KR101491823B1 - Microfluidic floating block and an combining method of microfluidic floating block by using these. - Google Patents

Abstract

The microfluidic flow block may include a groove for connection between the plurality of microfluidic flow blocks, a relief or relief angle to induce connection between the plurality of microfluidic flow blocks, A flow channel which is a path of the flow of the microfluid and a sealing part which is located at a distal end of the flow channel and blocks the leakage of the microfluidic fluid when the microfluidic flow blocks are connected to each other, sealing portion. The connection pin for connection between the microfluidic flow blocks corresponds to the shape of the coupling groove to be inserted into a coupling groove for connection between the microfluidic flow blocks .
The connection by the connection of the microfluidic flow block and the connection pin has an advantage that the connection direction of the flow block can be freely determined according to the user's intention.
That is, the fluid channel connection and the lamination of the flow block can be freely configured in the Z-axis direction, and the conical structure of the relief / relief formed on the outer surface of the flow block provides automatic positioning and position fixation between the flow blocks.
Further, the present invention can easily change and control the flow of the microfluid using the microfluidic flow block and the sealing part, and can be applied to a wide range of the protein chip, the dense chip, the drug delivery system, the microbiological / chemical analysis system, And the like.

Description

TECHNICAL FIELD [0001] The present invention relates to a microfluidic flow block and a microfluidic flow block connection method.

The present invention relates to a microfluidic flow block and a method of bonding a microfluidic flow block using the microfluidic flow block. More particularly, the present invention relates to a microfluidic flow block using a connecting pin and a sealing member capable of closely fixing a microfluidic flow block, The present invention relates to a microfluidic flow block configured to be easily connected and stacked in a space, and a method for connecting a microfluidic flow device using the microfluidic flow block.

In order to analyze a bio sample, an integrated small-scale analysis system is required which collectively processes the result of the sample through preprocessing (mixing, separation, three-dimensional focusing, etc.).

Recent developments in life sciences are increasing the number of target substances that need to be analyzed in areas such as drug development and diagnosis. Accordingly, a large amount of expensive reagents or samples are required, and the need for cost reduction through trace analysis is increasing.

Recently, many microfluidic control chips have been studied as a tool for applying biochemical reactions to chips. In order to use a microfluidic control chip as a biochemical reactor, it is necessary to induce fluid components such as a reaction solution, a sample, and a buffer on a chip to perform various microfluid control operations such as mixing, transport, branching, do. Here, various microfluid control operations on the chip may be controlled by various control methods such as mechanical force, air pressure, hydrostatic force, surface tension, gravity, magnetic force, electric force, optical transformation force, chemical reaction force, Methods are presented and implemented in various operations.

A microfluidic control device between a microfluidic control chip and an external control host has been studied for the purpose of guiding and supplying a fluid component such as a reaction solution, a sample, and a buffer from the outside to the microfluidic control chip. Such a microfluidic control device can be realized by the above-described various working principles.

The microfluidic control device should be able to accurately control the microfluidic fluid of the microfluidic control chip from the external large volume fluid control matrix. To this end, the control matrix and the microfluidic control chip must be kept airtight and connected so that there is no loss of volume.

In addition, the microfluidic control chip must be easy to attach and detach between the microfluidic control chip and the control host so that the microfluidic control chip can be used for a single use.

In order to carry out processes such as early diagnosis and chemical analysis on a small chip in the field of Bio-Micro Electro Mechanical Systems (Bio-MEMS) in general, It is indispensably required to integrate sensors that detect microbes that are capable of stopping, mixing and reacting and biomarkers related to disease (e.g., proteins, DeoxyriboNucleic Acid (DNA), etc.) with high sensitivity.

In the field of bio-microelectromechanical systems, particularly in the field of micro-systems used for chemical analysis and early diagnosis of diseases, for example bio lab on a chip, miniaturization, cost reduction, integration, Research is proceeding in a possible direction.

This is because the price of a general-purpose reagent is often expensive, so that a chemical analysis without pollution from the external environment can be reproducibly performed while using a necessary minimum amount of biological sample.

Accordingly, an inexpensive microfluidic control system attracts much attention.

10-1097357 relates to a multifunctional microfluidic flow control apparatus and a multifunctional microfluidic flow control method, and more particularly, to a multifunctional microfluidic flow control apparatus and a multifunctional microfluidic flow control method for use in microfluidic channels, And to a multifunctional microfluidic flow control method capable of implementing a control function for a multifunctional microfluidic flow. The microfluidic channel unit may include at least one microfluidic injection unit including first and second microfluidic injection passages, a microfluidic channel unit having a concavo-convex pattern formed therein to control the flow of at least one kind of microfluid injected through the microfluidic injection unit, And a microfluid discharger connected to the microfluidic channel to discharge the microfluid whose flow is controlled.

In the present invention, it is possible to freely connect and stack microfluidic flow blocks in an X-Y-Z three-dimensional space through a microfluidic flow block having a coupling groove structure into which symmetrical connecting pins can be inserted.

It is an object of the present invention to provide a seal between a microfluidic flow block and a seal of a fluid flow channel between microfluidic flow blocks by using a connecting pin and a sealing member.

The microfluidic flow block may include a groove for connection between the plurality of microfluidic flow blocks, a relief or relief angle to induce connection between the plurality of microfluidic flow blocks, A flow channel which is a path of the flow of the microfluid and a sealing part which is located at a distal end of the flow channel and which blocks the leakage of the microfluidic fluid when the microfluidic flow blocks are connected to each other, sealing portion. The connection pin for connection between the microfluidic flow blocks corresponds to the shape of the coupling groove to be inserted into a coupling groove for connection between the microfluidic flow blocks .

The microfluidic flow block structure having the coupling groove structure in which the four-sided symmetrical connection pins can be mounted has an advantage that the connection direction of the microfluidic flow block can be freely determined according to the user's intention.

That is, fluid flow channel connection and lamination of the microfluidic flow block can be freely configured in the Z-axis direction, and the shape of the emboss / depression formed on the outer surface of the microfluidic flow block can be automatically aligned and fixed Function.

Further, the present invention can easily change and control the flow of the microfluid using the microfluidic flow block and the sealing part, and can be applied to a wide range of the protein chip, the dense chip, the drug delivery system, the microbiological / And the like.

1 is a schematic view showing a microfluidic flow block and a connection pin according to the present invention.
FIG. 2 is a schematic view of a plurality of microfluidic flow blocks according to the present invention joined by connecting pins. FIG.
FIG. 3 shows a method of connecting microfluidic flow blocks according to the present invention.
4 illustrates a method of connecting microfluidic flow blocks according to an embodiment of the present invention.
5 illustrates a method of connecting microfluidic flow blocks according to an embodiment of the present invention.
6 shows a method of connecting microfluidic flow blocks according to an embodiment of the present invention.
7 illustrates a method of connecting microfluidic flow blocks according to an embodiment of the present invention.
8 illustrates a method of connecting microfluidic flow blocks according to an embodiment of the present invention.

1 is a schematic view showing a microfluidic flow block 100 and a connection pin 200 according to the present invention.

The microfluidic flow block 100 includes a groove 110 for connection between the plurality of microfluidic flowblocks 100, a plurality of microfluidic flowblocks 100, A channel 130 that is a path of the flow of the microfluid and a channel 130 that is located at a distal end of the flow channel 130, The microfluidic flow block 100 may include a sealing part 140 for blocking leakage of the microfluidic fluid.

A groove 110 for connection between the microfluidic flow blocks 100 is formed in a shape passing through the microfluidic flow block 100 and a shape of the microfluidic flow block 100 And a shape that does not penetrate the upper portion and the lower portion of the base portion.

The shape of the coupling groove 110 may be variously formed according to the shape of the coupling pin 200 to be inserted and coupled therewith.

In addition, the microfluidic flow block 100 preferably includes at least one of a polymer resin, an amorphous material, and a metal, but is not limited thereto.

The embossed or depressed shape 120 is disposed at at least one of the upper surface, the lower surface, and the side surface of the microfluidic flow block 100.

The embossed or depressed shape 120 may be implemented in the form of a cone to automatically guide the connection position of the microfluidic flow block 100 and the microfluidic flow block 100 It prevents the position change after connection.

If the embossed or engraved shape 120 is implemented in the shape of a cone, it is preferred that the cone not be structurally disturbed when the microfluidic flow blocks 100 are joined or detached at an angle of 45 degrees will be.

The flow channel 130, which is the path of the flow of the microfluid, may include at least one of a linear channel, a curved channel, and a spiral channel. In addition, the flow channel 130 may be formed as a single chamber, and the flow channel 130 may be shaped to have an irregular shape as required. It will be possible.

Also, the shape and surface of the flow channel (130) can be variously manufactured. If necessary, the surface of the flow channel 130 may be coated with a variety of hydrophilic, hydrophobic, chemical resistant, conductive, and the like.

The sealing part 140 may include a sealing member 141 for blocking leakage of the microfluid and a sealing groove 142 for inserting the sealing member 141. The sealing member 141 may be formed in an O-ring shape, but it is not limited thereto.

The sealing member 141 may be in the form of a ring or a polygonal ring having a hole formed in the central portion thereof, or may be in the form of a cap, in particular, a polymer resin, an amorphous material, Ethylene-propylene rubber, polyvinyl butyral resin, polyurethane resin, and nitrile-butadiene rubber among ethylene propylene dimethyl, silicone rubber, acrylic resin, amide resin, epoxy resin, phenol resin, polyester resin, polyethylene resin, The sealing member 141 may be coated with a functional material such as Teflon or Viton, if necessary.

In addition, the microfluidic flow block 100 may further include an injection unit or discharge unit 150 used to inject or discharge fluid.

The injection unit or discharge unit 150 may be a screw or elastic material so as to be inserted into the microfluidic flow block 100. However, the injection unit or the discharge unit 150 may be modified in various ways, There will be.

The connection pin 200 for connection between the microfluidic flow blocks 100 is inserted into a groove 110 for connection between the microfluidic flowblocks 100, it would be possible to have a structure corresponding to the shape of the groove 110.

FIG. 3 shows a method of connecting microfluidic flow blocks according to the present invention.

The method of connecting the microfluidic flow blocks includes the steps of preparing a plurality of microfluidic flow blocks 100 including a flow channel 130 that is a path of the microfluid of the present invention Arranging the plurality of microfluidic flow blocks 100 so that the flow channels 130 of the plurality of microfluidic flow blocks 100 may be connected to each other in a desired form; Forming a sealing part 140 for blocking the leakage of the microfluid and connecting the connection pin 200 of the present invention to the groove 110 of the plurality of microfluidic flow blocks, The connection pin 200 is inserted into a groove 110 of the microfluidic flow block to form a channel line through which the microfluid passes. It is possible to include the step of forming the stepped portion.

Further, after the step of forming the flow channel line through which the microfluid passes, the step of inserting the injection part or the discharge part 150 used for injecting or discharging the fluid It will be possible to include.

FIG. 8 illustrates a step of inserting an injection unit or a discharge unit 150 in a method of connecting microfluidic flow blocks according to an embodiment of the present invention.

As shown in FIG. 8A, it is possible that the injection or discharge part 150 has the shape of the screw structure 150a. A corresponding microfluidic flow block 100a may be used to insert the injection or discharge portion of such a threaded structure 150a.

8B, when the injection unit or the discharge unit 150 is formed of an elastic material, the corresponding microfluidic flow block 100b may be used. The injection portion or discharge portion 150b having elasticity may be manufactured by including at least one of silicone, rubber, and polymer such as PDMS (polydimethylsiloxane).

FIG. 2 is a schematic view of a plurality of microfluidic flow blocks according to the present invention joined by connecting pins. FIG.

The connection pin 200 for connection between the microfluidic flow blocks 100 is inserted into a groove 110 for connection between the microfluidic flowblocks 100, it would be possible to have a structure corresponding to the shape of the groove 110.

FIGS. 4 to 8 illustrate a method of connecting microfluidic flow blocks according to an embodiment of the present invention.

The connection pin 200 may be formed in at least one of a groove or a groove located at an upper portion or a lower portion of the microfluidic flow block 100 in the form of at least one of a diagonal, 110).

In this case, the groove 110 may be composed of a take-out groove 111 and an insert groove 112. The removal groove 111 allows the connection pin 200 to be easily removed using a mechanism such as a tweezer when the connection pin 200 is removed from the groove 112.

The connection pin 200 may be formed in at least one of a groove or a groove located at an upper portion or a lower portion of the microfluidic flow block 100 in the form of at least one of a diagonal, 110, it is possible that the upper connection pin and the lower connection pin exhibit magnetism and are coupled by the reaction of the magnetic force.

If the lengths of the upper and lower connection pins 200 are made the same, the connection pins 200 can be inserted into the upper and lower portions, respectively. If both protrusions of the connection pin are made longer, It may be inserted and fixed only on one side of the upper or lower portion of the flow block 100.

It is also possible that the upper connecting pin and the lower connecting pin are coupled by a screw structure. In the case where the connecting pin has a screw structure, a groove 110 for connection between the microfluidic flow blocks 100 may be formed to pass through the microfluidic flow block. The shape of the connecting pin 200 and the structure of the groove 110 may be determined by the bonding strength, the micro-fluidic flow, The arrangement of the fluid flow block 100, and the like.

6, the connection pin 200 may be in the form of a bolt 212 and a nut 211. As shown in FIG. In this case, a washer 213 may be additionally provided between the bolt 212 and the nut 211 to prevent damage to the lower block due to bolts during the fastening process.

The connection pin 200 may be used as a bolt 212 and a nut 211 when two or more microfluidic flow blocks 100 are connected vertically.

A sealing groove is formed at the center of the microfluidic flow block 100 to insert the vertical connection channel 130 and the O-ring-shaped sealing member 141.

The vertical connection channel can be connected in one direction or both directions upward or downward, and four bolt / nut coupling grooves 110a (110a) are formed around the sealing groove for inserting the sealing member 141 in the O- ). A bolt / nut coupling groove 110a should be formed avoiding the flow channel 130 of the microfluidic flow block 100.

As shown in FIG. 7, the connecting pin 200 has a narrow center and a wide dumbbell structure 220 having a wide end. When the coupling groove (groove) 110b has a double structure, It is also possible to implement such a combination.

Such a case may also be used when two or more of the microfluidic flow blocks 100 are vertically connected.

A plurality of coupling grooves in the form of the coupling grooves 110b of the double structure are formed in the periphery of the sealing member 141 which is the sealing part 140 and the sealing groove 142 into which the sealing member 141 is inserted, (not shown). But is not limited to, having four coupling grooves 110 preferably.

The coupling groove (110b) of the double structure is disposed symmetrically about a sealing groove (142) of an O-ring-shaped sealing member (141).

(130) inside the microfluidic flow block (100).

One side of the coupling groove (110b) of the double structure has a diameter equal to or larger than both ends of the coupling pin (220), and the other side is larger than the middle portion of the coupling pin (220) It would be desirable to have a smaller diameter than the portion.

The connection pin 220 is narrow in the middle and has a wide dumbbell structure at both ends.

The joining method is to insert the coupling pin 220 into a large diameter portion of the groove 110b of the double structure and then push the coupling groove 220 to a small diameter portion of the groove 110b. The connecting pin 220 having a dumbbell structure tightly adheres the upper / lower block.

The material of the connection pin 200 may be at least one of plastic, metal, non-metal, and wood. However, the connection pin 200 may be manufactured using various materials will be.

In order to connect the vertical structure of the microfluidic flow block 100, it is preferable to include the microfluidic flow block 100 as shown in FIG. 5A.

5A shows a vertically connecting block (side-type) for vertically connecting two microfluidic flow blocks 100, and includes a sealing groove for inserting two sealing members 141 on one side, It may be desirable to have a connection channel 142 and a connection flow channel 130.

The flow channel 130 may be formed in a U-shape for connecting the flow channel 130 of the upper and lower microfluidic flow block 100.

Further, the connection pin 200 may have a protrusion longer than the connection pin for general horizontal connection as described above, or a magnet or a combination of bolts / nuts may be applied to prevent the connection pin of the upper and lower parts from coming off It will be possible.

The connection structure between the microfluidic flow blocks of the present invention includes the microfluidic flow block 100 and the connection pin 200 to form the microfluidic flow block 100, It may be possible to connect this to the horizontal.

More specifically, the structure of the microfluidic flow block 100 capable of mounting the four-sided symmetrical connection pin 200 is configured such that the connection direction of the microfluidic flow block 100 is changed according to the user's intention It has the advantage of being free to decide.

That is, the connection of the microfluidic flow channel 130 in the vertical direction of the Z-axis and the lamination of the microfluidic flow block 100 can be freely configured, allowing free connection and stacking of the flow blocks in the XYZ three-dimensional space And the embossed / depressed shape 120 formed on the outer surface of the microfluidic flow block 100 provides automatic alignment and position fixation between the microfluidic flow blocks 100.

The present invention is also characterized in that the microfluidic fluid flow block (100) and the microfluidic fluid flow using a sealing part (140) comprising a sealing member (141) and a sealing groove (142) And can be used for a wide range of uses such as protein chips, DNA chips, drug delivery systems, microbiological / chemical analysis systems, and biochemical reactors.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it should be understood that various changes and modifications will be apparent to those skilled in the art. It is to be understood that the present invention is not limited to the above-described embodiments. Accordingly, the scope of protection of the present invention should be construed according to the following claims, and all technical ideas which fall within the scope of equivalence by alteration, substitution, substitution, Range. In addition, it should be clarified that some configurations of the drawings are intended to explain the configuration more clearly and are provided in an exaggerated or reduced size than the actual configuration.

100: microfluidic flow block 100a: microfluidic flow block 100a:
100b: microfluidic flow block 110:
111: take-out groove 112: groove (groove)
110a: engaging groove 110b: engaging groove
120: positive or negative shape 130: microfluidic channel
140: sealing part 141: sealing member
142: sealing groove 150: injection part or discharge part
150a: injection part or discharge part 150b: injection part or discharge part
200: connecting pin 211: connecting pin nut
212: connecting pin bolt 213: connecting pin washer
220: Connection pin

Claims (19)

In a microfluidic flow block,
A coupling groove for connection between the plurality of microfluidic flow blocks;
A relief or relief shape to induce connection between a plurality of said microfluidic flow blocks and prevent said relief;
A flow channel that is a path of flow of the microfluid;
A sealing unit positioned at a distal end of the flow channel to block leakage of the microfluidic fluid when the plurality of microfluidic flow blocks are connected to each other;
An inlet or outlet used for injecting or discharging fluid;
A connection pin having a structure corresponding to the shape of the coupling groove to be inserted into the coupling groove for coupling between the microfluidic flow blocks;
/ RTI >

A groove for connection between the microfluidic flow blocks is formed in a shape passing through the microfluidic flow block and is formed in the upper and lower portions of the microfluidic flow block, Shape,

Wherein the sealing part includes a sealing member for blocking leakage of the microfluid and a sealing groove for inserting the sealing member,

Wherein the injection unit and the discharge unit are made of a material having a screw structure or elasticity so as to be inserted into the microfluidic flow block,

The connecting pin
Wherein the microfluidic fluid is inserted into the groove located at the upper or lower portion of the microfluidic flow block in at least one of a diagonal, a diagonal, and a diagonal. (block).
delete delete delete delete delete delete delete delete The method according to claim 1,
The connecting pin
The upper connection pin and the lower connection pin have magnetism,
Wherein the microfluidic fluid is a structure that is bonded by the magnetic reaction. The method according to claim 1,
The connecting pin
Wherein the upper connecting pin and the lower connecting pin are coupled by a screw structure. The method according to claim 1,
The connecting pin
Wherein the microfluidic flow block is in the form of a bolt and a nut. The method according to claim 1,
The connecting pin
It has a narrow center and a wide dumbbell structure at both ends.
When the coupling groove is a double structure, it is inserted
To thereby lock and unlock the microfluidic flow block. The method according to claim 1,
Wherein the connection pin comprises at least one of plastic, metal, nonmetal, and wood. In a method of connecting microfluidic flow blocks,
(i) a microfluidic channel including a flow channel which is a path of a flow of a microfluidic flow; preparing a plurality of microfluidic flow blocks according to any one of claims 1 to 14;
(ii) arranging the plurality of microfluidic flow blocks such that the flow channels of the plurality of microfluidic flow blocks are connected to each other in a desired form;
(iii) forming a sealing portion for blocking leakage of the microfluid;
(iv) inserting the connecting pin into a groove of the plurality of microfluidic flow blocks;
(v) the coupling pin is inserted into the groove of the microfluidic flow block,
Forming a flow channel line through which the microfluid passes;
And connecting the microfluidic flow blocks. 16. The method of claim 15,
Between each step or after step (v)
Used to inject or drain fluids
The step of inserting the injection part or the discharge part
Further comprising a plurality of microfluidic flow blocks.
delete delete delete

Images