KR20100085224A - Laser blood glucose measurement device - Google Patents

Abstract

PURPOSE: A laser blood glucose measurement device is provided to secondary infection due to blood by allowing a user to separate a strip without touching it. CONSTITUTION: A laser module(300) radiates a laser to one direction. A finger interlock(400) converts the laser module into a ready state. An interlock holder(800) prevents a laser from being exposed to the outside. A strip connector(540) inserts a strip. A controller(500) controls blood measurements and the laser. A button portion operates the laser module.

Description

LASER BLOOD GLUCOSE MEASUREMENT DEVICE

The present invention relates to a separate laser blood glucose measurement apparatus without touching the strip inserted into the strip insert.

Generally, the Er: VA laser generator (laser module) used for low blood collection is a reflector made by depositing or plating silver / nickel / copper or these alloys on the surface of a metal several times and then processing the surface. The parts are formed in an outer shape, and the reflector has a flash pump for laser pumping and an Er: VA crystal, respectively.

The laser intensity emitted from the Er: VA laser generator varies depending on the amount of light emitted from the flash lamp and the volume, size, and density of the Er: VA crystal.

However, the conventional low-pain blood collection device using a laser has poor adhesion between the Er: BAA laser generator and the skin, and when a hole is punched through the skin, a "puck" sound is heard and white spots on the skin where the blood is collected There is a disadvantage that the smoke coming out and burning the skin anxious the psychology of blood patients.

In addition, since the glare of the flash lamp and the laser irradiated to the skin are visible, the retina may be damaged by a strong stimulus.

For this reason, the conventional low pain blood collection device using the Er: VA laser generating unit has the advantage of being able to collect blood with low pain unlike the needle-shaped lancet. Brought.

If you look at the technology that strips are used to measure blood glucose, the world's three major companies, Johnson & Johnson, Abbott and Germany Roche, dominate the market, and in Korea, Olmedikus, Infopia and Ice Sense are There is a commercially available type of equipment for measuring blood glucose after collecting blood with a needle-shaped lancet.

Insulin-dependent patients who need to measure blood glucose in real time 2 to 3 times a day usually have a needle-like lancet in the form of a blood sample, which is painful because blood is cut by cutting the skin tissue with a lancet. Not only is this large, it also results in the blood being drawn more than necessary.

In addition, the bleeding area must be bleeding, and even after such bleeding, the wound may not heal quickly and may be infected by a virus or bacteria.

In order to solve this problem, the applicant solved the above problem through the registered patent 10-0782142.

However, Applicant's Patent 10-0782142 has a problem that it is not hygienic because it is necessary to separate the blood-containing strip directly by hand.

In addition, the Applicant's Patent No. 10-0782142 when the laser module is formed, was used to manufacture the cover to cover the compression tube to accommodate the reflector between the front cover and the back cover, but the front cover and back cover with the excellent compression tube There was manufacturing difficulty in covering.

In addition, the laser module wrapped in the compression tube has a problem in that it can not discharge the heat generated from the reflector to the outside to reduce the efficiency.

Therefore, the technical problem to be solved by the present invention is to separate without touching the strip from which blood is collected for blood glucose measurement.

In addition, the technical problem to be solved by the present invention is to provide a laser blood glucose measurement apparatus miniaturized by a laser module and the internal structure arrangement.

In addition, the technical problem to be solved by the present invention is to downsize the disposable cap, so that it can be easily mounted on the pinger interlock.

In addition, the technical problem to be solved by the present invention is to minimize the problem due to heat generated in the laser module.

Laser blood glucose measurement apparatus according to an aspect of the present invention is a laser module for generating a laser to irradiate in one direction, a pinger interlock (Finger Interlock) for switching the laser module to a ready state, and the laser irradiated from the laser module An interlock holder for preventing exposure to the outside, a strip connector for inserting a strip, a control unit for controlling blood measurement and a laser, a button unit for operating the laser module, and a case accommodating the configuration In the laser blood glucose measurement apparatus consisting of a negative portion, characterized in that it further comprises a strip separating portion for separating the strip connected to and inserted into the strip inserting portion.

The laser module of the laser blood glucose measurement apparatus according to the above features further comprises a disposable cap inserted into the Finger Interlock (Finger Interlock) to prevent from contamination of the blood, the disposable cap facilitates insertion into the Pinger Interlock Characterized in that it further forms a finger support for maintaining a constant angle of the finger.

The laser module of the laser blood glucose measurement apparatus according to the above characteristics is a guideline to insert a disposable cap on the front of the Fingerer Interlock (Finger Interlock),

An inlet prevention part for preventing insertion of a predetermined depth or more so that the hole of the disposable cap and the hole of the pinger interlock coincide with each other, and a blocking film for preventing contamination of blood and blocking dust adsorbed during high temperature laser irradiation. do.

The laser module of the laser blood glucose measurement apparatus according to the feature is characterized in that the blocking film is formed of a PP film (Poly Proplyene Film).

In the laser module of the laser blood glucose measurement apparatus according to the above features, the interlock holder has a cross-section in the shape of a cross-section, and intersects on both sides of the case part so as to slide from the top of the case part to cover the pinger interlock. And a receiving portion for receiving the lock holder.

The laser module of the laser blood glucose measurement apparatus according to the above features, the laser module is a reflector (Reflector) is formed in the receiving space therein, Er: YAG crystal is inserted into the receiving space of the reflector, both ends are exposed to the outside of the receiving space And a front cover including a flash lamp inserted into an accommodating space of the reflector together with an Er: YAG crystal, a focusing lens for collecting a laser beam irradiated from the Er: YAG crystal, and the Er: YAG crystal. A back cover for adjusting the intensity of the laser by adjusting the direction of the laser beam, and a metal guide and a silicon guide fixing the Er: YAG crystal and the flash lamp accommodated in the reflector, the tree on the outer circumferential surface of the reflector. A conductive tape wrapped to increase the conductivity of the beaker, and a reflector between the front cover and the back cover, Which it is characterized in that it further comprises a clamp (Clamp) cover.

The laser module of the laser blood glucose measurement apparatus according to the above features, the clamp cover further includes a heat dissipation hole for dissipating heat of the reflector, and a screw unit for fastening and fixing the front cover and the clamp cover. It is done.

According to this aspect of the present invention,

The present invention has the effect of preventing the secondary contamination caused by blood by separating without touching the strip inserted for blood glucose measurement.

In addition, the present invention by miniaturizing the laser module, the focal length is reduced to increase the laser density per unit area has the effect of increasing the accuracy of blood collection with the same energy as conventional.

In addition, by miniaturizing the laser module, the size of the disposable cap to be irradiated is also downsized, so that the thickness of the finger fat embedded in the disposable cap is constant, thereby maintaining the focal length.

In addition, the present invention has an effect of increasing the efficiency of the laser module by dissipating heat generated from the laser module by forming a heat dissipation hole in the clamp cover surrounding the reflector of the laser module.

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

1 is an exploded view showing a laser blood glucose measurement apparatus according to the present invention, Figure 2 is a perspective view showing a laser blood glucose measurement apparatus according to the present invention.

As shown in Figure 1 and 2, the laser blood glucose measurement apparatus 10 according to an embodiment of the present invention, the case unit 100, 200, the laser module 300, the strip connector 300, the pinger interlock ( 400, the control unit 500, the capacitor 600, the strip separating unit 700, the interlock holder 800, the strip connector 540, and the disposable cap 1000.

Here, the case parts 100 and 200 are divided into the front case part 100 and the rear case part 200 and are formed by combining them.

Inside the front case 100, a display device 510 capable of outputting a result, a button unit 520 for operating or giving a command to the laser module 300, and a controller for analyzing data of blood buried in a strip And an interlock holder 800 for accommodating the strip connector 540 into which the strip can be inserted and preventing exposure of the laser generated from the laser module to the outside.

In the rear case 200, a laser module 300 fixed by the laser module fixing unit 30 and generating a laser, a capacitor 600 storing energy at both sides of the laser module 300, and a laser module 300. The front side accommodates the pinger interlock 400 for converting the laser module into a ready state, the rear side of the laser module 300 forms a battery accommodating portion 210 to insert a battery, the strip inserted into the strip connector 540 To separate the strip constitutes a separator 700.

Here, the laser module 300 serves to generate a laser and irradiate in one direction, and the laser module 300 is disposed between the two capacitors 600 to reduce the space. At this time, the focal length of the laser module 300 is 10mm and the irradiation focus is concentrated to 0.15mm. The numerical value according to the exemplary embodiment of the present invention is not limited thereto, but is a numerical value indicating the maximum efficiency.

A more detailed description of the laser module 300 will be described again with reference to FIGS. 3 and 4.

Here, the pinger interlock 400 is located in front of the laser module 300 to convert the laser module into a ready state.

Here, the disposable cap 1000 is a consumable that needs to be replaced when the laser is irradiated once by inserting it into the pinger interlock 400.

Further details regarding the pinger interlock 400 and the disposable cap 1000 are described again in FIG. 5.

Here, the control unit 500 includes a display unit 510, a button unit 520, a charging connector 530, and a strip connector 540, and typically, blood absorbed by a strip inserted into the strip connector 540. The function of acquiring the data is obtained, but the control of the display unit 510, the button unit 520, and the charging connector 530.

In this case, the display unit 510 outputs the result processed by the control unit and the state of the laser blood glucose measurement apparatus 10.

At this time, the button unit 520 is connected to the reflector of the laser module 300 to switch the laser module 300 to the ready state by the pinger interlock 400 to irradiate the laser collected using the button unit 520. do. In this case, the button unit 520 may not only command the operation of the laser, but also adjust the intensity of the laser.

In this case, the charging connector 530 may charge the laser blood glucose measurement apparatus 10 by using a general charging method, and insert a battery through the battery accommodating portion 210 formed in the rear case part 200 to measure the laser blood glucose level. Power to the device 10 can be provided.

At this time, the strip connector 540 is located in the opposite direction to the pinger interlock 400, and the blood collected in the strip inserted into the strip connector 540 is buried. In this case, the time when the blood is buried in the strip may be known through the display unit 510 when the preparation of the controller 500 is completed.

In addition, the position of the strip connector 540 is not limited to the position corresponding to the embodiment of the present invention.

Here, the strip separator 700 is formed inside the connection with the strip connector 540 and used to separate the inserted strip. At this time, the strip separating part 700 is connected to the button 710 pushing up on one side of the rear case part 200 to separate the strip while pushing up the button 710. In this case, since the used strip is a contaminant due to blood, a person who comes into contact with a strip of blood, such as a nurse, needs to be separated without touching it.

Here, the interlock holder 800 is formed in a dichroic (C) cross section, and both sides of the front case part 100 so as to slide from the top of the front case part 100 so as to cover the pinger interlock 400. It is configured to connect the slide member 810 of the interlock holder 800 to the receiving portion of the.

In this case, the interlock holder 800 covers the pinger interlock 400 in line with the laser module 300 to prevent the laser beam emitted from the laser module 300 from being exposed to the outside. In addition, the interlock holder 800 forms a slide member 810 accommodated in the accommodation portion of the side surface of the front case portion 100. As such, there is no fear that the irradiated laser is exposed to the outside by forming the interlock holder 800 to prevent safety accidents.

In addition, the interlock holder 800 using the slide member 810 has the advantage that both sides are connected to the front case portion 100 is strong.

Here, the finger interlock (Finger Interlock, 400) is configured on the front surface for outputting the laser generated by the laser module 300 to the outside, and the elastic member (not shown) between the laser module 300 to form a finger Press to operate the internal sensor (not shown) to switch the laser module 300 to the ready state. At this time, the laser irradiation is not made in the state that the pinger interlock 400 is not pressed, thereby preventing a safety accident in which the laser is exposed to the outside.

3 is an exploded view showing a laser module of the laser blood glucose measurement apparatus according to the present invention, Figure 4 is a cross-sectional view showing a laser module of the laser blood glucose measurement apparatus according to the present invention.

As shown in Figure 3 and 4, the laser module 300 according to an embodiment of the present invention is a flash lamp 310, Er: YAG crystal 320, reflector 330, focusing lens 340, metal The guides 351 and 352, the silicon guides 361 and 362, the conductive tape 370, and the covers 381, 382 and 383.

The flash lamp 310 is applied to the reflector 330 by a predetermined voltage or more to ionize the flash lamp 310 causes a current of a certain amperes A to flow from the anode toward the cathode to emit light.

The Er: YAG crystal 320 sees light having a predetermined wavelength of the laser light emitted from the flash lamp 310 and irradiates through one side having a low laser reflectance. In an embodiment of the present invention, the wavelength of the laser has a 2.94 micro meter.

The reflector 330 has an accommodating space therein to accommodate the Er: YAG crystal 320 and the flash lamp 310 and to absorb the light emitted from the flash lamp 310 by the Er: YAG crystal 320. Gather

The conductive tape 370 is wrapped around the outer circumferential surface of the reflector 330 to increase the conductivity of the reflector 330.

The focusing lens 340 collects the laser irradiated from the Er: YAG crystal 320.

Covers 381, 382, 383 receive Er: YAG crystals 320, flash lamps 310, and reflectors 330, and front covers 381, back covers 382, and clamp covers 383. Consists of.

The front cover 381 includes a focusing lens 340 and accommodates one side of the Er: YAG crystal 320 and the flash lamp 310, wherein the Er: YAG crystal 320 is in line with the focusing lens 340. The metal guide 351 and the silicon guide 361 that secures it for placement are accommodated therein. In this case, the metal guide 351 and the silicon guide 361 form two holes to insert the Er: YAG crystal 320 and the flash lamp 310.

The back cover 382 accommodates the other side of the Er: YAG crystal 320 and the flash lamp 310, and the metal guide 352 for fixing the Er: YAG crystal 320 to be in line with the focusing lens; The silicon guide 362 is accommodated therein and the intensity of the laser is adjusted.

The clamp cover 383 accommodates the reflector 330 which accommodates the flash lamp 310 and the Er: YAG crystal 320 between the front cover 381 and the back cover 382, but the front cover 381 and the clamp. The cover 383 and the back cover 382 are fastened in this order. At this time, the front cover 381 and the clamp cover 383 forms a screw portion (381-1) to enable easy opening and closing.

In addition, the clamp cover 383 further includes a heat dissipation hole 383-1 for dissipating heat from the reflector 330.

A method of assembling a laser module having the above configuration is as follows.

First, the silicon guide 362 and the metal guide 352 are inserted into the back cover 382 and the Er: YAG crystal 320 is inserted. At this time, Er: YAG crystal 320 is matched to the same hole size of the silicon guide 362 and the metal guide 352, and then inserted into any one hole.

Subsequently, the flash lamp 310 is inserted into the other hole of the silicon guide 362 and the metal guide 352. In this case, the flash lamp 310 is inserted such that the cathode is inserted in the direction of the back cover 382.

Next, the reflector 330 is inserted into the back cover 382. In this case, the reflector 330 accommodates the Er: YAG crystal 320 and the flash lamp 310.

Subsequently, the metal guide 351 and the silicon guide 361 are inserted in the other side of the reflector 300 accommodating the Er: YAG crystal 320 and the flash lamp 310.

Subsequently, the outer circumferential surface of the reflector 330 is wrapped with the conductive tape 370.

Subsequently, the back cover 382 and the clamp cover 383 are coupled to each other, and the front cover 381 is fastened to the other side of the clamp cover 383. At this time, the connecting portion of the clamp cover 383 and the front cover 381 may be formed by the skew flow portion (381-1) to be rotated and fastened. In this case, the front cover 381 is in a state where the focusing lens 340 is accommodated therein.

5 is a view showing a state in which the pinger interlock and the disposable cap of the laser blood glucose measurement apparatus according to the present invention are connected.

As shown in FIG. 5, the pinger interlock 400 forms a guideline 410 so that the disposable cap 1000 can be pushed into the front surface of the pinger interlock 400, and the disposable cap hole 1010 and the blocking film 430 coincide with each other. To prevent the insertion and the insertion prevention portion 420 to prevent a predetermined depth so as to block contamination from the blood generated when the laser generated from the laser module 300 to the finger of the subject and the dust adsorbed during the laser irradiation The blocking film 430 is formed.

In this case, the blocking layer 430 is formed of a PP film.

The disposable cap 1000 coincides with the blocking film 430 to facilitate insertion into the capping hole 1010 to which the laser is irradiated and the pinger interlock 400 and to maintain a constant finger angle 1020. ).

The pinger interlock 400 and the disposable cap 1000 are combined with the disposable cap 1000 on the guideline 410 of the pinger interlock 400 to hold the finger support member 1020 of the disposable cap 1000. Push to the position where the prevention part 420 is formed.

The method for measuring blood glucose using the laser blood glucose measurement apparatus according to the present invention goes as follows.

First, insert the strip into the strip connector. At this time, the strip insertion may be made after blood collection.

The disposable cap is then secured inside the interlock holder and the top of the pinlock holder and the finger is placed on top of the disposable cap. At this time, the disposable cap is pushed and fixed along the guideline of the pinger interlock.

The interlock holder is then pressed to the ready state.

Subsequently, after switching to the ready state, the laser module is operated by using the button unit formed outside the case unit.

Then, the generated laser is focused on the focusing lens and irradiated to the inserted finger through the blocking film of the disposable cap.

The blood generated by the laser irradiated to the subject's finger is then absorbed into the strip.

Subsequently, the blood data absorbed in the strip is transferred to the controller.

Subsequently, the blood analysis data analyzed by the controller is output to the display unit.

Finally, the strip separator is used to automatically release the used strip. At this time, since the used strip is a contaminant due to blood, a person who comes into contact with a strip of blood, such as a nurse, needs a method of separating the strip without touching it.

While the present invention has been particularly shown and described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, Of course, this is possible. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the equivalents as well as the claims to be described later.

1 is an exploded view showing a laser blood glucose measurement apparatus according to the present invention.

2 is a perspective view showing a laser blood glucose measurement apparatus according to the present invention.

3 is an exploded view showing a laser module of the laser blood glucose measurement apparatus according to the present invention.

4 is a cross-sectional view showing a laser module of the laser blood glucose measurement apparatus according to the present invention.

5 is a view showing a state in which the pinger interlock and the disposable cap of the laser blood glucose measurement apparatus according to the present invention are connected.

<Description of the symbols for the main parts of the drawings>

10: laser blood glucose measurement device 30: laser module fixing portion

31: locking jaw accommodating part 32: locking jaw

100: front case portion 200: rear case portion

300: laser module 310: flash lamp

320: Er: YAG Crystal 330: Reflector

340: focusing lens 351, 352: metal guide

361, 362: Silicon Guide 370: Conductive Tape

381: Front cover 381-1: Screw part

382: Back Cover 383: Clamp Cover

383-1: Heat Sink 400: Finger Interlock

410: guideline 420: ingress prevention unit

430: blocking film 500: control unit 510: display unit 520: button unit

530: charging connector 540: strip connector

600: capacitor 700: strip separator

710: Button 800: Interlock Holder

810: slide member 1000: disposable cap

1010: disposable cap hole 1020: finger support

Claims (7)

A laser module for generating a laser and irradiating in one direction, a Finger interlock for converting the laser module to a ready state, and an interlock holder for preventing the laser emitted from the laser module from being exposed to the outside. A laser blood glucose measurement apparatus comprising a holder, a strip connector for inserting a strip, a control unit for controlling blood measurement and a laser, a button unit for operating the laser module, and a case unit for accommodating the configuration, And a strip separating unit for separating the strip connected to and inserted into the strip inserting unit. The method of claim 1, Inserting into the Pinger Interlock (Finger Interlock) further comprises a disposable cap to prevent from contamination of blood, The disposable cap is a laser blood glucose measurement apparatus characterized in that it further forms a finger support to facilitate insertion into the pinger interlock and to maintain a constant angle of the finger. The method according to claim 1 or 2, Guidelines for inserting the disposable cap on the front of the Finger Interlock (Finger Interlock), An anti-entry portion preventing insertion of a predetermined depth or more so that the hole of the disposable cap and the hole of the pinger interlock coincide; and Laser blood glucose measurement apparatus, characterized in that for forming a barrier for preventing contamination of blood and blocking dust adsorbed during high-temperature laser irradiation. The method of claim 3, wherein The blocking film is a laser blood glucose measurement apparatus, characterized in that formed by a PP film (Poly Proplyene Film). The method of claim 1, The interlock holder is formed in a dichroic (C) cross-section, it characterized in that the receiving portion for receiving the interlock holder on both sides of the case portion so as to slide from the top of the case portion to cover the pinger interlock Laser blood glucose meter. According to claim 1, The laser module includes a reflector having an accommodating space therein, an Er: YAG crystal inserted into an accommodating space of the reflector, and both ends of which are exposed to the outside of the accommodating space, and an Er: YAG crystal in the accommodating space of the reflector. A front cover having a flash lamp inserted together, a focusing lens for collecting the laser beam irradiated from the Er: YAG crystal, and a back for controlling the intensity of the laser by adjusting the direction of the Er: YAG crystal. The cover (Back Cover), and the metal guide and silicon guide for fixing the Er: YAG crystal and the flash lamp accommodated in the reflector, Laser blood glucose measurement apparatus further comprises a conductive tape wrapped on the outer peripheral surface of the reflector to increase the conductivity of the tracker, and a clamp cover for receiving and fixing the reflector between the front cover and the back cover . The method of claim 6, The clamp cover further comprises a heat dissipation hole for dissipating heat from the reflector, and a screw unit for fastening and fixing the front cover and the clamp cover.

Images