KR100956158B1 - Suction catheter for surgical - Google Patents

Abstract

The present invention relates to a medical suction catheter, and more particularly to a medical suction catheter that can effectively cool the heat emitted from the light source provided inside the handle.

In the medical suction catheter according to the present invention, the distal end of the optical waveguide is connected to the front of the handle, the medical suction catheter is provided with a light source for irradiating light to the end of the optical waveguide integrally inside the handle, the handle The inside of the heat-conductive material is formed of a heat-dissipating cylinder formed in a cylindrical shape is separated into the inside and the outside, the front end portion of the heat-dissipating cylinder is in contact with the heat dissipation of the light source, the handle and the inside of the heat-radiating cylinder A continuous inflow path is formed, and a discharge path connected to the outside of the heat dissipation cylinder is formed, and the front end of the heat dissipation cylinder is characterized in that a vent hole for connecting the outside and the inside separated by the heat dissipation cylinder is formed.

Suction Machine, Suction Device, Suction Catheter

Description

Medical suction catheters {SUCTION CATHETER FOR SURGICAL}

The present invention relates to a medical suction catheter, and more particularly to a medical suction catheter that can effectively cool the heat emitted from the light source provided inside the handle.

Suction equipment is a device used in the operating room and refers to a device that suctions and removes blood, sap, pus and other debris from a patient during surgery.

In general, the suction equipment includes a suction jar configured to suck foreign substances and other dirt, and to be well-resistant to washing, disinfection and bacterial infection, a suction device including a compressor for adding suction to the suction container, and It is composed of a suction catheter provided with a suction tube for suctioning dirt, and a suction hose connecting the suction container and the suction catheter.

However, when using the suction equipment, it is difficult to accurately determine the inhalation site only with the lighting device of the operating table. Therefore, the suction catheter as described above is provided with an optical waveguide for irradiating a portion to be treated with light from a light source that emits light of a constant illuminance together with a suction tube for sucking various foreign substances generated on the procedure. Korean Patent Laid-Open Publication No. 10-2005-0117277 discloses a suction catheter in which a light source is integrally formed with a catheter, and FIG. 5 illustrates this. Referring to the drawings, the suction catheter disclosed in the Republic of Korea Patent Publication No. 10-2005-0117277, the waveguide 1 is coupled to one side of the suction pipe 2 side by side and the suction pipe 2 and the waveguide 3 is handled (3) is integrally configured by the operator to hold the handle (3) by hand to operate the opening and closing switch (4).

However, the conventional medical suction catheter composed of a light source integrally inside the handle as described above is configured such that heat generated from the light source is cooled by natural cooling, so that the temperature of the light source is high, so that the luminous efficiency is lowered, and the life of the light source is shortened. Has the disadvantage of being shortened.

The present invention was conceived by recognizing the above point, an object of the present invention is a medical suction that can effectively cool the heat emitted from the light source by sucking and exhausting the air to cool the heat emitted from the integrally configured light source To provide a catheter.

In order to achieve the above object, the medical suction catheter according to the present invention has an end portion of the optical waveguide connected to the front of the handle, and a light source for irradiating light to the end of the optical waveguide is integrally provided inside the handle. In the medical suction catheter, the inside of the handle is a thermally conductive material, a heat radiation cylinder formed in a cylindrical shape is installed and separated into the inside and the outside, the front end of the heat radiation cylinder is in contact with the heat radiation of the light source, An inflow path is formed in the handle and is connected to the inside of the heat dissipation cylinder, and a discharge path is formed to be connected to the outside of the heat dissipation cylinder. The front end of the heat dissipation cylinder has a ventilation hole connecting the outside and the inside separated by the heat dissipation cylinder. Characterized in that formed.

In addition, the medical suction catheter according to the present invention, the outer peripheral surface of the heat dissipation cylinder is formed so that the spiral flow groove is connected from the front end to the rear end, the heat dissipation cylinder is in contact with the projection between the flow groove on the inner surface of the case It is installed inside the case, the inflow path is formed to extend forward from the center of the rear end of the case to lead to the interior of the heat radiation cylinder, the plurality of discharge paths are arranged in a ring around the inflow path in the front It is characterized in that it is formed to be connected to the helical flow groove extending from the rear end of the heat dissipation cylinder.

In addition, the medical suction catheter according to the present invention is characterized in that the light source is provided with a condenser lens connected to the end of the optical waveguide, and a lamp for generating light and irradiating the condenser lens.

In addition, the medical suction catheter according to the present invention, the lamp is characterized in that composed of an LED element.

Medical suction catheter according to the present invention by the configuration as described above has the advantage that can effectively cool the heat emitted from the light source integrally configured in the interior of the handle.

Hereinafter, a medical suction catheter according to the present invention will be described in more detail with reference to the embodiment shown in the drawings.

1 is a perspective view showing a medical suction catheter according to an embodiment of the present invention, Figure 2 is an exploded perspective view showing a medical suction catheter according to an embodiment of the present invention, Figure 3 is an embodiment of the present invention Figure 4 is a cross-sectional view showing a medical suction catheter according to Figure 4 is a cross-sectional view showing in detail a medical suction catheter according to an embodiment of the present invention.

Medical suction catheter according to the present invention is the end of the optical waveguide 10 is connected to the front of the handle 30, the light source 20 for irradiating light to the end of the optical waveguide 10 of the handle 30 In the medical suction catheter integrally provided therein, it has a structure capable of effectively dissipating heat generated from the light source 30 provided in the handle 30.

Referring to the drawings, the medical suction catheter according to an embodiment of the present invention comprises an optical waveguide 10, the light source 20, the handle 30 and the suction tube 40.

The optical waveguide 10 is to transmit the light generated from the light source 20 provided in the handle 30 to irradiate the surgical site to suck the dirt by the suction tube 40 in the tubular shape Has Referring to the drawings, the optical waveguide 10 is elongated in a tubular shape so that the light input through the rear end 11 connected to the light source 20 is irradiated forward through the tip. The inside of the optical waveguide 10 is filled with a medium for transmitting light, usually a fiber is used as the medium. The optical waveguide 10 has a rear end 11 inserted into the coupling hole 311 formed at the front end of the case body 31 of the handle 30 and coupled to the handle 30.

The light source 20 generates light and injects the generated light into the rear end portion 11 of the optical waveguide 10. Referring to the drawings, the light source 20 receives the lamp 21 for generating light and the light generated by the lamp 21 to focus on the end of the optical waveguide 10 to be incident. It comprises a condenser lens 22 connected to the end of the optical waveguide (10). The lamp 21 is provided inside the handle 30. For this purpose, it is preferable that the lamp 21 is composed of an LED element having a small output and high output. Heat is generated together with light from the lamp 21, and the heat is provided at the rear of the lamp 21 to radiate heat through the heat dissipation part 211. As described above, the light source 20 including the lamp 21 and the condenser lens 22 is inserted into and mounted on the light source mounting part 312 formed at the front end side of the case body 31 of the handle 30.

The handle 30 is not only a part for the user to grip by hand, but also a configuration for providing a space for the light source 20 to be integrally provided therein. In particular, the present invention is characterized in that the light source 20 is provided in the interior of the handle 30 is configured to effectively discharge the heat generated therefrom to the inside of the handle 30.

Referring to the drawings, the handle 30 includes cases 31 and 32 and heat dissipation cylinders 33 installed inside the cases 31 and 32 for heat dissipation.

The cases 31 and 32 are composed of a case body 31 and a case cap 32. The case main body 31 has a coupling hole 311 for inserting and coupling the rear end end portion 11 of the optical waveguide 10 to a front end portion thereof, and is connected to the coupling hole 311 to the rear of the light source ( A light source mounting part 312 for mounting 20 is formed, and extends rearward from the light source mounting part 312 to have a cylinder shape in which a heat radiation cylinder mounting part 313 for inserting and mounting the heat radiation cylinder 33 is formed. . The case cap 32 is coupled to a rear end of the case body 31 to block the heat dissipation cylinder mounting portion 313. The case cap 32 is formed with an inflow path 321 penetrating the center in the front end direction at the rear end, and a plurality of discharge paths 322 arranged in an annular shape are penetrated in the front end direction at the rear end.

The heat dissipation cylinder 33 stays inside the casings 31 and 32 so that air introduced into the inflow paths 321 of the casings 31 and 32 is sufficiently heat exchanged (to take heat generated from the light source). The inner spaces of the cases 31 and 32 are separated to be discharged to the discharge path 322. In particular, the heat dissipation cylinder 33 is formed of a thermally conductive material (for example, a metal having thermal conductivity such as gold and aluminum) to introduce heat generated from the light source 20 into the cases 31 and 32. Conduct heat to the air to be released and then released. The heat dissipation cylinder 33 is formed of a heat conductive material in a cylindrical shape so that the inner spaces of the cases 31 and 32 are separated into the inside and the outside of the heat dissipation cylinder 33. Is installed. At this time, the heat dissipation cylinder 33 of the case 31, 32 so that the front end portion 331 is in contact with the heat dissipation of the light source 20, that is, the heat dissipation portion 211 of the lamp 21 The heat radiation cylinder mounting portion 313 is installed inside. The inflow path 321 formed in the case cap 32 is connected to the inside of the heat dissipation cylinder 33 separated by the heat dissipation cylinder 33, and to the outside of the heat dissipation cylinder 33. A discharge passage 322 formed in the case cap 32 is followed. In addition, the front end portion 331 of the heat dissipation cylinder 33 is formed with a ventilation hole 332 connecting the outside and the inside separated by the heat dissipation cylinder 33. Accordingly, heat generated by the light source 20 is transferred to the heat radiation cylinder 33 in which the front end portion 331 is in contact with the heat radiation portion 211, and the heat is introduced through the inflow passage 321. Then, it flows into the inside of the heat radiation cylinder 33 and is delivered to the air in contact with the inner surface of the heat radiation cylinder 33. In addition, the air introduced into the heat dissipation cylinder 33 flows out of the heat dissipation cylinder 33 through the vent hole 332 and contacts the outer surface of the heat dissipation cylinder 33 to take heat away. Discharged through the furnace 322. The air introduced into the inflow path 321 flows out of the heat radiation cylinder 33 through the vent hole 332 of the heat radiation cylinder 33 through the inside of the heat radiation cylinder 33. The flow of air discharged to the 322 is made by a predetermined blowing means (not shown in the figure). For example, the blowing means may be achieved by means for injecting air into the inlet passage 321 or means for sucking air into the discharge passage 322. In addition, the blowing means may be achieved by mounting a blowing fan inside the case (31,32).

On the other hand, the present invention is the heat dissipation cylinder 33 so that the air discharged to the outside of the heat dissipation cylinder 33 through the vent hole 332 is in contact with the outer surface of the heat dissipation cylinder 33 to increase the time to take the heat Air discharged to the outside of the) is characterized in that configured to be discharged while contacting the outer surface of the heat radiation cylinder 33 in a spiral. Referring to the drawings, a spiral flow groove 333 is formed in the outer peripheral surface of the heat dissipation cylinder 33 from the front end to the rear end, and the heat dissipation cylinder 33 thus formed is a heat dissipation cylinder of the case body 31. The protrusion 333a between the flow grooves 333 abuts on the inner surface of the mounting portion 313 and is installed inside the case body 31. Accordingly, a spiral passage is formed on the outer side of the heat dissipation cylinder 33 by the flow groove 333 together with the inner surface of the case body 31, that is, the inner surface of the heat dissipation cylinder mounting portion 313. Therefore, the air discharged to the outside of the heat radiation cylinder 33 through the vent hole 332 in the inside of the heat radiation cylinder 33 is the spiral formed by the inner surface of the heat radiation cylinder mounting portion 313 and the flow groove 333. It flows along the passage of and accordingly makes contact with the outer surface of the said heat radiation cylinder mounting part 313 with sufficient time. The inflow passage 321 extends forward from the center of the rear end portion of the case cap 32 to lead to the inside of the heat dissipation cylinder 33, and the discharge passage 322 is formed around the inflow passage 321. In the plural are arranged in an annular shape is extended to the front is formed to be connected to the spiral flow groove 333 is terminated at the rear end of the heat radiation cylinder (33).

The suction tube 40 is coupled to the lower portion of the optical waveguide 10 as a tube for sucking the dirt of the surgical site.

The medical suction catheter described and illustrated in the drawings is only one embodiment for carrying out the present invention, and should not be construed as limiting the technical spirit of the present invention. The scope of protection of the present invention is defined only by the matters set forth in the claims below, and the embodiments which are improved and changed without departing from the gist of the present invention are obvious to those skilled in the art. It will be said to belong to the protection scope of the present invention.

1 is a perspective view showing a medical suction catheter according to an embodiment of the present invention

Figure 2 is an exploded perspective view showing a medical suction catheter according to an embodiment of the present invention

Figure 3 is a cross-sectional view showing a medical suction catheter according to an embodiment of the present invention

Figure 4 is a cross-sectional view showing in detail a medical suction catheter according to an embodiment of the present invention

Figure 5 is a perspective view of a conventional medical suction catheter

<Short description of the major reference symbols>

10 light waveguide

20 light source

21 lamps

22 condenser lens

30 handle

31,32 cases (case body, case cap)

321 funnel

322 exhaust furnace

33 Heat dissipation cylinder

332 ventilation hole

333 Flow Groove

40 suction tube

Claims (4)

In the medical suction catheter, the distal end of the optical waveguide is connected to the front of the handle, and a light source for irradiating light to the distal end of the optical waveguide is integrally provided inside the handle. The inside of the handle is a thermally conductive material is formed of a heat radiation cylinder formed in a cylindrical shape is separated into the inside and the outside, the front end of the heat radiation cylinder is in contact with the heat radiation of the light source, The handle is formed with an inflow path leading to the inside of the heat dissipation cylinder, a discharge path leading to the outside of the heat dissipation cylinder is formed, Medical suction catheter characterized in that the front end of the heat dissipation cylinder is formed with a vent hole for connecting the outside and the inside separated by the heat dissipation cylinder. The method of claim 1, The handle is provided with a case that forms an outer shape that can be gripped by hand and a space formed therein, On the outer circumferential surface of the heat dissipation cylinder, a spiral flow groove is formed to extend from the front end to the rear end, The heat dissipation cylinder is installed inside the case so that the protrusion between the flow grooves in contact with the inner surface of the case, The inflow passage extends forward from the center of the rear end portion of the case to extend into the heat dissipation cylinder, The discharge passage is a medical suction catheter, characterized in that formed in a plurality of annular arrangement around the inlet passage extending in front connected to the spiral flow groove terminated at the rear end of the heat dissipation cylinder. The method according to claim 1 or 2, The light source is a medical suction catheter comprising a condenser lens connected to the end of the optical waveguide and a lamp for generating light and irradiating the condenser lens. The method of claim 3, The lamp is a medical suction catheter, characterized in that consisting of LED elements.

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