KR101064390B1 - Infusion apparatus's parts wear test device - Google Patents

Abstract

The present invention relates to a wear test apparatus for injector parts for measuring the wear of the stick, which is the main part of the injector for injecting drugs, to be reflected in the production of high quality sticks.
The wear test apparatus of the injector component according to the present invention is to test the stick 100 applied to the drug injection device, the cradle (2) to which the stick 100 is coupled in a horizontal state; A jig (3) coupled to the stick (100) in friction contact; A driving unit (4) for causing friction with the stick (100) by moving the jig (3) forward and backward within a limited section; A measuring unit 5 measuring a displacement value of the stick 100; A controller 15 for calculating a displacement value measured by the measurement unit 5; It is configured to include a display unit 16 connected to the control unit 15 to display the calculated value to recognize.

Description

Abrasion test device for injector parts {INFUSION APPARATUS'S PARTS WEAR TEST DEVICE}

The present invention relates to a wear test apparatus for injector parts, and more particularly, to measure the wear of the stick, which is a main part of the injector for injecting drugs, to be reflected in the production of higher quality sticks based on the improved data. It relates to an abrasion test apparatus for an injection part.

In general, mesotherapy is a method of injecting a drug into the dermal layer of the skin using a microneedle or applying injection stimulation.

Drug injectors applied to mesotherapy are devices that inject drugs into the skin at high speed using electricity or pneumatic pressure, also called 'meso gun'.

There are two types of conditions: electricity using electricity and pneumatic using air pressure.

Compared with the electric main condition, the pneumatic main condition is generally preferred to the electric main condition because the electric power is provided with sufficient power and the temperature rise is small even after continuous use for a long time.

An example of such pneumatic condition is disclosed in Korean Patent No. 10-0597814.

However, the prior patent has a problem of creating a patient's rejection or fear as the needle of the syringe is formed as a gun type protruding outward.

In this regard, the present applicant has filed a “drug infusion device” for forming a rod-shaped structure to minimize the fear and rejection of the drug injection device as a Korean Patent Application No. 2010-0031338.

Looking at the prior patent on the basis of Figure 1, the case 10 is formed in the shape of a rod, the syringe support 12 is provided on the upper portion of the case 10, the syringe 11 is mounted, compresses air to generate a constant pneumatic Compressor 13, a pair of solenoid valves 14 to open and close to selectively deliver the pneumatic pressure generated by the compressor 13, the needle insertion cylinder 15 and the drug injection cylinder provided in the case 10 (16) and the exercise transmission unit 20 to transmit the force by the stretching operation of the drug injection cylinder 16 to the rear end of the syringe 11 to inject drugs, the exercise transmission unit 20 is As shown in FIG. 2, it includes a stick 21 for moving the syringe support 12.

The stick 21 is a consumable that needs to be replaced after a predetermined number of times since wear and tear occurs because the stick 21 repeatedly moves back and forth in contact with the friction plate.

However, at present, there is no test data on the difference in wear degree according to the material of the stick, so it is not possible to predict the service life, there is a problem that the stick may be damaged during use.

In addition, in order to improve durability of the stick, it is necessary to grasp the properties of each material in advance and predict deformation and damage due to age and wear.

As is known, the frictional wear test requires a variety of types of driving such as rotational motion, linear motion, vibration, and impact in addition to the contact of two materials in order to understand the wear resistance of materials.

This friction abrasion test is carried out on various materials such as coated surfaces of ultrathin films, soft materials, and hard materials.

In general, abrasion test is performed by the contact of two objects, and the rotation of the motor is transmitted by gears or pulleys to perform friction movement.

However, when the motor is used, there was a problem that can not be measured for a long time due to heat generation.

The present invention has been made to solve the above problems of the prior art, by measuring the wear degree for the stick, which is a major component of the drug injection device described in the applicant's prior patents by predicting the change according to the material of higher quality products It is an object of the present invention to provide an apparatus for testing wear of injector components, which can produce a product and improve the reliability of the drug injecting device by inducing a replacement before the stick is broken.

In addition, the present invention can be tested for a long time by using the pneumatic pressure and can evaluate the wear of the material at a faster speed than the existing invention, and can be driven by a single pneumatic device to drive a plurality of test devices economical injection Another object is to provide an apparatus for testing the wear of mechanical components.

The purpose as described above is to test a stick applied to a drug injection device, which includes: a base; A cradle mounted on the base and to which the stick is coupled in a horizontal state; A jig coupled to the stick and in frictional contact; A driving unit for causing friction with the stick by moving the jig forward and backward within a limited section; A measuring unit measuring a displacement value of the stick; A control unit calculating a displacement value measured by the measuring unit; It can be achieved by the wear test apparatus of the injector component, characterized in that it comprises a display unit connected to the control unit to display the calculated value to recognize.

The cradle is characterized in that the space is formed inside, the front and rear support is formed through the hole is formed so that the stick is coupled in a horizontal state through the through hole.

The jig has a coupling hole coupled to the stick in a loose state is formed in the upper portion, the lower portion is connected to the drive unit, is installed in the cradle, the lower end of the friction plate is coupled to the end of the shaft, the jig is loose The combination is characterized in that the coupling hole is friction with the outer circumferential surface of the stick during the forward and backward movement to cause wear.

The drive unit is a pneumatic cylinder operated by pneumatic, characterized in that composed of a body connected to the pneumatic hose, a piston inserted into the body and a shaft connected to the piston.

According to the present invention, by measuring the wear degree of the stick, which is the main component of the drug injection device, it is possible to predict the durability of the material and its life, thereby producing a higher quality product, and inducing the stick to be replaced before the stick is broken. There is an effect that can improve the reliability of the drug injection device.

1 is a view showing a drug injection device that the applicant previously filed,
Figure 2 is a view showing the wear test apparatus of the component for the injector according to the present invention,
3 is a view showing operation of a part of FIG. 2;
Figure 4 is a graph showing the wear test results using the wear test apparatus of the injection component parts according to the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a view showing the wear test apparatus of the injector component according to the present invention, Figure 3 is a view showing the operation of the part of Figure 2, Figure 4 is using the wear test apparatus of the injector component according to the present invention A graph showing the wear test results.

As shown in Fig. 2 and Fig. 3, the wear test apparatus (A) of the injector component according to the present invention is for testing the stick (100) applied to the drug injection device, the base (1); A cradle (2) installed on the base (1) and to which the stick (100) is coupled in a horizontal state; A jig (3) coupled to the stick (100) in friction contact; A driving unit (4) for causing friction with the stick (100) by moving the jig (3) forward and backward within a limited section; A measuring unit 5 measuring a displacement value of the stick 100; A controller 15 for calculating a displacement value measured by the measurement unit 5; It is configured to include a display unit 16 connected to the control unit 15 to display the calculated value to recognize.

The base 1 has a plate shape having a constant area, and at one end thereof, a backward preventing member 10 supporting the rear end of the stick 100 is vertically formed to prevent backward of the stick 100, and is spaced apart from the holder. (2) is mounted, and the measuring part 5 is attached to the other side.

The cradle 2 has a space 20 formed therein, the front support 13 formed with a through hole 30, the rear support 10 formed with a sleeve 7 is formed, the stick 100 through 30 and the sleeve 7 are coupled in a horizontal state.

The front support 13 is attached with a stopper 6 of constant length to limit excessive forward operation of the jig 3.

In addition, the protrusion 9 is formed to limit excessive advancement of the jig 3 by being in contact with the outer surface of the rear support 10 in one portion of the stick 100.

The jig 3 has a coupling hole 30 having a larger diameter than the stick 100 is formed in the upper portion so that the jig 3 is loosely coupled to the stick 100, and the lower portion is connected to the shaft 41 of the driving unit 4. It is installed in the holder (2).

A spring 12 is interposed between the jig 3 and the front support 13, and the spring 12 is coupled to the outside of the stick 100.

Therefore, as the shaft 41 of the driving unit 4 moves forward, as shown in FIG. 3B, the jig 3 is inclined to contact the stick 100 with the upper and lower portions of the coupling hole 30.

When the shaft 41 of the driving unit 4 moves backward, as shown in FIG. 3 (a), the jig 3 stands up, is spaced apart from the stick 100, and is driven backward by the repulsive force of the measuring unit 5.

The drive unit 4 is a pneumatic cylinder operated by pneumatic pressure, and is composed of a piston inserted into the pneumatic hose 11 and a shaft 41 connected to the piston.

The lower end of the jig 3 is coupled to the end of the shaft 41. The jig 3 is coupled in a loose state so that the engagement hole rubs with the outer circumferential surface of the stick 100 when the forward and backward movements cause wear.

The measurement unit 5 is for measuring the displacement value of the stick 100, a linear displacement meter is formed therein is a spring 52 mounted on the rod 52 exposed to the outside, the end of the rod 52 is stick The support 100 is supported at one end so that deformation of the stick 100 can be detected.

One end of the stick 100 is supported by the rod 52 and the other end is supported by the reverse guard 10.

The control unit 15 is for calculating the displacement value measured by the measuring unit 5, the LABVIEW program is mounted, and controls the drive unit 4 to be driven to select 100 to 420 times per minute In addition, the moving distance of the stick 100 measured by the linear displacement meter, which is the measuring unit 5, is changed from an analog signal to a digital signal to store data.

The measuring method of the wear test apparatus (A) of the component for injectors according to the present invention configured as described above is as follows.

The drive unit 4 is driven by the signal of the controller 15 so that the shaft 41 moves forward, and the stick 100 also moves forward by being in close contact with the outer circumferential surface of the stick 100 while the jig 3 is inclined. Works.

On the contrary, when the driving unit 4 is driven backward, the jig 3 stands up and is spaced apart from the stick 100, and the stick 100, which is in a free state, is driven backward by the repulsive force of the spring 12 of the measuring unit 5. Done.

In the measuring unit 5, the forward and backward moving distances of the sticks 100 are measured by analog signals.

Thereafter, the controller 15 converts the analog signal into a digital signal, stores data, and displays data about the number of round trips and the round trip distance of the stick 100 on the display unit 16 to show the number and the graph.

In addition, the LABVIEW program mounted on the controller 15 sets the maximum movement distance of the stick 100 to set the measured value.

Meanwhile, the frictional contact between the jig 3 and the stick 100 is performed about 100 to 420 times per minute, so that the frictional contact occurs between 6000 and 25200 times per hour.

As shown in FIG. 3, the outer peripheral surface of the stick 100 is worn out due to the inclination of the jig 3.

That is, as the number of frictional contacts increases, the deeper the trench, the inclination of the jig 3 is increased. On the other hand, the movement distance of the stick 100 is shortened and displacement occurs.

When the stick 100 does not reach the measured value for 1 second, the operation of the driving unit 4 immediately stops and the round trip frequency measurement is stopped.

The measured value is evaluated by the number of round trips compared to the measurement time to evaluate the wear performance.

Figure 4 is a graph showing the wear test results of the stick 100 of the skd-11 material. The x-axis represents time and the y-axis represents displacement.

As shown in the graph, it can be seen that there is no displacement, that is, no wear, from 300,000 to 700,000 times.

Therefore, the stick of skd-11 material can be seen as the age of 300,000 ~ 700,000 times.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it will be readily apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the invention, all such modifications and modifications being attached It is obvious that the claims belong to the claims.

1: expectation 2: cradle
3: jig 4: driving part
5 measuring part 6 stopper
7: sleeve 8: rear support
9: protrusion 10: reverse guard
11: Pneumatic hose 12: Spree
13: front support 15: control unit
16 display unit

Claims (6)

To test the stick 100 applied to the drug injection device,
Expectation (1);
A cradle (2) installed on the base (1) and to which the stick (100) is coupled in a horizontal state;
A jig (3) coupled to the stick (100) in friction contact;
A driving unit (4) for causing friction with the stick (100) by moving the jig (3) forward and backward within a limited section;
A measuring unit 5 measuring a displacement value of the stick 100;
A controller 15 for calculating a displacement value measured by the measurement unit 5;
A display unit 16 connected to the control unit 15 to display the calculated value so that the calculated value can be recognized
Abrasion test device for injector parts, characterized in that it comprises a. The method of claim 1,
The cradle 2
A front support 13 having a through hole 30 to which the stick 100 is coupled;
A rear support (10) having a sleeve (7) to which the stick (100) is coupled;
A stopper 6 attached to the front support 13 to limit the operation of the jig 3.
Abrasion test device for injector parts, characterized in that it comprises a. The method of claim 1,
The jig 3 is
A coupling hole 30 coupled to the stick 100 in a loose state is formed at an upper portion thereof, and a lower portion thereof is connected to the driving unit 4 and is installed inside the holder 2.
Spring 12 is installed between the jig (3) and the front support (13),
Apparatus for testing wear of the injector component, characterized in that the spring (12) is coupled to the outside of the stick (100). The method of claim 1,
The drive unit 4 is a pneumatic cylinder operated by pneumatic pressure, and includes a piston coupled therein and a shaft 41 connected to the piston, and the lower portion of the jig 3 is coupled to the shaft 41. Abrasion test device for injector parts. The method of claim 1,
The measuring unit 5 is a linear displacement gauge for measuring the displacement value of the stick 100, the end of the rod 52 of the linear displacement gauge is supported on the end of the stick 100 to detect the deformation of the stick 100 Abrasion test device for injector parts, characterized in that. The method of claim 1,
The control unit 15
Apparatus for abrasion testing of components for injectors, characterized in that the LABVIEW program for measuring and calculating the wearability of the stick 100 is mounted.

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