KR100532127B1 - Fluid resistor device using fluid resistor units and, its applications digital fluid logic circuits - Google Patents

Abstract

The present invention relates to a digital fluid logic circuit using a fluid resistance element that regulates the flow or hydraulic resistance of a microfluid in the microchannel.

The digital fluid logic circuit according to the present invention comprises a fluid supply source for supplying a fluid, an entrance passage communicating with the fluid supply source, an exit passage through which the fluid is discharged, and the entrance passage and the exit passage, and are discharged into the exit passage. A fluid logic unit to adjust the flow rate or the hydraulic pressure of the fluid to be provided; The fluid logic unit includes an on / off valve means for controlling whether the fluid is introduced or discharged to another vent, a plurality of fluid resistance elements forming at least two or more paths of the fluid supplied through the inlet passage; Having a straight channel; At least two unit fluid resistance elements connected in series, parallel or series-parallel mixing between the entry channel and the exit channel, each having the same unit fluid resistance value; According to the on / off control operation of the on / off valve means, the path of the fluid is changed to control the flow rate or oil pressure of the fluid discharged to the exit passage, and the output value according to the flow rate or oil pressure of the fluid discharged to the exit passage This is determined.

Description

Fluid resistor device using fluid resistor units and, its applications digital fluid logic circuits}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fluid resistance element for controlling the flow or hydraulic resistance of a micro fluid in a micro flow path, and a digital fluid logic circuit using the fluid resistance element.

Recently, interest in microbial sample injectors, microanalyzers, and the like has increased. These applications require precise control of small amounts of fluid, such as nl or μl. In order to meet the demand, it is necessary to precisely adjust the flow resistance.

In the related art, in order to control the flow resistance of a fluid as shown in FIG. 1, a method of adjusting the width of a flow path having the same depth is used.

Referring to FIG. 1, a method for adjusting the flow resistance of a fluid according to the related art uses different fluid resistance elements 40 and 41 between flow paths 30. The micro flow rate / hydraulic regulator having such a configuration changes the cross-sectional area of the fluid resistance element in the flow path in order to adjust the flow rate / hydraulic pressure by a predetermined amount. That is, as shown in FIG. 1, the flow resistance is adjusted by increasing or decreasing the width of the fluid resistance portion having the same depth.

However, these methods generally present significant difficulties in controlling the flow rate or pressure at a desired level by adjusting the cross-sectional area of the flow path since the flow or hydraulic resistance is not linearly related to the cross-sectional area of the flow path.

In addition, even if the fluid resistance element is designed according to a specific flow rate or pressure, processing error occurs during the manufacturing process, there is a difficulty in maintaining the homogeneity between the same fluid system and the accuracy of the flow rate or pressure in the entire fluid system.

Looking at the prior art, there are the following.

First, US Patent (US 5849367) 'Micromachined Fluid Handling Devices' is a method of controlling the flow of microfluids using a micropump, a valve and a flow regulator. The flow regulator of the prior patent is a method for adjusting the cross-sectional area of the flow path using a thin film. In this case, there is a problem in that the accuracy of the flow rate and the flow resistance is lowered due to the poor repeatability and linearity due to the operation characteristics of the thin film.

U.S. Patent (US 6296020) 'Fluid Circuit Components based upon Passive Fluid Dynamics' uses each fluid flow path by changing the flow resistance due to the contact angle or surface tension between the fluid and the flow path wall when the fluid enters the empty flow path. It is a method of controlling the separation and mixing of the microfluid flowing through. This prior patent discloses a method of blocking flow or adjusting the order of flow through each empty flow path using fluid resistance. However, this prior patent does not solve the above-mentioned problems because the influence of the machining error that occurs during micro-processing is very large.

The present invention has been made to solve the problems of the prior art as described above, instead of the method of adjusting the depth and width of the fluid resistance element in the flow path to control the flow resistance of the fluid, the unit fluid resistance is defined in depth and width An object of the present invention is to provide a fluid resistive element that forms an element and connects the unit fluid resistive element in series, parallel or series-parallel mixing to change the overall flow resistance.

In addition, an object of the present invention is to configure a fluid flow rate / hydraulic control device using the above-described fluid resistance element, and to provide a digital fluid logic circuit using the flow rate / hydraulic pressure control device of the fluid.

The digital fluid logic circuit according to the present invention for achieving the object as described above, the fluid supply source for supplying a fluid, the entrance and exit flow passage in communication with the fluid supply source, and the entrance and exit flow path And a fluid logic unit configured to adjust a flow rate or hydraulic pressure of the fluid discharged to the exit passage,

The fluid logic unit includes an on / off valve means for controlling whether the fluid is introduced or discharged to another vent, a plurality of fluid resistance elements forming at least two or more paths of the fluid supplied through the inlet passage; With a straight flow path,

The fluid resistive element includes at least two unit fluid resistive elements for connecting any two flow paths in series, in parallel, or in parallel and parallel mixing.

According to the on / off control operation of the on / off valve means, the path of the fluid is changed to control the flow rate or oil pressure of the fluid discharged to the exit passage, and the output value according to the flow rate or oil pressure of the fluid discharged to the exit passage This is characterized in that it is determined.

Hereinafter, an embodiment of a digital fluid logic circuit using a fluid resistance element according to the present invention will be described in detail with reference to the accompanying drawings.

First, the fluid resistance element proposed by the present invention and a flow rate / hydraulic control device using the same will be described, and finally, the digital fluid logic circuit according to the present invention will be described.

2 conceptually illustrates a method of controlling the flow resistance of a fluid proposed in the present invention.

Figure 2 (a) shows a method of controlling the total flow resistance by connecting the unit fluid resistance elements defined in accordance with the present invention in series on a plane, Figure 2 (b) shows the unit fluid resistance elements in parallel 2 shows a method of adjusting the total flow resistance, and (c) of FIG. 2 shows a method of controlling the total flow resistance by connecting the unit fluid resistance element in a series-parallel mixture.

3 is a diagram illustrating embodiments of a unit fluid resistance device according to the present invention. Unit fluid resistance element is formed by adjusting the cross-sectional area of the flow path to control the flow resistance of the fluid. (A), (b), (c), (d), (e), (f), (g), (h), (i), (j), (k), and (l) of FIG. , (m) and (n) show a method of forming various unit fluid resistance elements 52, respectively, and (a) and (b) are relative to the width of the flow path inside the flow path 30 having the same depth. As a result, a method of forming the unit fluid resistance element 52 by a method of reducing the width of the flow path is illustrated.

3C, 3D, and 3E have a constant width change in the flow path 30 having the same depth, and a method of reducing the width relatively to the width of the flow path 30. A method of forming the unit fluid resistance element 52 is shown.

3 (f), (g), (h), (i), (j) and (k) are flow paths relatively larger than the width of the flow path 30 inside the flow path 30 having the same depth. The method of forming the unit fluid resistive element 52 by a method of widening the width of the cross section is shown.

In addition, (l), (m) and (n) of Figure 3 to form a unit fluid resistance element 52 by the method of manufacturing the column-shaped geometric structure 52 in the form of islands in the flow path (30). It shows how.

On the other hand, in Fig. 3 (a) to (n), the fluid supply source (not shown in the figure) communicates with the front end portion 10 of the flow path 30, and the outlet of the fluid communicates with the rear end portion 20. Can be. Then, when the fluid supplied from the fluid source flows through the flow path 30, in the unit fluid resistance element 52, the pressure loss due to the viscosity of the relatively larger value than the remaining flow path 30 and the additional change due to the geometry change The pressure loss is generated so that the flow resistance per unit length in the unit fluid resistance element 52 has a much larger value than the flow resistance per unit length in the flow path 30.

4 illustrates embodiments in which a fluid resistance element is formed by connecting unit fluid resistance elements in series according to the present invention.

The fluid resistance element shown in FIG. 4 may constitute a unit fluid resistance element 50 formed as shown in FIG. 3, and the unit fluid resistance element 50 is connected in series between the flow path and the flow path to adjust the overall flow resistance. do.

Looking at the similarity between the electric and fluid areas, voltage corresponds to hydraulic pressure, current corresponds to flow rate per unit time, and electrical resistance corresponds to flow resistance, and the role in each area is very similar as shown in [Equation 1] below. Able to know.

Where R is the electrical resistance, V is the voltage difference, i is the current, R _f is the flow or hydraulic resistance, ΔP is the pressure difference, and Q is the flow rate.

As shown in FIG. 4, instead of the method of adjusting the cross-sectional area of the flow path in order to control the flow resistance in the flow path 30, the unit fluid resistance elements 41 are simply connected in series to provide the total flow resistance of each flow path 30. Adjust This simulates the series connection of resistors in the electrical domain.

When the fluid supply device for supplying the fluid at a constant hydraulic pressure or flow rate or pulsating hydraulic pressure or flow rate is connected to the fluid resistance element of FIG. 4, the flow rate / hydraulic controller may be configured to discharge the hydraulic pressure or flow rate of the supplied fluid. Can be.

5 illustrates a method of constructing a fluid resistance element by connecting unit fluid resistance elements in parallel according to the present invention.

As shown in Figure 5, in order to adjust the overall flow resistance of the flow path 30, instead of the method of adjusting the cross-sectional area of the flow path in accordance with the resistance value unit fluid resistance element 51 is connected in parallel. This simulates the parallel connection of resistors in the electrical domain.

When the fluid supply device for supplying fluid at a constant hydraulic pressure or flow rate or pulsating hydraulic pressure or flow rate is connected to the fluid resistance element of FIG. Can be.

6 illustrates a method of constructing a fluid resistance element by connecting a unit fluid resistance element in series and parallel mixing according to the present invention. In FIG. 6A, the unit fluid resistance element 53 is the same as the unit fluid resistance element 54 of FIG. 6B.

In this case, the flow or hydraulic resistance by the unit fluid resistance element 53 in FIG. 6A is the same as the flow or hydraulic resistance by the unit fluid resistance element 54 in FIG. 6B. In FIG. 6B, the unit fluid resistance element on the left side and the unit fluid resistance element on the right side each have a flow or hydraulic resistance that is half the size of the unit fluid resistance element 53 of FIG. 6A. This simulates the resistance of the same value by connecting the same size resistor in series and parallel in the electrical domain.

When the fluid supply device supplying the fluid at a constant hydraulic pressure or flow rate, or pulsating hydraulic pressure or flow rate is connected to the fluid resistance element of FIG. Can be.

7 is a reference diagram for explaining an equivalent circuit configuration according to the present invention. That is, FIG. 7 is a circuit diagram of a voltage and current divider for dividing a voltage or current at a predetermined ratio, and when a voltage or current source is connected between both ends 30 of two resistors R ₁ and R ₂ , Regardless of the absolute value, the voltage and current are divided according to the ratio of the resistance values. By applying the equivalent circuit of FIG. 7, a fluid mixer or a fluid distributor for mixing or dispensing a fluid at a predetermined ratio may be configured.

8 is a diagram illustrating a digital fluid logic circuit according to the present invention. FIG. 8A illustrates an embodiment of a fluid AND product, and FIG. 8B illustrates an embodiment of a OR logic device.

In the fluid logical multiplication device, as shown in FIG. 8A, a fluid supply source is connected to the input terminal 10 of the flow path 30, and fluid flows through one flow path 30 and two air vents through the flow path 30. Flows into (70, 71). The other end of the flow path 30 conducting with the input end 10 is electrically connected with the straight flow path 32 including the straight flow path 31 and the fluid resistance element 52 conducting with one vent 70. The other end of the flow path 32 is connected to the other straight flow path 33 which is connected to one vent 71 and the straight flow path 34 including the fluid resistance element 52 and the outlet 20. On / off valves 60A and 60B are connected to the air vents 70 and 71, and the flow rate or hydraulic pressure of the fluid discharged to the outlet 20 varies depending on the on / off operation of the on / off valves 60A and 60B. The output values '1' and '0' are determined by the magnitude of the fluid flow rate or the hydraulic pressure.

Fig. 8A is a fluid logical multiplication device. When the two on / off valves 60A and 60B are both ON, that is, when the on / off valves 60A and 60B both close the vents 70 and 71, the fluid supplied from the fluid source is flowed into the flow path ( 30) is discharged to the outlet 20 through the straight flow path 32, the fluid resistance element 52, and the straight flow path 34, the output value is '1' because of the large flow rate or hydraulic pressure of the fluid discharged to the outlet It becomes

On the other hand, one of the two on / off valves (60A, 60B) of the ON / OFF valve is ON (ON) and the other ON / OFF valve is OFF (OFF), or both on / off valves In the OFF state, that is, at least one of the on / off valves opens the vent, the fluid supplied from the fluid supply source is discharged to the vent through the straight passage 31 or the straight passage 33 having a relatively low resistance value. Therefore, the flow rate or hydraulic pressure of the fluid discharged to the outlet is reduced. Therefore, the output value at this time is '0'.

Meanwhile, in the fluid logic element, as shown in FIG. 8B, the fluid supply source and the on / off valves 60A and 60B communicate with the two input terminals 10A and 10B of the flow path 30. The fluid is discharged to the output terminal 20 through the 30. This output stage 20 is located at the center of two input stages 10A and 10B. In addition, the fluid resistance element 52 is positioned forward by the same distance based on the point where the input terminals 10A and 10B are coupled in the flow path 30 connecting the two input terminals 10A and 10B and the output terminal 20. .

Referring to the operation of the fluid logic element, the fluid logic element is the output terminal 20 when any one or two of the on / off valves 60A and 60B of the two input terminals 10A and 10B are turned on. ) Should be in the '1' state. Since both vents are opened when the on / off valves of the two input stages 10A and 10B are turned on, the fluid is input from the fluid supply source into the flow path 30 and discharged through the output stage 20. When one of the two on / off valves is on, one vent is opened so that fluid is input from the fluid source into the flow path and discharged through the output stage. Therefore, the output value at this time is '1'.

On the other hand, when both the on / off valves are in the off state, since both the vents are closed, no fluid is input from the fluid source into the flow path, and thus no fluid is discharged through the output stage. Therefore, the output value at this time is '0'.

Such a logic logic circuit can be combined to form various logic circuits.

Although the technical spirit of the present invention has been described above with reference to the accompanying drawings, it is intended to exemplarily describe the best embodiment of the present invention, but not to limit the present invention. In addition, it is obvious that any person skilled in the art may make various modifications and imitations without departing from the scope of the technical idea of the present invention.

As described above, according to the present invention, a complex fluid element and a fluid network using a unit fluid resistance element, unlike the conventional method of adjusting the width and depth of the flow path to adjust the flow or hydraulic resistance, a unit having a constant flow resistance Since the fluid resistance elements set the required flow or hydraulic resistance in the whole fluid system through series, parallel, or parallel-parallel mixed connection, the flow path can be easily established by simply placing the defined unit fluid resistance elements on the plane without complicated calculations. It can be designed and has the effect of reducing the influence of machining errors occurring during the manufacturing process.

The present invention can be used in a micro flow rate or a hydraulic regulator such as an insulin pump, which can be applied to a microbial sample injector and a micro drug mixer for implementing a closed artificial pancreas.

1 is a conceptual diagram showing a method for adjusting the flow resistance of a fluid according to the prior art,

2 is a view conceptually illustrating a method of controlling the flow resistance of a fluid proposed in the present invention,

3 is a view illustrating an embodiment of forming various unit fluid resistance elements by using a method of manufacturing a portion in which the cross-sectional area of the flow path is sharply reduced in order to control the flow resistance of the fluid according to the present invention;

4 is a view showing an embodiment of configuring a fluid resistance element through the series connection of the unit fluid resistance element according to the present invention,

5 is a view showing an embodiment of configuring a fluid resistance element through the parallel connection of the unit fluid resistance element according to the present invention,

FIG. 6 is a view showing embodiments of configuring a fluid resistance element through a series-parallel mixed connection of a unit fluid resistance element according to the present invention; FIG.

7 is a reference diagram for explaining an equivalent circuit configuration of a fluid resistance element according to the present invention;

8 is a diagram illustrating embodiments of a digital fluid logic circuit using the fluid resistance device according to the present invention.

Claims (8)

A fluid supply source for supplying a fluid, an entrance flow passage communicating with the fluid supply source, an exit passage through which the fluid is discharged, and a fluid configured to control the flow rate or hydraulic pressure of the fluid discharged into the exit passage, between the entrance passage and the exit passage; With a logic section, The fluid logic unit includes an on / off valve means for controlling whether the fluid is introduced or discharged to another vent, a plurality of fluid resistance elements forming at least two or more paths of the fluid supplied through the inlet passage; With a straight flow path, At least two unit fluid resistance elements connected in series, parallel or series-parallel mixing between the entry and exit channels and each having the same unit resistance value; According to the on / off control operation of the on / off valve means, the path of the fluid is changed to control the flow rate or oil pressure of the fluid discharged to the exit passage, and the output value according to the flow rate or oil pressure of the fluid discharged to the exit passage Digital fluidic circuit, characterized in that determined. The method of claim 1, wherein the fluid logic unit, A first linear flow path and a first fluid resistance element which separate and input a fluid supplied from the fluid supply source through the inlet flow path, and a second linear flow path which separates and inputs a fluid passing through the first fluid resistance element, respectively; And a first on / off valve for controlling whether the second fluid resistance element, the fluid passing through the first straight channel to the vent port, and the discharge path of the fluid passing through the second straight channel passage are discharged. And a second on / off valve for controlling, the outlet passage is connected to the second fluid resistance element to discharge the fluid passing through the first fluid resistance element and the second fluid resistance element to the outside, And the fluid resistive element comprises at least two or more unit fluid resistive elements connected in series, parallel or series-parallel mixing between any two flow paths and each having the same unit fluid resistance value. The method of claim 1, wherein the fluid logic unit, A first on / off valve for controlling the inflow of fluid in the first path supplied from the fluid supply source, a second on / off valve for controlling the inflow of fluid in the second path supplied from the fluid supply source; A first fluid resistance element connected between the first on / off valve and the outlet passage such that the fluid passing through the second on / off valve flows toward the outlet passage without being flowed back toward the first on / off valve; And a second fluid resistance element connected between the second on / off valve and the outlet passage such that the fluid passing through the first on / off valve flows toward the outlet passage without being flowed back toward the second on / off valve. , And the fluid resistive element comprises at least two or more unit fluid resistive elements connected in series, parallel or series-parallel mixing between any two flow paths and each having the same unit fluid resistance value. The digital fluid according to any one of claims 1 to 3, wherein the unit fluid resistive element forms a flow path having the same depth and width, and a column-shaped protrusion is formed in an island shape in the flow path at a predetermined position. Logic circuit. The digital fluid logic circuit of claim 4, wherein the protrusion has a cylindrical or polygonal column shape. The method of any one of claims 1 to 3, wherein the unit fluid resistance element forms a flow path having a predetermined geometric shape by changing the width at a predetermined position while forming a flow path having the same depth and width. Digital fluid logic circuit. The digital fluid logic circuit of claim 6, wherein the unit fluid resistance element has a geometrical shape having a relatively narrow width inside a flow path having the same depth. The digital fluid logic circuit of claim 6, wherein the unit fluid resistance element has a geometric shape that is relatively widened in a flow path having the same depth.