KR20170136084A - Device for detection of blood vessel - Google Patents

Abstract

The present invention relates to a blood vessel detecting device including a sensing unit that is in close contact with the outer surface of a needle and detects vibrations caused by the pulses in a blood vessel transmitted to the needle. The blood vessel detecting device also includes a driver unit that houses the sensing unit therein and is provided with circuit components that are electrically connected to the sensing unit. According to the present invention, the sensing unit is closely attached to the outer portion of the needle close to the needle hub, and is housed in the driver unit to detect the vibrations caused by the pulses in a blood vessel transmitted to the needle and detect the distance to the blood vessel. As a result, it is possible to prevent substances harmful to the human body from entering the body through the needle. In addition, the blood vessel detecting device minimizes rejection and fear of a patient in clinical applications, allows a user to easily detect a blood vessel for drug injection, and prevents the needle from penetrating the blood vessel while detecting the blood vessel.

Description

[0001] DEVICE FOR DETECTION OF BLOOD VESSEL [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a blood vessel detection device, and more particularly, to a blood vessel detection device capable of detecting and displaying blood vessels and preventing or preventing penetration of the needles into the blood vessels during injection.

A syringe is a mechanism for injecting a drug solution into the tissue of a living body. The syringe includes a barrel in which a drug solution is contained, and includes a needle for allowing a drug solution contained in the barrel to be injected into the body, and the barrel and the needle are connected to each other by a needle hub. The drug solution contained in the barrel is injected into the body through the needle under the pressure of the piston motion of the plunger inserted in the barrel.

Injection using a common syringe injects the needle into the body and pressurizes the barrel to allow the drug to enter the body through the needle. Normal injections, except intravenous and intramuscular injections, should ensure that the needle does not penetrate the vessel. Therefore, a detection device for detecting the position of a blood vessel during the injection for safe injection may be used.

A common detection device for detecting the position of a blood vessel is mounted on a body part where an injection is performed or is provided near a patient, and a blood vessel is detected while a patch or the like is in close contact with the skin. On the other hand, other types of general detection devices are provided inside the needle to detect the blood vessel when the needle contacts the blood vessel or is located in the blood vessel.

In the general detection device, since parts for detecting blood vessels such as electrodes and wires are provided inside the needles, there is a problem that harmful substances to the human body can be introduced into the body during scanning. In addition, due to the size of the device, there is a problem that it can cause the patient to feel rejection and fear during clinical application.

Korean Patent No. 10-1002079 entitled " Method for Measuring Vessels of a Vascular Apparatus "

SUMMARY OF THE INVENTION The present invention has been conceived to solve the problems as described above, and it is an object of the present invention to provide a method for preventing harmful substances to the body during injection, The present invention is intended to provide a blood vessel detection device that can easily detect and inject blood vessels and prevent needle infiltration of the blood vessels during blood vessel detection.

The solution to the problem of the present invention is not limited to those mentioned above, and other solutions not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided a blood vessel detection device including a sensing unit and a sensing unit, which are closely attached to an outer surface of a needle, for sensing vibration due to an intracoronary pulse transmitted to a needle, And a driver unit provided with a circuit component connected thereto.

In addition, the driver unit may include a receiving space for allowing the sensing unit to be received as approaching inward, and a receiving unit for receiving the sensing unit, which is caught on the leading end of the sensing unit so as to prevent detachment of the sensing unit, And a latching rib.

In addition, the driver unit is provided with a latching groove formed between the latching rib in the accommodating space, and the latching unit is brought into contact with the detecting unit when the detecting unit is moved to the latching groove side, And a latching protrusion of the sensing unit for inhibiting detachment.

Furthermore, the driver unit may include an elastic unit for applying an elastic force to the sensing unit side so as to increase the adhesion between the sensing unit and the needle.

In the blood vessel detection device according to the present invention having the above-described configuration, the sensing unit is in close contact with the outside of the needle close to the needle hub, and the sensing unit is accommodated in the driver unit, Thereby preventing the substances that are harmful to the human body from being introduced into the body through the needle at the time of injection and preventing the user from feeling irritation and frightness in the clinical application, And has the advantage of preventing the infiltration of the blood vessels in the blood vessels during the detection of the blood vessels.

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

1 is an exploded perspective view of a blood vessel detection device according to an embodiment of the present invention;
2 is a cross-sectional view of one embodiment of the present invention;
3 is a sectional view of a blood vessel detection device according to another embodiment of the present invention.

Hereinafter, a blood vessel detection device according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view of an apparatus for detecting blood vessels according to an embodiment of the present invention, FIG. 2 is a sectional view of an embodiment of the present invention, and FIG. 3 is a sectional view of a blood vessel detecting apparatus according to another embodiment of the present invention.

As shown in these drawings, the blood vessel detection apparatus according to an embodiment of the present invention includes a sensing unit 100 and a driver unit 200, as best shown in FIGS. 1 and 2.

The sensing unit 100 is in close contact with the outer surface of the needle 10 and senses a vibration due to an intravascular pulse transmitted to the needle 10. The sensing unit 100 is provided at a position close to the needle hub 30 connecting the needle 10 and the barrel 20 and is in close contact with the needle 10. The sensing unit 100 senses a gradually increasing vibration as the needle 10 approaches the blood vessel. On the other hand, the sensing unit 100 senses a gradually weakening vibration as the needle 10 moves away from the blood vessel. In the present invention, the sensing unit 100 preferably comprises a vibration sensor for sensing vibration.

The sensing unit 100 is in close contact with the outer surface of the needle 10 and is accommodated in the driver unit 200. The sensing unit 100 is fitted to the driver unit 200 and fixed in position. The combination of the sensing unit 100 and the needle 10 is achieved by the needle 10 passing through the sensing unit 100 and interdigitated with each other. One side of the needle 10 coupled with the sensing unit 100 is exposed to the outside and the other side of the needle 10 coupled with the needle hub 30 is received in the driver unit 200.

The driver unit (200) receives the sensing unit (100) therein. The driver unit 200 also forms a receiving space for accommodating the needle hub, in addition to the receiving space in which the sensing unit 100 is accommodated. The driver unit 200 receives the needle hub 30 in the needle hub accommodating space. The driver unit (200) and the needle hub (30) are coupled to each other by fitting.

The sensing unit 100 is closely attached to the outer side of the needle 10 close to the needle hub 30 and is accommodated in the driver unit 200 so that the needle 10) by detecting the vibration due to the intravascular pulse to detect the distance to the blood vessel, thereby preventing the harmful substances from flowing into the body through the needle at the time of injection and preventing the patient from feeling rejection and fear And it is advantageous that the user can easily detect and inject blood vessels.

Further, the sensing unit 100 senses the vibration caused by the intravascular pulsation through the needle 10 positioned outside the blood vessel, rather than sensing the intravascular blood flow, thereby preventing the intravascular penetration of the needle during the blood vessel detection It also has the advantage of being able to.

A circuit component electrically connected to the sensing unit 100 is provided in the driver unit 200. The circuit component preferably includes a signal converting unit (not shown) and an output unit (not shown). The driver unit 200 converts the sensing signal of the sensing unit 100 through the signal converting unit. The converted sensing signal is output as a notification sound through the output unit. The output unit of the driver unit 200 may output the converted sensing signal as a notification light.

For example, the output unit of the driver unit 200 may shorten the output interval of the notification sound or the notification light according to the intensity of the vibration sensed by the sensing unit 100 as the needle 10 approaches the blood vessel, The user can be informed that the distance between the needle 10 and the blood vessel is getting closer. The output unit may be a speaker for outputting a notification sound, or may be a light emitting device for outputting a notification light.

The driver unit 200 forms an accommodation space for allowing the sensing unit 100 to be received while approaching inward. In addition, the driver unit 200 includes a latching rib 210 to prevent the sensing unit 100, which has flowed into the accommodation space side, from being detached along the inflow direction.

The latching rib 210 of the driver unit 200 contacts the leading end of the sensing unit 100 introduced into the accommodation space and fixes the position of the sensing unit 100. The latching rib 210 prevents detachment of the sensing unit 100 and defines the receiving space in which the sensing unit 100 is accommodated. The sensing unit 100 can be kept in close contact with the interior of the driver unit 200 by the latching rib 210.

Meanwhile, the latching rib 210 is provided with a needle through opening so that one side of the needle 10 penetrates and can be exposed to the outside. The latching rib 210 separates the sensing unit 100 from the outside. Therefore, the latching rib 210 not only has the advantage of fixing the position of the sensing unit 100, but also has the advantage of preventing the harmful substances from the sensing unit 100 or circuit components from being introduced into the body during injection .

Furthermore, the driver unit 200 may further include a locking protrusion 220. The latching protrusion 220 forms a latching groove in the driver unit 200 with the latching rib 210. The engaging protrusion 220 is in contact with the sensing unit 100 when the sensing unit 100 is moved toward the engaging groove. The engaging protrusion 220 suppresses detachment of the sensing unit 100 inserted into the engaging groove in the direction opposite to the engaging groove after the contact with the sensing unit 100.

For example, the user (medical staff) moves the sensing unit 100 to the engagement groove of the driver unit 200 so that the driver unit 200 and the sensing unit 100 are coupled to each other. Thereafter, the needle 10 is fitted into the driver unit 200 so that the needle 10 coupled with the needle hub 30 passes through the sensing unit 100 and is exposed to the outside. Upon fitting the needle hub 30 into the driver unit 200, a blood vessel detecting device is provided outside the needle.

As described above, when scanning is performed using a syringe equipped with a blood vessel detection device, the needle 10 is positioned inside the human body and is vibrated by an intravascular pulse. The sensing unit (100) senses this vibration. The signal converting unit of the driver unit 200 converts the sensing signal sensed by the sensing unit 100. The output unit of the driver unit 200 outputs the converted sensed signal as sound or light so that the user can confirm information about the position and distance of the blood vessel.

The driver unit 200 may further include an elastic unit 300. 3, the elastic unit 300 included in the driver unit 200 may be provided with an elastic force (elastic force) on the sensing unit 100 side so as to increase the adhesion between the sensing unit 100 and the needle 10. [ .

The elastic unit 300 applies an elastic force to a ball in contact with the sensing unit 100 so that an elastic force is transmitted to the sensing unit 100 through the elastic unit 300 such as a spring. In another embodiment of the present invention shown in FIG. 3, the sensing unit 100 may be in contact with the needle 10 in contact with the elastic unit 300. At this time, the sensing unit 100 may have a plurality of elastic units, and elasticity may be transmitted through the elastic units 300, respectively. The elastic unit 300 is fitted into a lead-in groove formed on the inner side of the driver unit 200 to apply an elastic force to the sensing unit 100.

Another embodiment of the present invention may increase the adhesion between the sensing unit 100 and the needle 10 to increase the accuracy of vibration sensing through the needle 10. [ Therefore, the user can more accurately inform the distance between the needle 10 and the blood vessel.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It is obvious.

10: Needle 20: Barrel
30: Needle hub 40: Plunger
100: sensing unit 200: driver unit
210: Retaining rib 220:
300: elastic unit

Claims (4)

A sensing unit which is in close contact with the outer surface of the needle and detects vibration due to an intravascular pulse transmitted to the needle; And
And a driver unit having the sensing unit therein and having circuit components electrically connected to the sensing unit. The method according to claim 1,
Wherein the driver unit comprises:
A receiving space for allowing the sensing unit to be received while approaching inwardly and a latching rib which is caught at the tip of the sensing unit so as to prevent detachment of the sensing unit introduced into the accommodation space side along the direction of the sensing unit; Wherein the blood vessel detection device comprises: 3. The method of claim 2,
Wherein the driver unit comprises:
Wherein the detecting unit is formed with a latching groove in the receiving space, the detecting unit being in contact with the detecting unit when the detecting unit is moved toward the latching groove, And a locking protrusion for restricting detachment of the unit. The method according to claim 1,
Wherein the driver unit comprises:
And an elastic unit for applying an elastic force to the sensing unit side so as to increase the adhesion between the sensing unit and the needle.

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