KR102352188B1 - Compact mechanical pumps with constant flow - Google Patents

Abstract

The present invention includes a cylinder having through-holes formed at both ends, respectively, the fluid is accommodated therein; a plunger provided to be flowable inside the cylinder and having a flow hole through which the fluid passes; a first push bar connected to one side of the plunger, provided to be retractable from the through hole, and for pressing the plunger by the force of a spring provided at the rear; It is connected to the other side of the plunger corresponding to the first pusher, is provided retractably in the through hole, and comprises a second pusher for pressing the suction of the syringe mounted in front of the cylinder, and the spring When the plunger is pressed with the first pusher by the force of It is configured to discharge the chemical, and the inner surface of the cylinder further comprises a bypass groove to reduce the flow load of the fluid when the plunger moves along the cylinder. It relates to a small mechanical damper that can maintain a constant flow rate of drug discharge in a syringe by pumping it at a constant force and speed through a fluid flow, and maintain a constant flow rate that can reduce manufacturing costs according to a simple structure and miniaturization.

Description

Compact mechanical pumps with constant flow

The present invention relates to a small mechanical damper that maintains a constant flow rate, and more specifically, by pumping at a constant force and speed through the force of a spring and a fluid flow in the damper, it is possible to maintain a constant flow rate of drug discharge in the syringe, and has a simple structure And it relates to a small mechanical damper that maintains a constant flow rate that can reduce manufacturing costs according to miniaturization.

In general, microfluidic devices (devices designed to manipulate microfluids) generate It is a device that uses phenomena.

For example, by micro-patterning a fluid channel inside a fluid device, cells present in the blood may be separated by size using a flow field generated thereby.

At this time, the flow rate of the injected liquid must be constant, and in response to this, an expensive electric damper is required to inject a constant flow rate, so there is a limit to the portability of the fluid device. It is a difficult situation.

KR 10-1492231 B1 KR 10-2011-0082671 A KR 10-1888352 B1

In order to solve the above problems, the present invention includes a plunger having a flow hole and a damper having a groove. The purpose of this is to provide a small mechanical damper that maintains a constant flow rate that can be pumped to maintain a constant flow rate of drug discharge in the syringe, is easy to carry due to miniaturization, and has a simple structure to reduce manufacturing costs. .

In order to achieve the above object, the present invention is a cylinder having through-holes formed at both ends, respectively, the fluid is accommodated therein; a plunger provided to be flowable inside the cylinder and having a flow hole through which the fluid passes; a first push bar connected to one side of the plunger, provided to be retractable from the through hole, and for pressing the plunger by the force of a spring provided at the rear; It is connected to the other side of the plunger corresponding to the first pusher, is provided retractably in the through hole, and comprises a second pusher for pressing the suction of the syringe mounted in front of the cylinder, and the spring When the plunger is pressed with the first pusher by the force of It provides a small mechanical damper that maintains a constant flow rate, characterized in that the chemical liquid is discharged.

And, the inner surface of the cylinder is characterized in that when the plunger moves along the cylinder, a bypass groove is further formed to reduce the flow load of the fluid.

At this time, the groove is made of a groove having a predetermined thickness on the inner surface of the cylinder, characterized in that it is formed in a triangular shape gradually widening along the longitudinal direction of the cylinder.

On the other hand, on both sides of the cylinder, an inlet and an outlet through which the fluid is introduced/discharged are further formed in the cylinder, and are respectively connected to the inlet and the outlet and are directed in one direction by the spring through the inlet/discharge of the fluid. It is characterized in that a dispenser for returning the positioned plunger to its original position in the spring direction is further provided.

By providing the present invention configured as described above, it is possible to maintain a constant flow rate of drug discharge in the syringe, and there is an effect of reducing portability and manufacturing cost according to miniaturization.

1 is an exemplary view of the configuration and operating state showing a general mechanical damper including a spring.
Figure 2 is a block diagram showing a small mechanical damper that maintains a constant flow rate according to the present invention.
Figure 3 is a cross-sectional view showing the operating state of the small mechanical damper to maintain a constant flow rate according to the present invention.
Figure 4 is a cross-sectional view showing another embodiment of a small mechanical damper that maintains a constant flow rate according to the present invention.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the same technical field can easily carry out the present invention.

The present invention relates to a mechanical damper that can inject a chemical liquid (B) into the human body at a constant flow rate by the force of the spring 500. force can be applied.

This force (F) is determined by the compressed distance and spring constant according to Hooke's Law.

If, as in (a) of Figure 1, if the drug solution (B) in the syringe 600 is discharged directly using the force of the spring 500, the force applied by the spring 500 over time and the syringe 600 It can be seen that the flow rate discharged from the syringe 600 also decreases with time, as shown in (b) of FIG. 1 because the internal pressure decreases.

Accordingly, the present invention requires a component that can serve as a damper between the spring 500 and the syringe 600 .

In contrast, the small mechanical damper that maintains a constant flow rate of the present invention includes a cylinder 100, a plunger 200, a first and second pusher 300.400, and a spring 500, as shown in FIGS. can be configured.

Referring to FIG. 2 , the cylinder 100 has a space in which the fluid A is accommodated, and through-holes 110 may be formed at both ends, respectively.

The plunger 200 is provided inside the cylinder 100 , but is preferably provided to be movable along the longitudinal direction of the cylinder 100 .

In addition, a flow hole 210 is formed in the plunger 200 so that the fluid A accommodated in the cylinder 100 can pass through and flow in the opposite side of the cylinder 100 with respect to the plunger 200 . can

That is, the plunger 200 may move forward/reverse along the cylinder 100 as the fluid A flows through the flow hole 210 .

In this case, the first push rod 300 may be connected to or integrally extended to one side of the plunger 200 , and may be provided in the through hole 110 to be retractable.

In addition, a spring 500 is fixed to the rear of the cylinder 100 and configured to push the first push rod 300 by force.

Accordingly, the first push rod 300 may be moved by the force of the spring 500 to press the plunger 200 .

In addition, the second push bar 400 may be connected to the other side of the plunger 200 corresponding to the first push bar 300 , and may be provided to be retractable from the through hole 110 .

Accordingly, by the movement of the plunger 200 , the second push rod 400 may press the suction cup 620 of the syringe 600 mounted in the front of the cylinder 100 .

That is, when the plunger 200 is pressed with the first push rod 300 by the force of the spring 500 , the damping action by the flow field of the fluid A passing through the flow hole 210 of the plunger 200 . As a result, the second push rod 400 constantly presses the suction cup 620 of the syringe 600 to discharge the chemical solution B at a constant flow rate through the discharge port 630 of the syringe 600 .

Here, a bypass groove 120 may be further formed on the inner surface of the cylinder 100 to reduce the flow load of the fluid A when the plunger 200 moves along the cylinder 100 . have.

In addition, the groove 120 may be formed as a groove having a predetermined thickness on the inner surface of the cylinder 100 , and may be formed in a triangular shape gradually widening along the longitudinal direction of the cylinder 100 .

The present invention configured as described above will be described with reference to FIG. 3 in its operating state.

The force of the plunger 200 is applied in the opposite direction by the force of the spring 500, and the force of the plunger 200 within the cylinder 100 becomes weaker as the relative position of the plunger 200 moves away from the spring 500. .

That is, when the force (F _{0 ) applied by the spring 500 is the strongest, the force (F D0} ) applied in the opposite direction of the cylinder 100 is the strongest, and the force (F ₁ , F ₂ ) of the spring 500 is As it weakens, the force applied by the plunger 200 (F _D1 , F _D2 ) is also weakened.

Through this principle, when the plunger 200 serves to constantly maintain the pressure applied to the inside of the syringe 600 by the spring 500, the chemical solution B can be discharged at a constant flow rate due to the constant pressure. .

The principle that the force applied by the damper in the vast direction of the spring 500 changes according to the position of the plunger 200 is as follows.

_{The force F D} of the plunger 200 applied by the damper is formed according to the position of the plunger 200 while the fluid A passes through the flow hole 210 formed in the plunger 200 .

When the spring 500 applies a force to the right at the initial position t ₀ of the plunger 200, the plunger 200 also moves to the right while applying pressure to the fluid A in the cylinder 100, as a result The fluid A moves to the left through the flow hole 210 of the plunger 200 .

As the diameter of the flow hole 210 decreases, the resistance of the flow increases, and the force of the plunger 200 against the spring 500 increases.

While the fluid A flows to the left through the flow hole 210 , the fluid A moves along the groove 120 formed in the inner wall of the cylinder 100 .

When the fluid A flows through the flow hole 210 and the groove 120 , the fluid resistance is directly proportional _{to the force F D that the plunger 200 applies to the syringe 600 .}

The cross-sectional area of the groove 120 is formed to gradually become wider toward the right side of the cylinder 100, and as the plunger 200 moves to the right, the force F _D decreases.

Another force with respect to the force F _D is the frictional force generated in the area where the plunger 200 closes and the wall inside the cylinder.

Since this force also decreases as the plunger 200 moves to the right, the force F _D is ultimately reduced.

That is, in the initial position t _{0 of the plunger 200, the force F 0} of the spring 500 _{is strong, but the force F D0} of the plunger 200 due to the fluid resistance of the fluid A corresponds to the syringe. At the discharge flow rate P ₀ of 600 and the final position t ₂ of the plunger 200, the force F ₂ of the spring 500 is weak, but the plunger 200 due to the fluid resistance of the fluid A The force (F _D2 ) of the flow rate (P ₂ ) discharged to the weak seabed syringe 600 may be provided in the same way.

On the other hand, as shown in FIG. 4 as another embodiment of the above configuration, both sides of the cylinder 100 have an inlet 130 through which the fluid A is introduced/discharged inside the cylinder 100 and An outlet 140 is further formed, and the plunger 200 is connected to the inlet 130 and the outlet 140, respectively, and positioned in one direction by the spring 500 through the inlet/discharge of the fluid A. A dispenser 700 for returning to its original position in the direction of the spring 500 may be further provided.

That is, after all the chemical liquid B of the syringe 600 is discharged by the action of the damper by the force of the spring 500, the used syringe 600 is removed and a new syringe 600 is placed back in the cylinder. By injecting the fluid A through the inlet 130 on the right side of 100 , the plunger 200 may return to the left position of the cylinder 100 .

The inlet 130 and the outlet 140 have a check valve 800 or block that blocks the flow to the dispenser 700 side through the inlet 130 and the outlet 140 by the pressure generated in the cylinder 100, respectively. A valve is preferably provided.

By providing the present invention configured as described above, it is possible to maintain a constant flow rate of drug discharge in the syringe, and there is an effect of reducing portability and manufacturing cost according to miniaturization.

The terms and words used in the present specification and claims described above should not be construed as being limited to conventional or dictionary meanings, and the present inventors have adequately defined the concept of terms to describe their invention in the best way. It should be interpreted as meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined as

Accordingly, the configurations shown in the drawings and embodiments described in this specification are merely one of the most preferred embodiments of the present invention, and do not represent all of the technical spirit of the present invention, so they can be substituted at the time of the present application. It should be understood that there may be various equivalents and variations that exist.

100: cylinder
110: through hole
120: groove
130: inlet
140: outlet
200: plunger
210: flow hole
300: the first mill
400: second push rod
500: spring
600: syringe
610: housing
620: suck
630: outlet
700: dispenser
800: check valve
A: fluid
B: drug solution

Claims (4)

a cylinder 100 having through-holes 110 formed at both ends, respectively, the fluid A is accommodated therein;
a plunger 200 provided movably inside the cylinder 100 and having a flow hole 210 through which the fluid A passes;
A first push rod (300) connected to one side of the plunger (200), provided retractably in the through hole (110), and for pressing the plunger (200) by the force of a spring (500) provided at the rear side (300) Wow;
The syringe 600 is connected to the other side of the plunger 200 in correspondence to the first push rod 300 , is retractably provided in the through hole 110 , and is mounted in front of the cylinder 100 . It is configured to include a second push rod 400 for pressing the suction 620,
When the plunger 200 is pressed with the first push rod 300 by the force of the spring 500, the flow field of the fluid A passing through the flow hole 210 of the plunger 200 acts as a damping action. The second push rod 400 constantly presses the suction cup 620 of the syringe 600 to discharge the chemical solution B at a constant flow rate through the discharge port 630 of the syringe 600,
On the inner surface of the cylinder 100,
When the plunger 200 moves along the cylinder 100, a bypass groove 120 is further formed to reduce the flow load of the fluid A,
The groove 120,
A small mechanical damper that maintains a constant flow rate, characterized in that it is made of a groove having a predetermined thickness on the inner surface of the cylinder (100), and is formed in a triangular shape that gradually widens along the longitudinal direction of the cylinder (100).
delete delete The method according to claim 1,
On both sides of the cylinder 100,
An inlet 130 and an outlet 140 through which the fluid A is introduced/discharged are further formed in the cylinder 100, and are connected to the inlet 130 and the outlet 140, respectively, and the fluid A ) to maintain a constant flow rate, characterized in that the dispenser 700 is further provided to return the plunger 200 positioned in one direction by the spring 500 to the original position in the spring 500 direction through the inlet/discharge Small mechanical dampers.

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