KR102104080B1 - Sonic vibration device for painless syringe and painless sylinge having the same - Google Patents

Abstract

The present invention provides a fine vibration to the injection surface in the subcutaneous tissue and the skin surface to be injected during painless injection to further alleviate the pain, and enables the injection of the injected drug into the subcutaneous tissue and absorption into the body more quickly. Noise relates to a sound wave generator for a painless syringe that can be significantly reduced and a painless syringe having the same. According to the present invention, the sonicator is provided on one side of the painless injection unit to which the injection unit is detachably coupled to oscillate sound waves to vibrate the injection solution injected into the skin and subcutaneous tissue; A control circuit unit for controlling the sound wave generator in association with an operation operation of the operation unit constituting the painless injection unit; And a power source for supplying power to the sound wave oscillator. A sound wave oscillation device for a painless syringe comprising a painless syringe having the same is provided.

Description

A sonic oscillation device for a painless syringe and a painless syringe having the same {SONIC VIBRATION DEVICE FOR PAINLESS SYRINGE AND PAINLESS SYLINGE HAVING THE SAME}

The present invention relates to a sound wave oscillation device for a painless syringe and a painless syringe having the same, and more particularly, to provide a fine vibration to the injected drug injected into the skin surface and subcutaneous tissue injected during painless injection to further relieve pain and avoid It relates to a sonic oscillation device for a painless syringe and a painless syringe having the same, so that injection of the injected drug into the tissue and absorption into the body can be achieved more rapidly, and noise generated can be significantly reduced.

In general, a syringe is thought to be a tool used by a nurse or doctor to inject medicine directly into a patient's body.

1 is a block diagram showing a general syringe. A conventional syringe is provided with a single injection needle (1) as shown in Figure 1, by pressing the piston (2) to inject the drug in the cylinder (3) to the patient.

However, users who need injections several times a day, for example, in the case of diabetic patients, should be injected frequently during nursing at home, not in a hospital. In addition to having to use the injection, it is also difficult for the person himself to inject the injection.

In addition, even in the case of a general patient, when attempting to inject himself or herself and injecting a child with extreme movement, there is also a significant difficulty in injecting without excellent injection technology, and in the case of a thick needle, pain when penetrating the skin There is a problem that can not be solved.

On the other hand, as a part of solving this problem, a syringe is inserted into the tip of the syringe, or a thin hole (about 0.1 mm diameter) instead of the needle, so that the ordinary syringe can be inserted into the sleeve for instant injection due to spring elasticity or air pressure. Painless syringes have been proposed that can be prepared and exert pressure from the back of the syringe to penetrate the injection solution into the skin.

However, such a conventional painless syringe, for example, in the case of a painless syringe that strikes a piston by a spring-blasting method, requires a very large force to compress it when compressing and loading the spring in order to make a momentary blow. jig) should be used, which is a very cumbersome and time-consuming problem in use, because it must be used after combining the loading jig every time during compression loading and then separating.

In addition, the conventional spring-ball-type painless syringe has a problem in that it cannot be applied when several injections of a small amount of injection liquid, such as skin beauty, are injected in a manner that the injection solution is injected at once when the blow bundle is hit once. The hitting sound generated during the hitting causes a discomfort to the operator, and in particular, animals, such as young birds, which are very sensitive to sound, die due to the hitting sound.

On the other hand, as another example of a conventional painless syringe, in the case of a painless syringe that strikes a piston by an air extrusion method, it does not have sufficient extruding force to strike the piston, and a large blown sound is generated by extrusion of compressed gas in the extrusion path, such as discomfort It will cause problems.

In addition, the conventional painless syringe simply injects the injection drug into the subcutaneous tissue only by pressing force, and because it is injected at a rapid rate, the injection solution may not be sufficiently injected into the subcutaneous tissue and some may protrude to the outside, and is sensitive to pain. There is a problem that can cause pain relatively relatively to the patient or the animal.

(Document 1) Republic of Korea Patent Registration No. 10-0777146 (Nov. 19, 2007 announcement) (Document 2) Republic of Korea Utility Model Publication No. 20-1994-0006930 (announced on October 7, 1994) (Document 3) Republic of Korea Utility Model Publication No. 20-1997-0001378 (announced on March 4, 1997) (Document 4) Republic of Korea Patent Publication No. 10-2001-0067582 (2001.07.13. Published)

Therefore, the present invention for solving the above-mentioned conventional problems, by providing a fine vibration on the skin surface to be injected during painless injections to further alleviate pain, and to inject the injected drug into the subcutaneous tissue and absorb it into the body more quickly An object of the present invention is to provide a sonic oscillation device for a painless syringe and a painless syringe having the same.

In addition, the present invention can significantly reduce the noise generated while having a sufficient pressure to inject the injection drug rapidly during the instant injection of the injection drug through pneumatic, to minimize the impact of noise on the subjects, such as infants, especially due to impact noise An object of the present invention is to provide a painless syringe equipped with a sound wave generator that can be very useful for animal procedures such as small bird animals that can die.

In addition, another object of the present invention is to provide a painless syringe having a sound wave oscillation device that is convenient to use and can be used in various fields such as medical treatment of humans and animals as well as skin beauty, thereby improving the usability.

The problems of the present invention are not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

The painless syringe of the present invention includes: a valve body having one end closed and an inner space in the longitudinal direction; A spool type valve member that is provided to be slidably movable while contacting the inner space of the valve body with both ends and the central portion, and having a through hole in the central portion; A liquefied gas container which is detachably coupled to the other end of the valve body and communicates with the internal space of the valve body in a state in which a nozzle unit configured at one end is opened; An operation unit configured on one side of the valve body and moving the valve member in a predetermined operation; A cylinder body coupled to one side of the valve body and having an internal space in the longitudinal direction; A piston member having one end slidably moved while contacting the inner space of the cylinder body, and having a piston rod at the other end; A syringe unit detachably coupled to the other end of the cylinder body and having a syringe rod facing the piston rod; Gas for communicating and closing the inner space of the cylinder body and the inner space of the valve body where the one end side of the piston member is located according to the operation of the operating unit, and communicating and closing the inner space of the cylinder body with the outside Flow path forming means; A sound wave oscillation device provided on one side of the syringe unit and oscillating sound waves to vibrate the injection solution injected into the skin and subcutaneous tissue; And a chemical injection control means configured on one side of the piston rod of the piston member to control the sliding movement of the piston member when the piston member moves to move the syringe rod of the syringe unit.

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In the present invention, the valve member is a cylindrical body portion, a plurality of extending flange portions extending outwardly from the both ends and the central portion of the cylindrical body, and coupled to the end faces of the extending flange portion to the inner surface of the valve body It includes a sliding sealing member that provides airtightness while sliding, and the cylinder body is formed with an inner space on one side, and a guide hole is formed on the other side to communicate with the inner space and to guide the piston rod of the piston member tightly. It is formed in a cylindrical shape, and the other end is formed with a coupling portion detachably coupled with a coupling portion of a rod protection cap constituting the syringe unit, and the piston member slides along an inner surface of a guide hole of the cylinder body. And, formed on one end of the piston rod and the cylinder body The piston head in contact with the surface, and is provided on the outer edge of the piston head may include a sliding seal member to provide confidentiality and sliding contact with the inner surface of the cylinder body.

In the present invention, it may further include a cushion member provided on the front and rear edges of the piston head.

In the present invention, the gas flow path forming means includes an inflow communication path communicating one side of the inner space of the valve body with one end side of the inner space of the cylinder body; An exhaust communication path communicating the other side of the inner space of the valve body with the other end side of the inner space of the cylinder body; At least one external communication path formed on an outer edge of the valve member and communicating with and closing the discharge communication path according to the front-rear movement of the valve member; And an outlet passage formed in the valve body in communication with the outside and the outside passage passage.

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In the present invention, the chemical injection control means has a plurality of stopper grooves formed on the outer edge with a gap in the longitudinal direction of the piston rod; A mounting hole formed in a direction perpendicular to the guide hole in one side of the guide hole in the cylinder body; A spherical stopper provided linearly movable in the mounting hole on the inner wall side of the guide hole; A cover cap coupled to cover the mounting hole; And an elastic member provided between the spherical stopper and the cover cap to elastically support the spherical stopper.

In the present invention, the sound wave oscillation device is provided on one side of one end of the syringe unit sonic wave oscillator for oscillating sound waves; A control circuit unit for controlling the sound wave generator in conjunction with an operation operation of the operation unit; And a power supply for supplying power to the sound wave oscillator.

In the present invention, the control circuit unit switching unit for detecting the operation or on-off operation of the operation unit; An operation control unit receiving an operation command from the switching unit according to the operation of the operation unit and controlling the generated sound wave of the sound wave oscillator; And it may include a level control unit for adjusting the sound wave oscillation level generated by the sound wave oscillator.

According to the above-described sound wave generator for a painless syringe according to the present invention and a painless syringe having the same, the pain is further relieved by giving a minute vibration to the skin surface to be injected during painless injection, and injection of the injected drug in the subcutaneous tissue and the body It has the effect of making my absorption more quickly.

In addition, according to the present invention, the instantaneous injection of the injection drug through pneumatics has an effect of significantly reducing the generated noise while having a sufficient pressing force to rapidly inject the injection drug.

In addition, the present invention has the effect of minimizing the effect of noise to the person to be treated, such as infants, and can be particularly useful for animal procedures such as small bird animals that can die due to impact noise.

In addition, the present invention is convenient to use, and can be used in various fields such as human and animal medical treatments and skin care, thereby improving the usability.

The effects of the present invention are not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a block diagram showing a general syringe.
Figure 2 is a schematic view showing a painless syringe having a sound wave oscillation apparatus according to the present invention.
Figure 3 is a block diagram showing the configuration of the control circuit portion of the sound wave generator in a painless syringe having a sound wave generator according to the present invention.
4 is a view showing the operating state of the painless syringe having a sound wave oscillation apparatus according to the present invention, a view showing the neutral state of the operation unit.
5 is a view showing the operation state of the painless syringe equipped with a sound wave oscillation apparatus according to the present invention, a view showing the state of the forward operation (scanning operation or ejection operation) of the operation unit.
6 is a view showing the operating state of the painless syringe having a sound wave oscillation apparatus according to the present invention, a view showing a retracting operation (loading operation) state of the operation unit.
7 is a view showing another embodiment of a painless syringe having a sound wave oscillation apparatus according to the present invention.

Additional objects, features and advantages of the invention may be more clearly understood from the following detailed description and accompanying drawings.

Prior to the detailed description of the present invention, the present invention is capable of various changes, and may have various embodiments. The examples described below and illustrated in the drawings are intended to limit the present invention to specific embodiments. No, it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

When an element is said to be "connected" or "connected" to another component, it is understood that other components may be directly connected to or connected to the other component, but other components may exist in the middle. It should be. On the other hand, when a component is said to be "directly connected" or "directly connected" to another component, it should be understood that no other component exists in the middle.

The terms used in this specification are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this specification, terms such as “include” or “have” are intended to indicate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, and that one or more other features are present. It should be understood that the existence or addition possibilities of fields or numbers, steps, operations, components, parts or combinations thereof are not excluded in advance.

In addition, terms such as "... unit", "... unit", "... module" described in the specification mean a unit that processes at least one function or operation, which is hardware or software or hardware and It can be implemented with a combination of software.

In addition, in the description with reference to the accompanying drawings, the same reference numerals are assigned to the same components regardless of reference numerals, and redundant descriptions thereof will be omitted. In the description of the present invention, when it is determined that detailed descriptions of related known technologies may unnecessarily obscure the subject matter of the present invention, detailed descriptions thereof will be omitted.

Hereinafter, a sound wave generator for a painless syringe according to a preferred embodiment of the present invention and a painless syringe having the same will be described.

First, the sound wave oscillation device for a painless syringe according to the present invention includes: a sound wave oscillator provided on one side of one end of a painless injection unit to which the injection liquid unit is detachably coupled; A control circuit unit for controlling the sound wave generator in association with an operation operation of the operation unit constituting the painless injection unit; And a power source (or battery unit) for supplying power to the sound wave generator.

The sound wave oscillator may be configured by, for example, a plurality of vibration plates disposed on a substrate, and an acoustic wave vibrator installed inside the vibration plate.

The control circuit unit is a switching unit that detects an operation operation or an on-off operation of the operation unit constituting the painless injection unit, and receives sound of the sound generated by the sound wave generator by receiving an operation command from the switching unit according to the operation of the operation unit It includes an operation control unit for controlling, and a level control unit for adjusting the sound wave generation level generated by the sound wave oscillator.

Next, a specific embodiment of a painless syringe having a sound wave oscillation apparatus according to the present invention will be described in detail with reference to FIGS. 2 to 6. 2 is a block diagram showing a painless syringe having a sound wave oscillating device according to the present invention, and FIG. 3 is a block diagram showing the configuration of a control circuit portion of a sound wave oscillating device in a painless syringe having a sound wave oscillating device according to the present invention. 4 to 6 is a view showing the operating state of the painless syringe having a sound wave oscillation apparatus according to the present invention, Figure 4 is a view showing the neutral state of the operation unit, Figure 5 is a forward operation of the operation unit ( It is a figure which shows the state of a scanning operation or a blowout operation, and FIG. 6 is a figure which shows the state of a retraction operation (load operation) of an operation unit.

The painless injection device according to the present invention, as shown in Figures 2 to 6, one end is closed, the valve body 100 having an inner space 101 in the longitudinal direction; A spool type valve member 200 having both ends and a central portion slidably contacting the interior space of the valve body 100 and being slidably movable, and having a through hole 201 in the central portion; A liquefied gas container (300) detachably coupled to the other end of the valve body (100) and communicating with an internal space of the valve body (100) with the nozzle unit configured at one end open; An operation unit configured on one side of the valve body 100 and moving the valve member 200 in a predetermined operation; A cylinder body 500 coupled to one side of the valve body 100, one end closed, and having an internal space in the longitudinal direction; A piston member 600 provided at one end to be slidably moved while airtightly contacting the inner space of the cylinder body 500, and having a piston rod 610 at the other end; An injection liquid unit 700 detachably coupled to the other end of the cylinder body 500 and having a syringe rod 711 contacting or recessed with the piston rod 610; According to the operation of the operation unit, the inner space of the cylinder body 500 where the one end side of the piston member 600 is located and the inner space of the valve body 100 communicate and close, and the cylinder body 500 ) A gas flow path forming means for communicating and closing the inner space with the outside air (outside); And sound wave generating means provided on a side where the injection liquid unit 700 is located and configured to generate sound waves.

The valve body 100 has an inner space (circular inner space) having a length longer than the length of the valve member 200, and a seating port in which the nozzle portion of the liquefied gas container 300 is detachably coupled is formed at the other end. .

The valve member 200 is coupled to a cross-section of the cylindrical body, a plurality of extending flange portions extending outwardly from the both ends and the central portion of the cylindrical body, and an end face of the extending flange portion, and the inner surface of the valve body 100 It comprises a sliding sealing member (for example, O-ring) 210 for maintaining airtightness while sliding contact with.

Here, the outer space portion formed between the extending flange portions of the valve member 200 constitutes one component of the gas flow path forming means, which will be described in detail below.

At the same time as the valve body 100 is coupled to the liquefied gas container 300, the nozzle portion of the liquefied gas container 300 is opened to fill the liquefied gas container 300 with a liquid filled gas in the liquefied gas container 300. Gas that can be ejected while being vaporized through the nozzle part of, for example, liquefied carbon dioxide (CO2) may be filled, but is not limited thereto.

Here, the nozzle portion of the liquefied gas container 300 is coupled to the seating port of the valve body 100, and at the same time, the charged liquefied gas (for example, liquefied carbon dioxide) consists of a configuration that can be ejected while being vaporized, Detailed description thereof will be omitted.

Subsequently, the operation unit is configured to be interlocked with the operation knob 410 on the valve body 100, for example, an operation knob 410 provided slidably on the valve body 100, and the operation operation It includes an interlocking member (not shown) in which the valve member 200 is moved back and forth during a predetermined operation (for example, forward and backward operation) of the knob. Here, it is preferable that the operation knob 410 of the operation unit further includes an elastic restoration member (not shown) that elastically supports to elastically restore the original state after the advance operation.

Next, the cylinder body 500 is formed with an inner space 501 on one side, and a guide hole communicating with the inner space on the other side and airtightly guiding the piston rod 610 of the piston member 600 is formed. It is formed in a cylindrical shape, and the other end is formed with a coupling portion 510 that is detachably coupled to the rod protection cap of the injection liquid unit 700 to be described later.

In addition, the piston member 600 provided in the cylinder body 500, the piston rod 610 and the piston rod 610 of the cylinder body 500, the sliding sliding movement along the inner surface of the guide hole, the piston rod 610 of the The piston head 620 is formed at one end and is in contact with the inner surface of the cylinder body 500, and is provided on the outer edge of the piston head 620, while slidingly contacting the inner surface of the cylinder body 500 to maintain airtightness It comprises a sliding sealing member (for example, O-ring) 630 for.

In addition, the piston member 600 further includes a cushion member 640 provided at an edge of the rear surface of the piston head 620 (opposite to the side where the proximal end of the piston rod 610 is configured). In addition, the cushion member 640 may also be provided on the front surface of the piston head 620 (the surface on the side where the proximal end of the piston rod 610 is configured).

As described above, the cushion member 640 provided in the piston member 600 has a piston head 620 formed with a larger diameter than the diameter of the piston rod 610, and the inner space of the cylinder body 500 is applied with strong force. When the momentary sliding movement, the piston head 620 does not collide directly with the cylinder body 500, but is cushioned by the cushion member 640.

Next, the injection unit 700 is a syringe 710 having a syringe rod 711, and one end is coupled to the syringe 710, the other end is coupled to the engaging portion 510 of the cylinder body 500 It includes a rod protection cap 720 having a syringe coupling portion 721 detachably coupled.

Here, the coupling between the coupling portion 510 of the cylinder body 500 and the syringe coupling portion 721 of the rod protection cap 720 is not particularly limited as long as the two components are detachably coupled. . For example, the coupling portion 510 of the cylinder body 500 is formed in a cylindrical shape so that the cylinder body 500 and the syringe unit 700 can be easily detached, and the syringe coupling portion 721 is cylindrical. It is formed, it can be combined by a bayonet mounting (bayonet mounting) coupling method to be fixed to the locking by rotating to one side after being fitted to the outer edge of the coupling portion 510.

Next, the gas flow path forming means is connected to one side of the inner space 101 of the valve body 100 and one end side of the inner space 501 of the cylinder body 500 with an inflow communication path 810. , The discharge communication path 820 communicating the other side of the inner space 101 of the valve body 100 and the other end side of the inner space 501 of the cylinder body 500, and of the valve member 200 The valve body 200 that is formed on the outer edge and communicates with the discharge communication path 820 according to the front-rear movement of the valve member 200 and closes and communicates with the outer communication path 830, and the outer communication path 830. ).

As shown in FIG. 3, in the neutral position of the operation knob 410 of the operation unit in the inflow communication path 810, the discharge communication path 820, the external communication path 830, and the discharge path 840, the Extruded gas is filled in the inner space 101 of the valve body 100 without communicating with both the inflow communication path 810 and the discharge communication path 820, the external communication path 830, and the discharge path 840 It has a first gas flow path.

In addition, in the inflow communication passage 810, the discharge communication passage 820, the external communication passage 830 and the discharge passage 840, the operation of the operation knob 410 for injecting the injection liquid of the injection liquid unit (forward operation) In the state, as illustrated in FIG. 4, the extruded gas (or filling gas) filled in the interior space 101 of the valve body 100 by opening the inflow communication path 810 is inside the cylinder body 500. It is supplied to one side of the space 501 to move the piston member 600, the discharge communication path 820 and the external communication path 830 and the discharge path 840 is the inner space 501 of the cylinder body 500 It has a second gas flow path formed in communication with the other side of the.

In addition, in the inflow communication path 810, the discharge communication path 820, the external communication path 830 and the discharge path 840, in the state of loading (retreat operation) of the operation knob 410, as shown in FIG. Likewise, the inflow communication path 810 is closed, and the discharge communication path 820 and the interior space 501 of the valve body 100 communicate with each other to fill the interior space 101 of the valve body 100. Gas is supplied, and the outer communication path 830 and the emission path 840 have a third gas flow path that is not in communication with the emission communication path 820.

In the present invention, the extruded vaporized gas ejected from the liquefied gas container 300 when the operation knob is operated by the gas flow path forming means configured as described above is an internal filling gas (valve body 100) in a standby state (ie, a loaded state). It is possible to provide a painless injection device capable of injecting the injection liquid with instantaneous and no generation noise by transmitting a fast and strong ejection pressure to the piston member 600 by being transmitted to the internal space 101 of the gas (gas vaporized). .

Next, the sound wave oscillator means is detachably coupled to the rod protection cap 720, the sound wave oscillator 1000 for oscillating sound waves; A control circuit unit 1110 for controlling the sound wave oscillator 1000 in conjunction with an operation operation of the operation unit (operation knob 410); And a power source (or battery unit) 1120 for supplying power to the sound wave generator 1000.

The sound wave oscillator 1000 may be configured by, for example, a plurality of vibration plates disposed on a substrate, an acoustic wave vibrator installed inside the vibration plate, and is not particularly limited as long as it is capable of oscillating sound waves.

The control circuit 1110 includes an operation unit (a switching unit 1111 that detects an operation operation or an on-off operation of the operation knob 410) as shown in FIG. 3, and the switching unit (in accordance with the operation of the operation unit) 1111) receiving an operation command from the operation control unit 1112 for controlling the sound wave generated by the sound wave oscillator 1000, and a level control unit 1113 for adjusting the sound wave oscillation level generated by the sound wave oscillator 1000 Here, the level adjustment unit 1113 may be omitted.

The sound wave generator provided as described above detects the injection operation of the operation knob 410 in the switching unit 1111, and the detected signal (operation command signal) is transmitted to the control circuit unit 1110, and the control circuit unit In 1110, the sound wave generator 1000 is controlled to control the sound wave of a predetermined level to be oscillated.

The sound waves generated from the sound wave oscillator 1000 gently vibrate the injection skin surface to relieve pain, and at the same time, the injection drug injected by subcutaneous manipulation is also finely vibrated to smoothly penetrate the subcutaneous tissue, and accordingly the body Can be quickly absorbed into the body.

In addition, the power supply 1120 may be composed of a cable that can connect external power, but is preferably composed of a battery unit (battery for charging) provided therein to ensure portability and usability.

On the other hand, the painless injection device according to the present invention controls the sliding movement of the piston member 600 when the piston member 600 is instantaneously moved (less than 1 second) by the pressure of the extruded gas (filling gas) (eg For example, it is a very short time by moving at a constant speed), but may further include a chemical injection control means that allows injection of the injection drug by the injection solution unit at a constant speed.

The chemical injection control means, as shown in the drawing in one embodiment, a plurality of stopper grooves 910 formed on the outer edge with a gap in the longitudinal direction of the piston rod 610 of the piston member 600, the cylinder The mounting hole formed in a direction orthogonal to the guide hole in one side of the guide hole in the body 500, and the spherical stopper 920 provided linearly in the mounting hole in the inner wall side of the guide hole, and the mounting A cover cap 930 coupled to cover the hole, and an elastic member (ie, coil spring) 940 provided between the spherical stopper 920 and the cover cap 930 to elastically support the spherical stopper 920. It includes.

In addition, the mounting hole included in the chemical injection control means and the cover cap 930 are coupled by a screw coupling method, and the cover cap 930 is rotated in a clockwise or counterclockwise direction of the cover cap 930. By adjusting the elastic force of the elastic member, the outer surface of the cover cap 930, based on the outer surface of the cylinder body 500 coupled to the cover cap 930 as a reference line according to the coupling pitch of the cover cap 930 A design elasticity display indicating the elastic force of action of the elastic member may be displayed.

Accordingly, by adjusting the coupling pitch of the cover cap 930, the elastic force of the elastic member is adjusted to adjust the pressing force of the spherical stopper 920 against the piston rod 610.

By configuring such a chemical injection control means, it is possible to reduce not only noise reduction but also scarring of the injection surface through the control of the moving speed, and to further relieve pain relatively.

On the other hand, in the above description, the liquefied gas container 300 shows a case where the valve body 100 is coupled in the longitudinal direction, but the painless injection device according to the present invention, as shown in FIG. 7, the liquefied gas container 300 is It may be orthogonally coupled to the valve body 100. 7 is a view showing another embodiment of a painless syringe having a sound wave oscillation apparatus according to the present invention.

Specifically, the painless injection device of the present invention can be configured in a gun type so that it can be easily gripped to further increase usability, as shown in FIG. 7, on one lower surface of the valve body 100 Further comprising a handle housing 120 for both the liquefied gas container, a lower end of the valve body 100 is formed with a seating port to which the nozzle part of the liquefied gas container 300 is detachably coupled, and the seating port is in communication. It is formed to communicate with the inner space 101 of the valve body 100 through a flow path.

The liquefied gas container 300 is mounted and coupled to the receiving space of the handle housing 120.

According to the sound wave oscillation device for a painless syringe according to the present invention and the painless syringe having the same as described above, the pain is further relieved by giving a minute vibration to the skin surface to be injected during painless injection, and of the injected drug injected into the subcutaneous tissue It is possible to make the injection and absorption into the body more quickly, and has an advantage that the generated noise can be significantly reduced while having a sufficient pressure to inject the injected drug rapidly during the instant injection of the injected drug through pneumatics.

In addition, the present invention can be very useful for animal procedures, such as small bird animals that can minimize the impact of noise on infants and other subjects, and can be killed due to impact noise. In addition, it can be used in a variety of ways, such as skin care and has the advantage of improving the usability.

The embodiments described in the present specification and the accompanying drawings are merely illustrative of some of the technical spirit included in the present invention. Therefore, the embodiments disclosed in the present specification are not intended to limit the technical spirit of the present invention, but to explain the present invention, it is obvious that the scope of the technical spirit of the present invention is not limited by these embodiments. Within the scope of the technical spirit included in the specification and drawings of the present invention, modifications and specific embodiments that can be easily inferred by those skilled in the art should be interpreted as being included in the scope of the present invention.

100: valve body
101: interior space of the valve body
200: valve member
210, 630: sliding sealing member
300: liquefied gas container
410: operation knob
500: cylinder body
510: coupling
501: inner space of the cylinder body
600: piston member
610: piston rod
620: piston head
640: cushion member
700: injection liquid unit
710: syringe
711: syringe loading
720: rod protection cap
721: joint
810: inflow communication path
820: exhaust communication path
830: Yeonyeon communication road
840: outlet
910: stopper home
920: spherical stopper
930: cover cap
940: elastic member
1000: sound wave oscillator
1110: control circuit
1111: switching unit
1112: motion control
1113: level adjustment
1200: battery unit

Claims (12)

delete delete delete delete One end is closed, the valve body having an inner space in the longitudinal direction;
A spool type valve member that is provided to be slidably movable while contacting the inner space of the valve body with both ends and the central portion, and having a through hole in the central portion;
A liquefied gas container which is detachably coupled to the other end of the valve body and communicates with the internal space of the valve body in a state in which a nozzle unit configured at one end is opened;
An operation unit configured on one side of the valve body and moving the valve member in a predetermined operation;
A cylinder body coupled to one side of the valve body and having an internal space in the longitudinal direction;
A piston member having one end slidably moved while contacting the inner space of the cylinder body, and having a piston rod at the other end;
A syringe unit detachably coupled to the other end of the cylinder body and having a syringe rod facing the piston rod;
Gas for communicating and closing the inner space of the cylinder body and the inner space of the valve body where the one end side of the piston member is located according to the operation of the operating unit, and communicating and closing the inner space of the cylinder body with the outside Flow path forming means;
A sound wave oscillation device provided on one side of the syringe unit and oscillating sound waves to vibrate the injection solution injected into the skin and subcutaneous tissue; And
When the piston member moves to move the syringe rod of the syringe unit, the chemical injection control means configured on one side of the piston rod of the piston member to control the sliding movement of the piston member
Painless syringe containing a.
The method of claim 5,
The valve member is coupled to a cross-section of the cylindrical body, a plurality of extended flange portions extending outwardly from the both ends and the central portion of the cylindrical body, and the cross-section of the extended flange portion, thereby providing airtightness while slidingly contacting the inner surface of the valve body. It includes a sliding sealing member provided,
The cylinder body is formed in a cylindrical shape in which an inner space is formed on one side, and a guide hole communicating with the inner space on the other side and hermetically guiding the piston rod of the piston member is formed, and the other end constitutes the syringe unit. A coupling portion detachably coupled with the coupling portion of the rod protection cap is formed,
The piston member is provided on a piston rod sliding along the inner surface of the guide hole of the cylinder body, a piston head formed on one end of the piston rod and contacting the inner surface of the cylinder body, and an outer edge of the piston head And a sliding sealing member for providing airtightness while slidingly contacting the inner surface of the cylinder body
Painless syringe.
The method of claim 6,
Cushion member provided at the front and rear edges of the piston head
The painless syringe further comprising.
The gas flow path forming means according to any one of claims 5 to 7,
An inflow communication path communicating one side of the interior space of the valve body with one end side of the interior space of the cylinder body;
An exhaust communication path communicating the other side of the inner space of the valve body with the other end side of the inner space of the cylinder body;
At least one external communication path formed on an outer edge of the valve member and communicating with and closing the discharge communication path according to the front-rear movement of the valve member; And
A discharge path formed in the valve body in communication with the outside and the outside communication path
Painless syringe containing.
delete The method of claim 5, wherein the chemical injection control means,
A plurality of stopper grooves formed on the outer edge with a gap in the longitudinal direction of the piston rod;
A mounting hole formed in a direction perpendicular to the guide hole in one side of the guide hole in the cylinder body;
A spherical stopper provided linearly movable in the mounting hole on the inner wall side of the guide hole;
A cover cap coupled to cover the mounting hole; And
An elastic member provided between the spherical stopper and the cover cap to elastically support the spherical stopper
Painless syringe containing.
According to claim 5, The sound wave generator,
A sound wave oscillator provided on one side of the syringe unit to oscillate sound waves;
A control circuit unit for controlling the sound wave generator in conjunction with an operation operation of the operation unit; And
Power source for supplying power to the sound wave generator
Painless syringe containing a.
The method of claim 11, wherein the control circuit unit,
A switching unit detecting an operation operation or an on-off operation of the operation unit;
An operation control unit receiving an operation command from the switching unit according to the operation of the operation unit and controlling the generated sound wave of the sound wave generator; And
Level adjustment unit for adjusting the sound wave oscillation level generated by the sound wave oscillator
Painless syringe containing.

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