KR20100030310A - A continuous ejector with a parallel thermo-pneumatic pump - Google Patents

Abstract

PURPOSE: A continuous ejector equipped with a parallel-connected thermo pneumatic pump is provided to successively jet fluid by making two or more parallel-connected thermo pneumatic pumps have opposite periodicity. CONSTITUTION: A continuous ejector of fluid comprises a first thermo pneumatic pump(210), a second thermo pneumatic pump(220), an ejector(230), and a controller(240). The first thermo pneumatic pump includes a thin film(215). The second thermo pneumatic pump includes the thin film(225) and is connected with the first thermo pneumatic pump in parallel. The ejector inhales the fluid which is exhausted from the first thermo pneumatic pump and the second thermo pneumatic pump by turns and sprays the fluid. The controller creates a first control signal and a second controlling signal. The first control signal controls operation of the first thermo pneumatic pump. The second controlling signal controls the operation of the second thermo pneumatic pump.

Description

A continuous ejector with a parallel thermo-pneumatic pump

The present invention relates to a continuous injection device, and more particularly, to connect two or more thermopneumatic pumps in parallel to compensate for the periodicity of the discharge flow rate of a single thermopneumatic pump to enable continuous injection of microfluids. The present invention relates to a continuous spraying device having a connected thermopneumatic pump.

Recently, the interest and development of the microfluidic system has been increased internationally, and the demand for the microfluidic injection device has been expanded along with the miniaturization of various electronic devices. Such a microfluidic system is a very important system applied to a field such as a micro medical device or a micro fuel cell.

In microfluidic control technology on a biochip such as a protein chip or a DNA chip, it is important to move a microfluidic sample at an arbitrary position at a desired speed. The movement of the sample is mainly performed through a micropump and a microvalve. .

The micropump has been proposed in various ways according to its operation principle or application, but a thermo-pneumatic pump that implements injection by using the behavior of a thin film expanded by heat is mainly used.

1 is a cross-sectional view of a thermopneumatic pump having a thin film according to the prior art.

Referring to FIG. 1, the thermopneumatic pump 100 according to the related art includes a main body 110, a fluid inlet 120, a fluid outlet 130, a fluid transport path 140, a thin film 150, and a thin film heater 160. And a thermopneumatic medium 170. In addition, the fluid inlet 120 is connected to the inlet fluid storage tank 180, and the fluid outlet 130 is connected to the outflow fluid storage tank 190. The fluid outlet 130 may further include a nozzle 131.

First, when the fluid is filled between the fluid inlet 120 and the fluid outlet 130, there is no pressure difference, so the fluid will be stopped in the fluid transport path 140. When power is supplied to the thin film heater 160 in this state, the thermopneumatic medium 170 expands and the thin film 150 swells toward the fluid transport path 140. Therefore, the pressure of the fluid transport path 140 is increased, the fluid inlet 120 is closed and the fluid outlet 130 is opened so that the fluid moves toward the fluid outlet 130.

In this state, when the power supply to the thin film heater 160 is cut off, the thermopneumatic medium 170 contracts and the thin film 150 returns to its original position. Therefore, the pressure of the fluid transport path 140 is reduced. In this case, the fluid outlet 130 is closed and the fluid inlet 120 is opened to allow the fluid to flow into the fluid transport path 140 from the inflow fluid storage tank 180.

Thus, the fluid can be moved by repeating the process of expansion and contraction of the thin film. In this case, when the nozzle 131 is provided at the end of the fluid outlet 130, the discharge of the fluid may be smoothed and the back flow of the fluid may be prevented.

As described above, a general micro thermopneumatic pump has a relatively simple internal structure and is a micro injector that performs the role of a pump by repeating expansion and contraction of a thin film. Compared with other pumps, the pumping speed is relatively high and complicated internal devices are not required, so it is possible to manufacture a compact device at low cost.

However, due to the structural limitation of repeating expansion and contraction, the flow rate of the fluid outlet has a periodicity, and it is difficult to completely control the periodicity of such expansion and contraction. In addition, the thermopneumatic pump is difficult to control the precise flow rate due to the nonlinearity of the back pressure (acting on the thin film). Therefore, there is a problem that the thermopneumatic pump cannot be applied to a system requiring continuous and uniform injection.

The technical problem to be achieved by the present invention is to continuously connect the two or more thermopneumatic pumps in parallel to complement the periodicity of the discharge flow rate of a single thermopneumatic pump, continuous injection with a parallel connected thermopneumatic pump to enable continuous injection To provide a device.

Continuous injection device having a parallel-connected thermopneumatic pump according to the present invention for solving the technical problem, the first hot-pneumatic pump having a thin film, the second hot air having a thin film and connected in parallel with the first thermopneumatic pump And an ejector for alternately sucking and injecting the fluid discharged from the pressure pump, the first thermopneumatic pump, and the second thermopneumatic pump.

According to the continuous injection device having a parallel-connected hot pneumatic pump according to the present invention by controlling two or more hot pneumatic pumps connected in parallel to the opposite periodicity to compensate for the periodicity of each other to enable continuous injection of the fluid There is.

In addition, the continuous injection device having a thermo-pneumatic pump connected in parallel according to the present invention can be widely used in the field requiring precise control of the flow rate and continuous injection of the fluid, such as fuel supply and micro medical equipment of the micro fuel cell. There are advantages to it.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

Figure 2 is a schematic view of the continuous injection device with a thermopneumatic pump connected in parallel in accordance with the present invention.

Referring to FIG. 2, a continuous injection device having a thermopneumatic pump connected in parallel according to the present invention includes a first thermopneumatic pump 210, a second thermopneumatic pump 220, and an ejector 230.

The first thermopneumatic pump 210 includes a main body 211, a fluid inlet 212, a fluid outlet 213, a fluid transport path 214, a thin film 215, a thin film heater 216, and a thermopneumatic medium 217. It is provided. Meanwhile, the second thermopneumatic pump 220 includes a main body 221, a fluid inlet 222, a fluid outlet 223, a fluid transport path 224, a thin film 225, a thin film heater 226, and a thermopneumatic medium 227. ). Details of the first thermopneumatic pump 210 and the second thermopneumatic pump 210 are similar to those of the conventional thermopneumatic pump, and detailed descriptions thereof will be omitted.

The second thermopneumatic pump 220 is connected in parallel with the first thermopneumatic pump 210. That is, the fluid inlet 212 of the first thermopneumatic pump 210 and the fluid inlet 222 of the second thermopneumatic pump 220 are connected to the same fluid reservoir (not shown) and the first thermopneumatic pump 210 The fluid discharge port 213 and the fluid discharge port 223 of the second thermopneumatic pump 220 are combined in one in the ejector 230. Meanwhile, the fluid inlet 212 of the first thermopneumatic pump 210 and the fluid inlet 222 of the second thermopneumatic pump 220 may be separately connected to each fluid reservoir instead of one fluid reservoir.

The continuous injection device having a thermopneumatic pump connected in parallel according to the present invention further includes a control unit 240. The controller 240 generates a first control signal Con1 for controlling the operation of the first thermopneumatic pump 210 and a second control signal Con2 for controlling the operation of the second thermopneumatic pump 220. do.

When the first control signal Con1 is activated, the first thermopneumatic pump 210 operates, and when the second control signal Con2 is activated, the second thermopneumatic pump 220 operates. At this time, the first control signal Con1 and the second control signal Con2 have a phase difference of 180 degrees, and thus the first thermopneumatic pump 210 and the second thermopneumatic pump 220 operate alternately. That is, when the first thermopneumatic pump 210 operates, the second thermopneumatic pump 220 is in a stopped state, and when the second thermopneumatic pump 220 is operated, the first thermopneumatic pump 210 is stopped. Will be in.

Fluid alternately discharged from the first thermopneumatic pump 210 and the second thermopneumatic pump 220 is continuously injected to the outside through the ejector 230.

The ejector 230 may include a first fluid suction port 231 through which the fluid discharged from the first thermopneumatic pump 210 is sucked, and a second fluid suction port 232 through which the fluid discharged from the second thermopneumatic pump 220 is sucked in. And a nozzle 237 for continuously injecting fluid alternately sucked through the first fluid suction port and the second fluid suction port.

The ejector 230 may further include connection lines 235 and 236 which naturally guide the fluid introduced through the first fluid suction port 231 and the second fluid suction port 232 toward the nozzle 237.

 A first suction valve 233 is formed at the first fluid suction port 231 to adjust a suction flow rate of the fluid discharged from the first thermo pneumatic pump 210, and a second thermal pneumatic pressure is formed at the second fluid suction port 232. A second suction valve 234 is formed to adjust the suction flow rate of the fluid discharged from the pump 220.

The first suction valve 233 is opened when the first thermopneumatic pump 210 operates in response to the first control signal Con1 to suck the fluid discharged from the first thermopneumatic pump 210. do. In addition, the first suction valve 233 is closed when the second thermopneumatic pump 220 operates.

The second suction valve 234 is opened when the second thermopneumatic pump 220 operates in response to the second control signal Con2 to suck the fluid discharged from the second thermopneumatic pump 220. do. In addition, the second suction valve 234 is closed when the first thermopneumatic pump 210 operates.

Meanwhile, the first thermopneumatic pump 210 may further include a first power supply unit 218 that supplies power to expand the thin film 215 of the first thermopneumatic pump 210 to transfer fluid. The second thermopneumatic pump 220 may further include a second power supply unit 228 that supplies power to expand the thin film 225 of the second thermopneumatic pump 220 to transfer fluid. .

The first power supply unit 218 and the second power supply unit 228 are shown separately provided in the first thermopneumatic pump 210 and the second thermopneumatic pump 220, respectively, but may be integrated into one power supply unit. It may be.

As a signal for controlling the operation of the first suction valve 233, the first control signal Con1, which is the same as the signal for controlling the operation of the first thermopneumatic pump 210, is used. However, the first control signal ( It is also possible to use a separate control signal from Con1).

In addition, the second control signal Con2, which is the same as the signal for controlling the operation of the second thermopneumatic pump 220, is used as a signal for controlling the operation of the second suction valve 234. It is also possible to use a separate control signal different from the signal Con2.

Meanwhile, in FIG. 2, only two thermopneumatic pumps are connected in parallel, but this is only an example, and the present disclosure is not limited thereto, and two or more thermopneumatic pumps may be connected in parallel.

As described above, the continuous injection device having the thermopneumatic pump connected in parallel according to the present invention connects the thermopneumatic pump to the fluid reservoir in parallel and controls the thermopneumatic pump connected in parallel through the control signal of the controller to alternately operate. This compensates for the periodicity of a single thermopneumatic pump to enable continuous injection of the fluid.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

1 is a cross-sectional view of a thermopneumatic pump having a thin film according to the prior art.

Figure 2 is a schematic view of the continuous injection device with a thermopneumatic pump connected in parallel in accordance with the present invention.

Claims (8)

In the injection device of a fluid A first thermopneumatic pump having a thin film; A second thermopneumatic pump having a thin film and connected in parallel with the first thermopneumatic pump; And And an ejector for alternately inhaling and injecting the fluid discharged from the first thermopneumatic pump and the second thermopneumatic pump. The method of claim 1, A first control signal for controlling the operation of the first thermopneumatic pump; And And a control unit for generating a second control signal for controlling the operation of the second thermopneumatic pump. The method of claim 2, The first control signal and the second control signal has a phase difference of 180 degrees so that the first thermopneumatic pump and the second thermopneumatic pump can be operated alternately. Injector. The method of claim 3, wherein the ejector, A first fluid suction port through which the fluid discharged from the first thermopneumatic pump is sucked; A second fluid suction port through which the fluid discharged from the second thermopneumatic pump is sucked; And And a diffuser for continuously injecting fluid alternately sucked through the first fluid suction port and the second fluid suction port. The method of claim 4, wherein The first fluid suction port further includes a first suction valve, And said second fluid suction port further comprises a second suction valve. The method of claim 5, The first suction valve is opened when the first thermopneumatic pump operates in response to the first control signal, and is closed when the second thermopneumatic pump operates. The second suction valve is opened when the second thermopneumatic pump operates in response to the second control signal, and is closed when the first thermopneumatic pump operates. Continuous injection device provided with. The method of claim 6, wherein the ejector is And a nozzle for guiding fluid introduced through the first fluid suction port and the second fluid suction port toward the diffuser. The method according to claim 6 or 7, The first thermopneumatic pump further includes a first power supply unit configured to supply power to expand a thin film provided in the first thermopneumatic pump to transfer fluid. The second thermopneumatic pump further includes a second power supply unit for supplying power to expand the thin film provided in the second thermopneumatic pump to transfer fluid. Continuous jet device.

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