the two channels 10 are capable of processing a double fluid volume. In addition, as the plurality of magnetic field switches 20 can be shared, the cost is therefore decreased.

(27) Please refer to FIG. 7. The arrangement of the magnetic field switches 20 is similar to FIG. 6. The difference between FIG. 7 and FIG. 6 lies that the plurality of magnetic field switches 20 allocated on an upper channel 10 and at a lower channel 10 have different allocations.

(28) If the fluid mix and species separation are performed in the channel system, the plurality of magnetic field switches 20 allocated on the upper channel 10 have the staggering arrangement, and the upper channel 10 is served for mixing the flow. The plurality of magnetic field switches 20 allocated at the lower channel 10 are a corresponding arrangement and the lower channel 10 is applied to separate the magnetic species 50.

(29) The plurality of magnetic field switches 20 allocated at two sides of the channel 10 can have various arrangements, so that it is capable of producing different effects of mixing fluid and separating species. In addition, the control module 30 adjusts the plurality of magnetic field switches 20 entirely or locally according to the magnetic field distribution demand to generate different local magnetic field gradients having different intensities. To be more precise, when the local magnetic field gradient is generated, separating the magnetic species 50 according to the magnetic moment of the magnetic species 50 can be achieved so as to sieve the magnetic species 50.

(30) The magnetic field switch of the present disclosure is consisted of a plurality of magnetic elements having respective magnetic anisotropies. The magnetic anisotropy characteristics of the magnetic element enable the magnetic element to be magnetized in a short period of time by the external magnetic field, and the magnetization and the pole strength of the magnetic element can be maintained for a long while without continuously supplying energy. The magnetic field switch of the present disclosure is therefore capable of decreasing the power consumption and the temperature variation compared to the conventional electromagnet which is continuously energized.

(31) By means of the magnetic control system, the present disclosure is capable of entirely or locally control the parameters such as the operation frequency and the magnetic field intensity according to the actual magnetic field distribution demand, so as to generate local magnetic field gradients having different intensities. In addition, based on the flow resistance demand, the system can be also used as controllable flow resistance device for magnetic fluids.

(32) By means of the multi-dimensional arrangement and the arrangement of a plurality of magnetic field switches, the present disclosure is capable of simultaneously mixing and/or separating fluid to effectively save the processing time. Besides, the inlet and outlet of the channel of the present disclosure are further disposed with a magnetoresistive sensor respectively to sense a degree of mixing of a fluid or a residual rate of a magnetic species that is separated.

(33) While the means of specific embodiments in present disclosure has been described by reference drawings, numerous modifications and variations could be made thereto by those skilled in the art without departing from the scope and spirit of the invention set forth in the claims. The modifications and variations should in a range limited by the specification of the present disclosure.